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LFE3-95E-7FN484I

LFE3-95E-7FN484I

  • 厂商:

    LATTICE(莱迪思半导体)

  • 封装:

    BBGA484

  • 描述:

    IC FPGA 295 I/O 484BGA

  • 详情介绍
  • 数据手册
  • 价格&库存
LFE3-95E-7FN484I 数据手册
SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LatticeECP3 Family Data Sheet Preliminary DS1021 Version 01.6, March 2010 LatticeECP3 Family Data Sheet Introduction November 2009 Preliminary Data Sheet DS1021 Features • Dedicated read/write levelling functionality • Dedicated gearing logic • Source synchronous standards support – ADC/DAC, 7:1 LVDS, XGMII – High Speed ADC/DAC devices • Dedicated DDR/DDR2/DDR3 memory with DQS support • Optional Inter-Symbol Interference (ISI)  correction on outputs  Higher Logic Density for Increased System Integration • 17K to 149K LUTs • 133 to 586 I/Os SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N  Embedded SERDES • 150 Mbps to 3.2 Gbps for Generic 8b10b, 10-bit SERDES, and 8-bit SERDES modes • Data Rates 230 Mbps to 3.2 Gbps per channel for all other protocols • Up to 16 channels per device: PCI Express, SONET/SDH, Ethernet (1GbE, SGMII, XAUI), CPRI, SMPTE 3G and Serial RapidIO  Programmable sysI/O™ Buffer Supports Wide Range of Interfaces • • • • • • •  sysDSP™ • Fully cascadable slice architecture • 12 to 160 slices for high performance multiply and accumulate • Powerful 54-bit ALU operations • Time Division Multiplexing MAC Sharing • Rounding and truncation • Each slice supports – Half 36x36, two 18x18 or four 9x9 multipliers – Advanced 18x36 MAC and 18x18 Multiply- Multiply-Accumulate (MMAC) operations On-chip termination Optional equalization filter on inputs LVTTL and LVCMOS 33/25/18/15/12 SSTL 33/25/18/15 I, II HSTL15 I and HSTL18 I, II PCI and Differential HSTL, SSTL LVDS, Bus-LVDS, LVPECL, RSDS, MLVDS  Flexible Device Configuration • • • • • •  Flexible Memory Resources Dedicated bank for configuration I/Os SPI boot flash interface Dual-boot images supported Slave SPI TransFR™ I/O for simple field updates Soft Error Detect embedded macro  System Level Support • Up to 6.85Mbits sysMEM™ Embedded Block RAM (EBR) • 36K to 303K bits distributed RAM • • • • •  sysCLOCK Analog PLLs and DLLs • Two DLLs and up to ten PLLs per device  Pre-Engineered Source Synchronous I/O IEEE 1149.1 and IEEE 1532 compliant Reveal Logic Analyzer ORCAstra FPGA configuration utility On-chip oscillator for initialization & general use 1.2V core power supply • DDR registers in I/O cells Table 1-1. LatticeECP3™ Family Selection Guide Device ECP3-17 ECP3-35 ECP3-70 ECP3-95 ECP3-150 LUTs (K) 17 33 67 92 149 sysMEM Blocks (18Kbits) 38 72 240 240 372 Embedded Memory (Kbits) 700 1327 4420 4420 6850 Distributed RAM Bits (Kbits) 36 68 145 188 303 18X18 Multipliers 24 64 128 128 320 SERDES (Quad) 1 1 3 3 4 2/2 4/2 10 / 2 10 / 2 10 / 2 4 / 295 4 / 295 PLLs/DLLs Packages and SERDES Channels/ I/O Combinations 256 ftBGA (17x17 mm) 4 / 133 4 / 133 484 fpBGA (23x23 mm) 4 / 222 4 / 295 672 fpBGA (27x27 mm) 4 / 310 1156 fpBGA (35x35 mm) 8 / 380 8 / 380 8 / 380 12 / 490 12 / 490 16 / 586 © 2009 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com 1-1 DS1021 Introduction_01.3 Introduction LatticeECP3 Family Data Sheet Lattice Semiconductor Introduction The LatticeECP3™ (EConomy Plus Third generation) family of FPGA devices is optimized to deliver high performance features such as an enhanced DSP architecture, high speed SERDES and high speed source synchronous interfaces in an economical FPGA fabric. This combination is achieved through advances in device architecture and the use of 65nm technology making the devices suitable for high-volume, high-speed, low-cost applications. The LatticeECP3 device family expands look-up-table (LUT) capacity to 149K logic elements and supports up to 486 user I/Os. The LatticeECP3 device family also offers up to 320 18x18 multipliers and a wide range of parallel I/O standards. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N The LatticeECP3 FPGA fabric is optimized with high performance and low cost in mind. The LatticeECP3 devices utilize reconfigurable SRAM logic technology and provide popular building blocks such as LUT-based logic, distributed and embedded memory, Phase Locked Loops (PLLs), Delay Locked Loops (DLLs), pre-engineered source synchronous I/O support, enhanced sysDSP slices and advanced configuration support, including encryption and dual-boot capabilities. The pre-engineered source synchronous logic implemented in the LatticeECP3 device family supports a broad range of interface standards, including DDR3, XGMII and 7:1 LVDS. The LatticeECP3 device family also features high speed SERDES with dedicated PCS functions. High jitter tolerance and low transmit jitter allow the SERDES plus PCS blocks to be configured to support an array of popular data protocols including PCI Express, SMPTE, Ethernet (XAUI, GbE, and SGMII) and CPRI. Transmit Pre-emphasis and Receive Equalization settings make the SERDES suitable for transmission and reception over various forms of media. The LatticeECP3 devices also provide flexible, reliable and secure configuration options, such as dual-boot capability, bit-stream encryption, and TransFR field upgrade features. The ispLEVER® design tool suite from Lattice allows large complex designs to be efficiently implemented using the LatticeECP3 FPGA family. Synthesis library support for LatticeECP3 is available for popular logic synthesis tools. The ispLEVER tool uses the synthesis tool output along with the constraints from its floor planning tools to place and route the design in the LatticeECP3 device. The ispLEVER tool extracts the timing from the routing and backannotates it into the design for timing verification. Lattice provides many pre-engineered IP (Intellectual Property) ispLeverCORE™ modules for the LatticeECP3 family. By using these configurable soft core IPs as standardized blocks, designers are free to concentrate on the unique aspects of their design, increasing their productivity. 1-2 LatticeECP3 Family Data Sheet Architecture March 2010 Preliminary Data Sheet DS1021 Architecture Overview SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Each LatticeECP3 device contains an array of logic blocks surrounded by Programmable I/O Cells (PIC). Interspersed between the rows of logic blocks are rows of sysMEM™ Embedded Block RAM (EBR) and rows of sysDSP™ Digital Signal Processing slices, as shown in Figure 2-1. In addition, the LatticeECP3 family contains SERDES Quads on the bottom of the device. There are two kinds of logic blocks, the Programmable Functional Unit (PFU) and Programmable Functional Unit without RAM (PFF). The PFU contains the building blocks for logic, arithmetic, RAM and ROM functions. The PFF block contains building blocks for logic, arithmetic and ROM functions. Both PFU and PFF blocks are optimized for flexibility, allowing complex designs to be implemented quickly and efficiently. Logic Blocks are arranged in a twodimensional array. Only one type of block is used per row. The LatticeECP3 devices contain one or more rows of sysMEM EBR blocks. sysMEM EBRs are large, dedicated 18Kbit fast memory blocks. Each sysMEM block can be configured in a variety of depths and widths as RAM or ROM. In addition, LatticeECP3 devices contain up to two rows of DSP slices. Each DSP slice has multipliers and adder/accumulators, which are the building blocks for complex signal processing capabilities. The LatticeECP3 devices feature up to 16 embedded 3.2Gbps SERDES (Serializer / Deserializer) channels. Each SERDES channel contains independent 8b/10b encoding / decoding, polarity adjust and elastic buffer logic. Each group of four SERDES channels, along with its Physical Coding Sub-layer (PCS) block, creates a quad. The functionality of the SERDES/PCS quads can be controlled by memory cells set during device configuration or by registers that are addressable during device operation. The registers in every quad can be programmed via the SERDES Client Interface (SCI). These quads (up to four) are located at the bottom of the devices. Each PIC block encompasses two PIOs (PIO pairs) with their respective sysI/O buffers. The sysI/O buffers of the LatticeECP3 devices are arranged in seven banks, allowing the implementation of a wide variety of I/O standards. In addition, a separate I/O bank is provided for the programming interfaces. 50% of the PIO pairs on the left and right edges of the device can be configured as LVDS transmit/receive pairs. The PIC logic also includes pre-engineered support to aid in the implementation of high speed source synchronous standards such as XGMII, 7:1 LVDS, along with memory interfaces including DDR3. Other blocks provided include PLLs, DLLs and configuration functions. The LatticeECP3 architecture provides two Delay Locked Loops (DLLs) and up to ten Phase Locked Loops (PLLs). In addition, each LatticeECP3 family member provides two DLLs per device. The PLL and DLL blocks are located at the end of the EBR/DSP rows. The configuration block that supports features such as configuration bit-stream decryption, transparent updates and dual-boot support is located toward the center of this EBR row. Every device in the LatticeECP3 family supports a sysCONFIG™ port located in the corner between banks one and two, which allows for serial or parallel device configuration. In addition, every device in the family has a JTAG port. This family also provides an on-chip oscillator and soft error detect capability. The LatticeECP3 devices use 1.2V as their core voltage. © 2010 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com 2-1 DS1021 Architecture_01.5 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-1. Simplified Block Diagram, LatticeECP3-35 Device (Top Level) sysIO Bank 0 sysIO Bank 1 Configuration Logic: Dual-boot, Encryption and Transparent Updates JTAG On-chip Oscillator SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Pre-engineered Source Synchronous Support: DDR3 - 800Mbps Generic - Up to 1Gbps sysIO Bank 7 sysIO Bank 2 Enhanced DSP Slices: Multiply, Accumulate and ALU sysCLOCK PLLs & DLLs: Frequency Synthesis and Clock Alignment Flexible sysIO: LVCMOS, HSTL, SSTL, LVDS Up to 486 I/Os sysMEM Block RAM: 18Kbit Flexible Routing: Optimized for speed and routability Programmable Function Units: Up to 149K LUTs SERDES/PCS SERDES/PCS CH 3 CH 2 SERDES/PCS SERDES/PCS CH 1 CH 0 sysIO Bank 6 sysIO Bank 3 3.2Gbps SERDES Note: There is no Bank 4 or Bank 5 in LatticeECP3 devices. PFU Blocks The core of the LatticeECP3 device consists of PFU blocks, which are provided in two forms, the PFU and PFF. The PFUs can be programmed to perform Logic, Arithmetic, Distributed RAM and Distributed ROM functions. PFF blocks can be programmed to perform Logic, Arithmetic and ROM functions. Except where necessary, the remainder of this data sheet will use the term PFU to refer to both PFU and PFF blocks. Each PFU block consists of four interconnected slices numbered 0-3 as shown in Figure 2-2. Each slice contains two LUTs. All the interconnections to and from PFU blocks are from routing. There are 50 inputs and 23 outputs associated with each PFU block. 2-2 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-2. PFU Diagram From Routing LUT4 & CARRY LUT4 & CARRY LUT4 & CARRY LUT4 & CARRY Slice 1 LUT4 & CARRY LUT4 LUT4 Slice 3 Slice 2 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Slice 0 LUT4 & CARRY D FF D FF D FF D D FF FF D FF To Routing Slice Slice 0 through Slice 2 contain two LUT4s feeding two registers, whereas Slice 3 contains two LUT4s only. For PFUs, Slice 0 through Slice 2 can be configured as distributed memory, a capability not available in the PFF. Table 2-1 shows the capability of the slices in both PFF and PFU blocks along with the operation modes they enable. In addition, each PFU contains logic that allows the LUTs to be combined to perform functions such as LUT5, LUT6, LUT7 and LUT8. There is control logic to perform set/reset functions (programmable as synchronous/ asynchronous), clock select, chip-select and wider RAM/ROM functions. Table 2-1. Resources and Modes Available per Slice PFU BLock Slice Resources PFF Block Modes Resources Modes Slice 0 2 LUT4s and 2 Registers Logic, Ripple, RAM, ROM 2 LUT4s and 2 Registers Logic, Ripple, ROM Slice 1 2 LUT4s and 2 Registers Logic, Ripple, RAM, ROM 2 LUT4s and 2 Registers Logic, Ripple, ROM Slice 2 2 LUT4s and 2 Registers Logic, Ripple, RAM, ROM 2 LUT4s and 2 Registers Logic, Ripple, ROM Slice 3 2 LUT4s Logic, ROM 2 LUT4s Logic, ROM Figure 2-3 shows an overview of the internal logic of the slice. The registers in the slice can be configured for positive/negative and edge triggered or level sensitive clocks. Slices 0, 1 and 2 have 14 input signals: 13 signals from routing and one from the carry-chain (from the adjacent slice or PFU). There are seven outputs: six to routing and one to carry-chain (to the adjacent PFU). Slice 3 has 10 input signals from routing and four signals to routing. Table 2-2 lists the signals associated with Slice 0 to Slice 2. 2-3 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-3. Slice Diagram FCO To Different Slice/PFU SLICE FXB FXA OFX1 A1 B1 C1 D1 CO F1 F/SUM Q1 D LUT4 & CARRY* FF* To Routing SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N CI M1 M0 LUT5 Mux From Routing OFX0 A0 B0 C0 D0 CO LUT4 & CARRY* F0 F/SUM Q0 D FF* CI CE CLK LSR * Not in Slice 3 FCI From Different Slice/PFU For Slices 0 and 1, memory control signals are generated from Slice 2 as follows: WCK is CLK WRE is from LSR DI[3:2] for Slice 1 and DI[1:0] for Slice 0 data from Slice 2 WAD [A:D] is a 4-bit address from slice 2 LUT input Table 2-2. Slice Signal Descriptions Function Type Signal Names Input Data signal A0, B0, C0, D0 Inputs to LUT4 Description Input Data signal A1, B1, C1, D1 Inputs to LUT4 Input Multi-purpose M0 Multipurpose Input Input Multi-purpose M1 Multipurpose Input Input Control signal CE Clock Enable Input Control signal LSR Local Set/Reset Input Control signal CLK System Clock Input Inter-PFU signal FC Fast Carry-in1 Input Inter-slice signal FXA Intermediate signal to generate LUT6 and LUT7 Intermediate signal to generate LUT6 and LUT7 Input Inter-slice signal FXB Output Data signals F0, F1 LUT4 output register bypass signals Output Data signals Q0, Q1 Register outputs Output Data signals OFX0 Output of a LUT5 MUX Output Data signals OFX1 Output of a LUT6, LUT7, LUT82 MUX depending on the slice Output Inter-PFU signal FCO Slice 2 of each PFU is the fast carry chain output1 1. See Figure 2-3 for connection details. 2. Requires two PFUs. 2-4 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Modes of Operation Each slice has up to four potential modes of operation: Logic, Ripple, RAM and ROM. Logic Mode In this mode, the LUTs in each slice are configured as 4-input combinatorial lookup tables. A LUT4 can have 16 possible input combinations. Any four input logic functions can be generated by programming this lookup table. Since there are two LUT4s per slice, a LUT5 can be constructed within one slice. Larger look-up tables such as LUT6, LUT7 and LUT8 can be constructed by concatenating other slices. Note LUT8 requires more than four slices. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Ripple Mode Ripple mode supports the efficient implementation of small arithmetic functions. In ripple mode, the following functions can be implemented by each slice: • Addition 2-bit • Subtraction 2-bit • Add/Subtract 2-bit using dynamic control • Up counter 2-bit • Down counter 2-bit • Up/Down counter with asynchronous clear • Up/Down counter with preload (sync) • Ripple mode multiplier building block • Multiplier support • Comparator functions of A and B inputs – A greater-than-or-equal-to B – A not-equal-to B – A less-than-or-equal-to B Ripple Mode includes an optional configuration that performs arithmetic using fast carry chain methods. In this configuration (also referred to as CCU2 mode) two additional signals, Carry Generate and Carry Propagate, are generated on a per slice basis to allow fast arithmetic functions to be constructed by concatenating Slices. RAM Mode In this mode, a 16x4-bit distributed single port RAM (SPR) can be constructed using each LUT block in Slice 0 and Slice 1 as a 16x1-bit memory. Slice 2 is used to provide memory address and control signals. A 16x2-bit pseudo dual port RAM (PDPR) memory is created by using one Slice as the read-write port and the other companion slice as the read-only port. LatticeECP3 devices support distributed memory initialization. The Lattice design tools support the creation of a variety of different size memories. Where appropriate, the software will construct these using distributed memory primitives that represent the capabilities of the PFU. Table 2-3 shows the number of slices required to implement different distributed RAM primitives. For more information about using RAM in LatticeECP3 devices, please see TN1179, LatticeECP3 Memory Usage Guide. Table 2-3. Number of Slices Required to Implement Distributed RAM Number of slices SPR 16X4 PDPR 16X4 3 3 Note: SPR = Single Port RAM, PDPR = Pseudo Dual Port RAM 2-5 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor ROM Mode ROM mode uses the LUT logic; hence, Slices 0 through 3 can be used in ROM mode. Preloading is accomplished through the programming interface during PFU configuration. For more information, please refer to TN1179, LatticeECP3 Memory Usage Guide. Routing SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N There are many resources provided in the LatticeECP3 devices to route signals individually or as busses with related control signals. The routing resources consist of switching circuitry, buffers and metal interconnect (routing) segments. The LatticeECP3 family has an enhanced routing architecture that produces a compact design. The ispLEVER design tool suite takes the output of the synthesis tool and places and routes the design. sysCLOCK PLLs and DLLs The sysCLOCK PLLs provide the ability to synthesize clock frequencies. All the devices in the LatticeECP3 family support four to ten full-featured General Purpose PLLs. General Purpose PLL The architecture of the PLL is shown in Figure 2-4. A description of the PLL functionality follows. CLKI is the reference frequency (generated either from the pin or from routing) for the PLL. CLKI feeds into the Input Clock Divider block. The CLKFB is the feedback signal (generated from CLKOP, CLKOS or from a user clock pin/logic). This signal feeds into the Feedback Divider. The Feedback Divider is used to multiply the reference frequency. Both the input path and feedback signals enter the Voltage Controlled Oscillator (VCO) block. In this block the difference between the input path and feedback signals is used to control the frequency and phase of the oscillator. A LOCK signal is generated by the VCO to indicate that the VCO has locked onto the input clock signal. In dynamic mode, the PLL may lose lock after a dynamic delay adjustment and not relock until the tLOCK parameter has been satisfied. The output of the VCO then enters the CLKOP divider. The CLKOP divider allows the VCO to operate at higher frequencies than the clock output (CLKOP), thereby increasing the frequency range. The Phase/Duty Select block adjusts the phase and duty cycle of the CLKOS signal. The phase/duty cycle setting can be pre-programmed or dynamically adjusted. A secondary divider takes the CLKOP or CLKOS signal and uses it to derive lower frequency outputs (CLKOK). The primary output from the CLKOP divider (CLKOP) along with the outputs from the secondary dividers (CLKOK and CLKOK2) and Phase/Duty select (CLKOS) are fed to the clock distribution network. The PLL allows two methods for adjusting the phase of signal. The first is referred to as Fine Delay Adjustment. This inserts up to 16 nominal 125ps delays to be applied to the secondary PLL output. The number of steps may be set statically or from the FPGA logic. The second method is referred to as Coarse Phase Adjustment. This allows the phase of the rising and falling edge of the secondary PLL output to be adjusted in 22.5 degree steps. The number of steps may be set statically or from the FPGA logic. 2-6 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-4. General Purpose PLL Diagram FDA[3:0] WRDEL 3 Phase/ Duty Cycle/ Duty Trim CLKI Divider CLKI VCO/ Loop Filter CLKOP Divider CLKOS CLKOP SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N PFD CLKOK2 CLKFB CLKFB Divider Duty Trim CLKOK CLKOK Divider Lock Detect RSTK RST DRPAI[3:0] DFPAI[3:0] LOCK Table 2-4 provides a description of the signals in the PLL blocks. Table 2-4. PLL Blocks Signal Descriptions Signal I/O Description CLKI I Clock input from external pin or routing CLKFB I PLL feedback input from CLKOP, CLKOS, or from a user clock (pin or logic) RST I “1” to reset PLL counters, VCO, charge pumps and M-dividers RSTK I “1” to reset K-divider WRDEL I DPA Fine Delay Adjust input CLKOS O PLL output to clock tree (phase shifted/duty cycle changed) CLKOP O PLL output to clock tree (no phase shift) CLKOK O PLL output to clock tree through secondary clock divider CLKOK2 O PLL output to clock tree (CLKOP divided by 3) LOCK O “1” indicates PLL LOCK to CLKI FDA [3:0] I Dynamic fine delay adjustment on CLKOS output DRPAI[3:0] I Dynamic coarse phase shift, rising edge setting DFPAI[3:0] I Dynamic coarse phase shift, falling edge setting Delay Locked Loops (DLL) In addition to PLLs, the LatticeECP3 family of devices has two DLLs per device. CLKI is the input frequency (generated either from the pin or routing) for the DLL. CLKI feeds into the output muxes block to bypass the DLL, directly to the DELAY CHAIN block and (directly or through divider circuit) to the reference input of the Phase Detector (PD) input mux. The reference signal for the PD can also be generated from the Delay Chain signals. The feedback input to the PD is generated from the CLKFB pin or from a tapped signal from the Delay chain. The PD produces a binary number proportional to the phase and frequency difference between the reference and feedback signals. Based on these inputs, the ALU determines the correct digital control codes to send to the delay 2-7 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor chain in order to better match the reference and feedback signals. This digital code from the ALU is also transmitted via the Digital Control bus (DCNTL) bus to its associated Slave Delay lines (two per DLL). The ALUHOLD input allows the user to suspend the ALU output at its current value. The UDDCNTL signal allows the user to latch the current value on the DCNTL bus. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N The DLL has two clock outputs, CLKOP and CLKOS. These outputs can individually select one of the outputs from the tapped delay line. The CLKOS has optional fine delay shift and divider blocks to allow this output to be further modified, if required. The fine delay shift block allows the CLKOS output to phase shifted a further 45, 22.5 or 11.25 degrees relative to its normal position. Both the CLKOS and CLKOP outputs are available with optional duty cycle correction. Divide by two and divide by four frequencies are available at CLKOS. The LOCK output signal is asserted when the DLL is locked. Figure 2-5 shows the DLL block diagram and Table 2-5 provides a description of the DLL inputs and outputs. The user can configure the DLL for many common functions such as time reference delay mode and clock injection removal mode. Lattice provides primitives in its design tools for these functions. Figure 2-5. Delay Locked Loop Diagram (DLL) Delay Chain ALUHOLD Delay0 Duty Cycle 50% CLKOP Delay1 ÷4 ÷2 (from routing or external pin) CLKI from CLKOP (DLL internal), from clock net (CLKOP) or from a user clock (pin or logic) Output Muxes Delay2 Reference Phase Detector Duty Cycle 50% Delay3 Arithmetic Logic Unit CLKOS ÷4 ÷2 Delay4 Feedback CLKFB LOCK Lock Detect 6 Digital Control Output UDDCNTL RSTN INCI GRAYI[5:0] DCNTL[5:0]* DIFF INCO GRAYO[5:0] * This signal is not user accessible. This can only be used to feed the slave delay line. 2-8 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Table 2-5. DLL Signals Signal I/O Description CLKI I Clock input from external pin or routing CLKFB I DLL feed input from DLL output, clock net, routing or external pin RSTN I Active low synchronous reset ALUHOLD I Active high freezes the ALU I Synchronous enable signal (hold high for two cycles) from routing CLKOP O The primary clock output CLKOS O The secondary clock output with fine delay shift and/or division by 2 or by 4 LOCK O Active high phase lock indicator SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N UDDCNTL INCI I Incremental indicator from another DLL via CIB. GRAYI[5:0] I Gray-coded digital control bus from another DLL in time reference mode. DIFF O Difference indicator when DCNTL is difference than the internal setting and update is needed. INCO O Incremental indicator to other DLLs via CIB. GRAYO[5:0] O Gray-coded digital control bus to other DLLs via CIB LatticeECP3 devices have two general DLLs and four Slave Delay lines, two per DLL. The DLLs are in the lowest EBR row and located adjacent to the EBR. Each DLL replaces one EBR block. One Slave Delay line is placed adjacent to the DLL and the duplicate Slave Delay line (in Figure 2-6) for the DLL is placed in the I/O ring between Banks 6 and 7 and Banks 2 and 3. The outputs from the DLL and Slave Delay lines are fed to the clock distribution network. For more information, please see TN1178, LatticeECP3 sysCLOCK PLL/DLL Design and Usage Guide. Figure 2-6. Top-Level Block Diagram, High-Speed DLL and Slave Delay Line HOLD GRAY_IN[5:0] INC_IN RSTN GSRN UDDCNTL DCPS[5:0] CLKOP CLKOS TPIO0 (L) OR TPIO1 (R) GPLL_PIO CIB (DATA) CIB (CLK) GDLL_PIO 4 Top ECLK1 (L) OR Top ECLK2 (R) FB CIB (CLK) Internal from CLKOP GDLLFB_PIO ECLK1 4 3 2 CLKI LatticeECP3 High-Speed DLL LOCK 1 0 3 2 GRAY_OUT[5:0] INC_OUT CLKFB DIFF 1 0 DCNTL[5:0]* DCNTL[5:0] 4 3 2 1 CLKI Slave Delay Line CLKO (to edge clock muxes as CLKINDEL) 0 * This signal is not user accessible. It can only be used to feed the slave delay line. 2-9 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor PLL/DLL Cascading LatticeECP3 devices have been designed to allow certain combinations of PLL and DLL cascading. The allowable combinations are: • PLL to PLL supported • PLL to DLL supported SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N The DLLs in the LatticeECP3 are used to shift the clock in relation to the data for source synchronous inputs. PLLs are used for frequency synthesis and clock generation for source synchronous interfaces. Cascading PLL and DLL blocks allows applications to utilize the unique benefits of both DLLs and PLLs. For further information about the DLL, please see the list of technical documentation at the end of this data sheet. PLL/DLL PIO Input Pin Connections All LatticeECP3 devices contains two DLLs and up to ten PLLs, arranged in quadrants. If a PLL and a DLL are next to each other, they share input pins as shown in the Figure 2-7. Figure 2-7. Sharing of PIO Pins by PLLs and DLLs in LatticeECP3 Devices PLL_PIO PLL DLL DLL_PIO Note: Not every PLL has an associated DLL. Clock Dividers LatticeECP3 devices have two clock dividers, one on the left side and one on the right side of the device. These are intended to generate a slower-speed system clock from a high-speed edge clock. The block operates in a ÷2, ÷4 or ÷8 mode and maintains a known phase relationship between the divided down clock and the high-speed clock based on the release of its reset signal. The clock dividers can be fed from selected PLL/DLL outputs, the Slave Delay lines, routing or from an external clock input. The clock divider outputs serve as primary clock sources and feed into the clock distribution network. The Reset (RST) control signal resets input and asynchronously forces all outputs to low. The RELEASE signal releases outputs synchronously to the input clock. For further information on clock dividers, please see TN1178, LatticeECP3 sysCLOCK PLL/DLL Design and Usage Guide. Figure 2-8 shows the clock divider connections. 2-10 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-8. Clock Divider Connections ECLK1 ECLK2 ÷1 CLKOP (PLL) CLKOP (DLL) ÷2 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N CLKDIV ÷4 RST ÷8 RELEASE Clock Distribution Network LatticeECP3 devices have eight quadrant-based primary clocks and eight secondary clock/control sources. Two high performance edge clocks are available on the top, left, and right edges of the device to support high speed interfaces. These clock sources are selected from external I/Os, the sysCLOCK PLLs, DLLs or routing. These clock sources are fed throughout the chip via a clock distribution system. Primary Clock Sources LatticeECP3 devices derive clocks from six primary source types: PLL outputs, DLL outputs, CLKDIV outputs, dedicated clock inputs, routing and SERDES Quads. LatticeECP3 devices have two to ten sysCLOCK PLLs and two DLLs, located on the left and right sides of the device. There are six dedicated clock inputs: two on the top side, two on the left side and two on the right side of the device. Figures 2-9, 2-10 and 2-11 show the primary clock sources for LatticeECP3 devices. Figure 2-9. Primary Clock Sources for LatticeECP3-17 Clock Input Clock Input From Routing Clock Input Clock Input Clock Input Clock Input CLK DIV Primary Clock Sources to Eight Quadrant Clock Selection CLK DIV DLL Input DLL DLL DLL Input PLL Input PLL PLL PLL Input SERDES Quad From Routing Note: Clock inputs can be configured in differential or single-ended mode. 2-11 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-10. Primary Clock Sources for LatticeECP3-35 Clock Input Clock Input From Routing PLL Input PLL PLL PLL Input Clock Input Clock Input Clock Input SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Clock Input CLK DIV DLL Input DLL PLL Input PLL Primary Clock Sources to Eight Quadrant Clock Selection CLK DIV DLL DLL Input PLL PLL Input SERDES Quad From Routing Note: Clock inputs can be configured in differential or single-ended mode. Figure 2-11. Primary Clock Sources for LatticeECP3-70, -95, -150 Clock Input Clock Input From Routing PLL Input PLL PLL PLL Input PLL Input PLL PLL PLL Input Clock Input Clock Input Clock Input Clock Input CLK DIV Primary Clock Sources to Eight Quadrant Clock Selection CLK DIV DLL Input DLL DLL DLL Input PLL Input PLL PLL PLL Input PLL Input PLL PLL PLL Input PLL Input PLL PLL PLL Input SERDES Quad SERDES Quad SERDES Quad SERDES Quad (ECP3-150 only) From Routing Note: Clock inputs can be configured in differential or single-ended mode. 2-12 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Primary Clock Routing The purpose of the primary clock routing is to distribute primary clock sources to the destination quadrants of the device. A global primary clock is a primary clock that is distributed to all quadrants. The clock routing structure in LatticeECP3 devices consists of a network of eight primary clock lines (CLK0 through CLK7) per quadrant. The primary clocks of each quadrant are generated from muxes located in the center of the device. All the clock sources are connected to these muxes. Figure 2-12 shows the clock routing for one quadrant. Each quadrant mux is identical. If desired, any clock can be routed globally. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Figure 2-12. Per Quadrant Primary Clock Selection PLLs + DLLs + CLKDIVs + PCLK PIOs + SERDES Quads 63:1 63:1 63:1 63:1 63:1 63:1 DCC DCC DCC DCC DCC DCC CLK0 CLK1 CLK2 CLK3 CLK4 CLK5 58:1 58:1 DCS CLK6 58:1 58:1 DCS CLK7 8 Primary Clocks (CLK0 to CLK7) per Quadrant Dynamic Clock Control (DCC) The DCC (Quadrant Clock Enable/Disable) feature allows internal logic control of the quadrant primary clock network. When a clock network is disabled, all the logic fed by that clock does not toggle, reducing the overall power consumption of the device. Dynamic Clock Select (DCS) The DCS is a smart multiplexer function available in the primary clock routing. It switches between two independent input clock sources without any glitches or runt pulses. This is achieved regardless of when the select signal is toggled. There are two DCS blocks per quadrant; in total, there are eight DCS blocks per device. The inputs to the DCS block come from the center muxes. The output of the DCS is connected to primary clocks CLK6 and CLK7 (see Figure 2-12). Figure 2-13 shows the timing waveforms of the default DCS operating mode. The DCS block can be programmed to other modes. For more information about the DCS, please see the list of technical documentation at the end of this data sheet. Figure 2-13. DCS Waveforms CLK0 CLK1 SEL DCSOUT 2-13 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Secondary Clock/Control Sources LatticeECP3 devices derive eight secondary clock sources (SC0 through SC7) from six dedicated clock input pads and the rest from routing. Figure 2-14 shows the secondary clock sources. All eight secondary clock sources are defined as inputs to a per-region mux SC0-SC7. SC0-SC3 are primary for control signals (CE and/or LSR), and SC4-SC7 are for clock and high fanout data. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N In an actual implementation, there is some overlap to maximize routability. In addition to SC0-SC3, SC7 is also an input to the control signals (LSR or CE). SC0-SC2 are also inputs to clocks along with SC4-SC7. High fanout logic signals (LUT inputs) will utilize the X2 and X0 switches where SC0-SC7 are inputs to X2 switches, and SC4-SC7 are inputs to X0 switches. Note that through X0 switches, SC4-SC7 can also access control signals CE/LSR. Figure 2-14. Secondary Clock Sources Clock Input From Routing Clock Input From Routing From Routing From Routing From Routing From Routing From Routing From Routing Clock Input Clock Input Secondary Clock Sources Clock Input Clock Input From Routing From Routing From Routing From Routing From Routing From Routing From Routing From Routing Note: Clock inputs can be configured in differential or single-ended mode. Secondary Clock/Control Routing Global secondary clock is a secondary clock that is distributed to all regions. The purpose of the secondary clock routing is to distribute the secondary clock sources to the secondary clock regions. Secondary clocks in the LatticeECP3 devices are region-based resources. Certain EBR rows and special vertical routing channels bind the secondary clock regions. This special vertical routing channel aligns with either the left edge of the center DSP slice in the DSP row or the center of the DSP row. Figure 2-15 shows this special vertical routing channel and the 20 secondary clock regions for the LatticeECP3 family of devices. All devices in the LatticeECP3 family have eight 2-14 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor secondary clock resources per region (SC0 to SC7). The same secondary clock routing can be used for control signals. Table 2-6. Secondary Clock Regions Number of Secondary Clock Regions ECP3-17 16 ECP3-35 16 ECP3-70 20 ECP3-95 20 ECP3-150 36 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Device Figure 2-15. LatticeECP3-70 and LatticeECP3-95 Secondary Clock Regions Vertical Routing Channel Regional Boundary Secondary Clock Region R1C2 Secondary Clock Region R1C3 Secondary Clock Region R1C4 Secondary Clock Region R2C1 Secondary Clock Region R2C2 Secondary Clock Region R2C3 Secondary Clock Region R2C4 Secondary Clock Region R3C1 Secondary Clock Region R3C2 Secondary Clock Region R3C3 Secondary Clock Region R3C4 Secondary Clock Region R4C1 Secondary Clock Region R4C2 Secondary Clock Region R4C3 Secondary Clock Region R4C4 Secondary Clock Region R5C1 Secondary Clock Region R5C2 Secondary Clock Region R5C3 Secondary Clock Region R5C4 SERDES Spine Repeaters 2-15 EBR Row Regional Boundary sysIO Bank 2 Secondary Clock Region R1C1 Configuration Bank sysIO Bank 1 sysIO Bank 3 sysIO Bank 6 sysIO Bank 7 sysIO Bank 0 EBR Row Regional Boundary Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-16. Per Region Secondary Clock Selection Secondary Clock Feedlines: 8 PIOs + 16 Routing 8:1 8:1 8:1 8:1 8:1 8:1 8:1 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 8:1 SC0 SC1 SC2 SC3 SC4 SC5 SC6 SC7 8 Secondary Clocks (SC0 to SC7) per Region Clock/Control Slice Clock Selection Figure 2-17 shows the clock selections and Figure 2-18 shows the control selections for Slice0 through Slice2. All the primary clocks and seven secondary clocks are routed to this clock selection mux. Other signals can be used as a clock input to the slices via routing. Slice controls are generated from the secondary clocks/controls or other signals connected via routing. If none of the signals are selected for both clock and control then the default value of the mux output is 1. Slice 3 does not have any registers; therefore it does not have the clock or control muxes. Figure 2-17. Slice0 through Slice2 Clock Selection Primary Clock Secondary Clock 8 Clock to Slice 7 28:1 Routing 12 Vcc 1 Figure 2-18. Slice0 through Slice2 Control Selection Secondary Control 5 Slice Control Routing 20:1 14 Vcc 1 2-16 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Edge Clock Sources Edge clock resources can be driven from a variety of sources at the same edge. Edge clock resources can be driven from adjacent edge clock PIOs, primary clock PIOs, PLLs, DLLs, Slave Delay and clock dividers as shown in Figure 2-19. Figure 2-19. Edge Clock Sources Clock Input Clock Input From Routing SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N From Routing Sources for top edge clocks From Routing From Routing Clock Input Clock Input Clock Input Clock Input From Routing Slave Delay Six Edge Clocks (ECLK) Two Clocks per Edge From Routing Slave Delay DLL Input DLL DLL DLL Input PLL Input PLL PLL PLL Input Sources for right edge clocks Sources for left edge clocks Notes: 1. Clock inputs can be configured in differential or single ended mode. 2. The two DLLs can also drive the two top edge clocks. 3. The top left and top right PLL can also drive the two top edge clocks. Edge Clock Routing LatticeECP3 devices have a number of high-speed edge clocks that are intended for use with the PIOs in the implementation of high-speed interfaces. There are six edge clocks per device: two edge clocks on each of the top, left, and right edges. Different PLL and DLL outputs are routed to the two muxes on the left and right sides of the device. In addition, the CLKINDEL signal (generated from the DLL Slave Delay Line block) is routed to all the edge clock muxes on the left and right sides of the device. Figure 2-20 shows the selection muxes for these clocks. 2-17 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-20. Sources of Edge Clock (Left and Right Edges) Input Pad Left and Right PLL Input Pad Edge Clocks DLL Output CLKOP ECLK1 6:1 PLL Output CLKOP SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Routing CLKINDEL from DLL Slave Delay Input Pad Left and Right PLL Input Pad Edge Clocks DLL Output CLKOS ECLK2 6:1 PLL Output CLKOS Routing CLKINDEL from DLL Slave Delay Figure 2-21. Sources of Edge Clock (Top Edge) Input Pad Top left PLL_CLKOP Top Right PLL_CLKOS ECLK1 7:1 Left DLL_CLKOP Right DLL_CLKOS Routing CLKINDEL (Left DLL_DEL) Input Pad Top Right PLL_CLKOP ECLK2 Top Left PLL_CLKOS 7:1 Right DLL_CLKOP Left DLL_CLKOS Routing CLKINDEL (Right DLL_DEL) The edge clocks have low injection delay and low skew. They are used to clock the I/O registers and thus are ideal for creating I/O interfaces with a single clock signal and a wide data bus. They are also used for DDR Memory or Generic DDR interfaces. 2-18 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor The edge clocks on the top, left, and right sides of the device can drive the secondary clocks or general routing resources of the device. The left and right side edge clocks also can drive the primary clock network through the clock dividers (CLKDIV). sysMEM Memory LatticeECP3 devices contain a number of sysMEM Embedded Block RAM (EBR). The EBR consists of an 18-Kbit RAM with memory core, dedicated input registers and output registers with separate clock and clock enable. Each EBR includes functionality to support true dual-port, pseudo dual-port, single-port RAM, ROM and FIFO buffers (via external PFUs). SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N sysMEM Memory Block The sysMEM block can implement single port, dual port or pseudo dual port memories. Each block can be used in a variety of depths and widths as shown in Table 2-7. FIFOs can be implemented in sysMEM EBR blocks by implementing support logic with PFUs. The EBR block facilitates parity checking by supporting an optional parity bit for each data byte. EBR blocks provide byte-enable support for configurations with18-bit and 36-bit data widths. For more information, please see TN1179, LatticeECP3 Memory Usage Guide. Table 2-7. sysMEM Block Configurations Memory Mode Configurations Single Port 16,384 x 1 8,192 x 2 4,096 x 4 2,048 x 9 1,024 x 18 512 x 36 True Dual Port 16,384 x 1 8,192 x 2 4,096 x 4 2,048 x 9 1,024 x 18 Pseudo Dual Port 16,384 x 1 8,192 x 2 4,096 x 4 2,048 x 9 1,024 x 18 512 x 36 Bus Size Matching All of the multi-port memory modes support different widths on each of the ports. The RAM bits are mapped LSB word 0 to MSB word 0, LSB word 1 to MSB word 1, and so on. Although the word size and number of words for each port varies, this mapping scheme applies to each port. RAM Initialization and ROM Operation If desired, the contents of the RAM can be pre-loaded during device configuration. By preloading the RAM block during the chip configuration cycle and disabling the write controls, the sysMEM block can also be utilized as a ROM. Memory Cascading Larger and deeper blocks of RAM can be created using EBR sysMEM Blocks. Typically, the Lattice design tools cascade memory transparently, based on specific design inputs. 2-19 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Single, Dual and Pseudo-Dual Port Modes In all the sysMEM RAM modes the input data and address for the ports are registered at the input of the memory array. The output data of the memory is optionally registered at the output. EBR memory supports the following forms of write behavior for single port or dual port operation: 1. Normal – Data on the output appears only during a read cycle. During a write cycle, the data (at the current address) does not appear on the output. This mode is supported for all data widths. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 2. Write Through – A copy of the input data appears at the output of the same port during a write cycle. This mode is supported for all data widths. 3. Read-Before-Write (EA devices only) – When new data is written, the old content of the address appears at the output. This mode is supported for x9, x18, and x36 data widths. Memory Core Reset The memory array in the EBR utilizes latches at the A and B output ports. These latches can be reset asynchronously or synchronously. RSTA and RSTB are local signals, which reset the output latches associated with Port A and Port B, respectively. The Global Reset (GSRN) signal can reset both ports. The output data latches and associated resets for both ports are as shown in Figure 2-22. Figure 2-22. Memory Core Reset Memory Core D SET Q Port A[17:0] LCLR Output Data Latches D SET Q Port B[17:0] LCLR RSTA RSTB GSRN Programmable Disable For further information on the sysMEM EBR block, please see the list of technical documentation at the end of this data sheet. sysDSP™ Slice The LatticeECP3 family provides an enhanced sysDSP architecture, making it ideally suited for low-cost, high-performance Digital Signal Processing (DSP) applications. Typical functions used in these applications are Finite Impulse Response (FIR) filters, Fast Fourier Transforms (FFT) functions, Correlators, Reed-Solomon/Turbo/Convolution encoders and decoders. These complex signal processing functions use similar building blocks such as multiply-adders and multiply-accumulators. sysDSP Slice Approach Compared to General DSP Conventional general-purpose DSP chips typically contain one to four (Multiply and Accumulate) MAC units with fixed data-width multipliers; this leads to limited parallelism and limited throughput. Their throughput is increased by higher clock speeds. The LatticeECP3, on the other hand, has many DSP slices that support different data widths. 2-20 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor This allows designers to use highly parallel implementations of DSP functions. Designers can optimize DSP performance vs. area by choosing appropriate levels of parallelism. Figure 2-23 compares the fully serial implementation to the mixed parallel and serial implementation. Figure 2-23. Comparison of General DSP and LatticeECP3 Approaches Operand A Operand A Operand B Operand B Operand B Operand B SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Operand A Operand A Single Multiplier x M loops x Multiplier 0 x x Multiplier 1 m/k loops Multiplier k Accumulator (k adds) Function Implemented in General Purpose DSP + m/k accumulate Output Function Implemented in LatticeECP3 LatticeECP3 sysDSP Slice Architecture Features The LatticeECP3 sysDSP Slice has been significantly enhanced to provide functions needed for advanced processing applications. These enhancements provide improved flexibility and resource utilization. The LatticeECP3 sysDSP Slice supports many functions that include the following: • Multiply (one 18x36, two 18x18 or four 9x9 Multiplies per Slice) • Multiply (36x36 by cascading across two sysDSP slices) • Multiply Accumulate (up to 18x36 Multipliers feeding an Accumulator that can have up to 54-bit resolution) • Two Multiplies feeding one Accumulate per cycle for increased processing with lower latency (two 18x18 Multiplies feed into an accumulator that can accumulate up to 52 bits) • Flexible saturation and rounding options to satisfy a diverse set of applications situations • Flexible cascading across DSP slices – Minimizes fabric use for common DSP and ALU functions – Enables implementation of FIR Filter or similar structures using dedicated sysDSP slice resources only – Provides matching pipeline registers – Can be configured to continue cascading from one row of sysDSP slices to another for longer cascade chains • Flexible and Powerful Arithmetic Logic Unit (ALU) Supports: – Dynamically selectable ALU OPCODE – Ternary arithmetic (addition/subtraction of three inputs) – Bit-wise two-input logic operations (AND, OR, NAND, NOR, XOR and XNOR) – Eight flexible and programmable ALU flags that can be used for multiple pattern detection scenarios, such 2-21 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor as, overflow, underflow and convergent rounding, etc. – Flexible cascading across slices to get larger functions • RTL Synthesis friendly synchronous reset on all registers, while still supporting asynchronous reset for legacy users • Dynamic MUX selection to allow Time Division Multiplexing (TDM) of resources for applications that require processor-like flexibility that enables different functions for each clock cycle SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N For most cases, as shown in Figure 2-24, the LatticeECP3 DSP slice is backwards-compatible with the LatticeECP2™ sysDSP block, such that, legacy applications can be targeted to the LatticeECP3 sysDSP slice. The functionality of one LatticeECP2 sysDSP Block can be mapped into two adjacent LatticeECP3 sysDSP slices, as shown in Figure 2-25. Figure 2-24. Simplified sysDSP Slice Block Diagram From FPGA Core Slice 0 Input Registers from SRO of Left-side DSP Slice 1 Casc A0 IR IR IR IR MULTA MULTB 9x9 9x9 9x9 IR IR IR IR MULTA 9x9 9x9 9x9 Casc A1 MULTB 9x9 9x9 Mult18-0 Mult18-1 Mult18-0 Mult18-1 PR PR PR PR Intermediate Pipeline Registers Cascade from Left DSP Carry Out Reg. Accumulator/ALU (54) Carry Out Reg. Accumulator/ALU (54) ALU Op-Codes Output Registers OR OR OR OR OR To FPGA Core 2-22 OR OR One of these OR Cascade to Right DSP Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-25. Detailed sysDSP Slice Diagram From FPGA Core C AA AB OPCODE BA BB SRIB SROB IR IR IR IR IR SROA SRIA MULTA MULTB IR IR PR PR SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N PR A_ALU 0 Previous DSP Slice B_ALU 0 Next DSP Slice BMUX AMUX C_ALU CMUX CIN A_ALU Rounding COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR FR OR To FPGA Core Note: A_ALU, B_ALU and C_ALU are internal signals generated by combining bits from AA, AB, BA BB and C inputs. See TN1182, LatticeECP3 sysDSP Usage Guide, for further information. The LatticeECP2 sysDSP block supports the following basic elements. • MULT (Multiply) • MAC (Multiply, Accumulate) • MULTADDSUB (Multiply, Addition/Subtraction) • MULTADDSUBSUM (Multiply, Addition/Subtraction, Summation) Table 2-8 shows the capabilities of each of the LatticeECP3 slices versus the above functions. Table 2-8. Maximum Number of Elements in a Slice Width of Multiply x9 x18 x36 MULT 4 2 1/2 MAC 1 1 — MULTADDSUB 2 1 — MULTADDSUBSUM 11 1/2 — 1. One slice can implement 1/2 9x9 m9x9addsubsum and two m9x9addsubsum with two slices. Some options are available in the four elements. The input register in all the elements can be directly loaded or can be loaded as a shift register from previous operand registers. By selecting “dynamic operation” the following operations are possible: • In the Add/Sub option the Accumulator can be switched between addition and subtraction on every cycle. • The loading of operands can switch between parallel and serial operations. 2-23 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor For further information, please refer to TN1182, LatticeECP3 sysDSP Usage Guide. MULT DSP Element This multiplier element implements a multiply with no addition or accumulator nodes. The two operands, AA and AB, are multiplied and the result is available at the output. The user can enable the input/output and pipeline registers. Figure 2-26 shows the MULT sysDSP element. Figure 2-26. MULT sysDSP Element SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N From FPGA Core C AA AB OPCODE BA BB SRIB SROB IR IR IR IR IR SROA SRIA MULTA MULTB IR IR PR PR A_ALU 0 Previous DSP Slice CMUX CIN PR 0 Next DSP Slice BMUX AMUX C_ALU A_ALU Rounding B_ALU COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR To FPGA Core 2-24 FR OR Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor MAC DSP Element In this case, the two operands, AA and AB, are multiplied and the result is added with the previous accumulated value. This accumulated value is available at the output. The user can enable the input and pipeline registers, but the output register is always enabled. The output register is used to store the accumulated value. The ALU is configured as the accumulator in the sysDSP slice in the LatticeECP3 family can be initialized dynamically. A registered overflow signal is also available. The overflow conditions are provided later in this document. Figure 2-27 shows the MAC sysDSP element. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Figure 2-27. MAC DSP Element From FPGA Core C AA AB OPCODE BA BB SRIB SROB IR IR IR IR IR SROA SRIA MULTA MULTB IR I PR PR A_ALU 0 Previous DSP Slice CMUX CIN PR 0 Next DSP Slice BMUX AMUX C_ALU A_ALU Rounding B_ALU COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR To FPGA Core 2-25 FR OR Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor MMAC DSP Element The LatticeECP3 supports a MAC with two multipliers. This is called Multiply Multiply Accumulate or MMAC. In this case, the two operands, AA and AB, are multiplied and the result is added with the previous accumulated value and with the result of the multiplier operation of operands BA and BB. This accumulated value is available at the output. The user can enable the input and pipeline registers, but the output register is always enabled. The output register is used to store the accumulated value. The ALU is configured as the accumulator in the sysDSP slice. A registered overflow signal is also available. The overflow conditions are provided later in this document. Figure 2-28 shows the MMAC sysDSP element. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Figure 2-28. MMAC sysDSP Element From FPGA Core C AA AB OPCODE BA BB SRIB SROB IR IR IR IR IR SROA SRIA MULTA MULTB IR IR PR PR A_ALU 0 Previous DSP Slice B_ALU 0 Next DSP Slice BMUX AMUX C_ALU PR CMUX CIN A_ALU Rounding COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR To FPGA Core 2-26 FR OR Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor MULTADDSUB DSP Element In this case, the operands AA and AB are multiplied and the result is added/subtracted with the result of the multiplier operation of operands BA and BB. The user can enable the input, output and pipeline registers. Figure 2-29 shows the MULTADDSUB sysDSP element. Figure 2-29. MULTADDSUB From FPGA Core C AA AB OPCODE BA BB SROB SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N SRIB IR IR IR IR IR SROA SRIA MULTA MULTB IR IR PR PR A_ALU 0 Previous DSP Slice CMUX PR 0 Next DSP Slice BMUX AMUX C_ALU CIN A_ALU Rounding B_ALU COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR To FPGA Core 2-27 FR OR Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor MULTADDSUBSUM DSP Element In this case, the operands AA and AB are multiplied and the result is added/subtracted with the result of the multiplier operation of operands BA and BB of Slice 0. Additionally, the operands AA and AB are multiplied and the result is added/subtracted with the result of the multiplier operation of operands BA and BB of Slice 1. The results of both addition/subtractions are added by the second ALU following the slice cascade path. The user can enable the input, output and pipeline registers. Figure 2-30 and Figure 2-31 show the MULTADDSUBSUM sysDSP element. Figure 2-30. MULTADDSUBSUM Slice 0 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N From FPGA Core C AA AB OPCODE BA BB SRIB SROB IR IR IR IR IR SROA SRIA MULTA MULTB I IR PR PR A_ALU 0 Previous DSP Slice CMUX PR Next DSP Slice BMUX AMUX C_ALU CIN A_ALU Rounding B_ALU 0 COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR To FPGA Core 2-28 FR OR Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-31. MULTADDSUBSUM Slice 1 From FPGA Core C AA AB OPCODE BA BB SRIB SROB IR IR IR IR IR SROA SRIA MULTA MULTB IR IR PR PR A_ALU 0 PR 0 Next DSP Slice SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Previous DSP Slice B_ALU CMUX CIN A_ALU Rounding BMUX AMUX C_ALU COUT R= A ± B ± C R = Logic (B, C) ALU 0 == IR = Input Register PR = Pipeline Register OR = Output Register FR = Flag Register OR OR FR OR To FPGA Core Advanced sysDSP Slice Features Cascading The LatticeECP3 sysDSP slice has been enhanced to allow cascading. Adder trees are implemented fully in sysDSP slices, improving the performance. Cascading of slices uses the signals CIN, COUT and C Mux of the slice. Addition The LatticeECP3 sysDSP slice allows for the bypassing of multipliers and cascading of adder logic. High performance adder functions are implemented without the use of LUTs. The maximum width adders that can be implemented are 54-bit. Rounding The rounding operation is implemented in the ALU and is done by adding a constant followed by a truncation operation. The rounding methods supported are: • Rounding to zero (RTZ) • Rounding to infinity (RTI) • Dynamic rounding • Random rounding • Convergent rounding 2-29 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor ALU Flags The sysDSP slice provides a number of flags from the ALU including: • Equal to zero (EQZ) • Equal to zero with mask (EQZM) • Equal to one with mask (EQOM) • Equal to pattern with mask (EQPAT) SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N • Equal to bit inverted pattern with mask (EQPATB) • Accumulator Overflow (OVER) • Accumulator Underflow (UNDER) • Either over or under flow supporting LatticeECP2 legacy designs (OVERUNDER) Clock, Clock Enable and Reset Resources Global Clock, Clock Enable and Reset signals from routing are available to every sysDSP slice. From four clock sources (CLK0, CLK1, CLK2, and CLK3) one clock is selected for each input register, pipeline register and output register. Similarly Clock Enable (CE) and Reset (RST) are selected at each input register, pipeline register and output register. Resources Available in the LatticeECP3 Family Table 2-9 shows the maximum number of multipliers for each member of the LatticeECP3 family. Table 2-10 shows the maximum available EBR RAM Blocks in each LatticeECP3 device. EBR blocks, together with Distributed RAM can be used to store variables locally for fast DSP operations. Table 2-9. Maximum Number of DSP Slices in the LatticeECP3 Family Device DSP Slices 9x9 Multiplier 18x18 Multiplier 36x36 Multiplier ECP3-17 12 48 24 6 ECP3-35 32 128 64 16 ECP3-70 64 256 128 32 ECP3-95 64 256 128 32 ECP3-150 160 640 320 80 Table 2-10. Embedded SRAM in the LatticeECP3 Family Device EBR SRAM Block Total EBR SRAM (Kbits) ECP3-17 38 700 ECP3-35 72 1327 ECP3-70 240 4420 ECP3-95 240 4420 ECP3-150 372 6850 2-30 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Programmable I/O Cells (PIC) Each PIC contains two PIOs connected to their respective sysI/O buffers as shown in Figure 2-32. The PIO Block supplies the output data (DO) and the tri-state control signal (TO) to the sysI/O buffer and receives input from the buffer. Table 2-11 provides the PIO signal list. Figure 2-32. PIC Diagram I/Os in a DQS-12 Group, Except DQSN (Complement of DQS) I/Os PIOA SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N TS ONEGB IOLT0 Tristate Register Block OPOSA OPOSB ONEGA** ONEGB** PADA “T” IOLD0 Output Register Block (ISI) INDD INCK INB IPB INA IPA DEL[3:0] ECLK1, ECLK2 SCLK CE LSR GSRN Input Register Block Control Muxes CLK CEOT LSR GSR CEI sysIO Buffer DI PADB “C” PIOB DQS Control Block (One per DQS Group of 12 I/Os)*** Read Control ECLK1 ECLK2 SCLK READ DCNTL[5:0] DYNDEL[7:0] DQSI PRMDET DDRLAT* DDRCLKPOL* ECLKDQSR* Write Control DQCLK0* DQCLK1* DQSW* * Signals are available on left/right/top edges only. ** Signals are available on the left and right sides only *** Selected PIO. 2-31 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Two adjacent PIOs can be joined to provide a differential I/O pair (labeled as “T” and “C”) as shown in Figure 2-32. The PAD Labels “T” and “C” distinguish the two PIOs. Approximately 50% of the PIO pairs on the left and right edges of the device can be configured as true LVDS outputs. All I/O pairs can operate as LVDS inputs. Table 2-11. PIO Signal List Name Type Description INDD Input Data Register bypassed input. This is not the same port as INCK. IPA, INA, IPB, INB Input Data Ports to core for input data 1 OPOSA, ONEGA , OPOSB, ONEGB1 Output Data CE PIO Control Clock enables for input and output block flip-flops. SCLK PIO Control System Clock (PCLK) for input and output/TS blocks. Connected from clock ISB. LSR PIO Control Local Set/Reset ECLK1, ECLK2 PIO Control Edge clock sources. Entire PIO selects one of two sources using mux. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Output signals from core. An exception is the ONEGB port, used for tristate logic at the DQS pad. ECLKDQSR1 Read Control DDRCLKPOL1 Read Control Ensures transfer from DQS domain to SCLK domain. DDRLAT1 Read Control Used to guarantee INDDRX2 gearing by selectively enabling a D-Flip-Flop in datapath. DEL[3:0] Read Control Dynamic input delay control bits. INCK From DQS_STROBE, shifted strobe for memory interfaces only. To Clock Distribution PIO treated as clock PIO, path to distribute to primary clocks and PLL. and PLL TS Tristate Data Tristate signal from core (SDR) DQCLK01, DQCLK11 Write Control Two clocks edges, 90 degrees out of phase, used in output gearing. DQSW2 Write Control Used for output and tristate logic at DQS only. DYNDEL[7:0] Write Control Shifting of write clocks for specific DQS group, using 6:0 each step is approximately 25ps, 128 steps. Bit 7 is an invert (timing depends on input frequency). There is also a static control for this 8-bit setting, enabled with a memory cell. DCNTL[6:0] 1 DATAVALID READ PIO Control Original delay code from DDR DLL Output Data Status flag from DATAVALID logic, used to indicate when input data is captured in IOLOGIC and valid to core. For DQS_Strobe Read signal for DDR memory interface DQSI For DQS_Strobe Unshifted DQS strobe from input pad PRMBDET For DQS_Strobe DQSI biased to go high when DQSI is tristate, goes to input logic block as well as core logic. GSRN Control from routing Global Set/Reset 1. Signals available on left/right/top edges only. 2. Selected PIO. PIO The PIO contains four blocks: an input register block, output register block, tristate register block and a control logic block. These blocks contain registers for operating in a variety of modes along with the necessary clock and selection logic. Input Register Block The input register blocks for the PIOs, in the left, right and top edges, contain delay elements and registers that can be used to condition high-speed interface signals, such as DDR memory interfaces and source synchronous interfaces, before they are passed to the device core. Figure 2-33 shows the input register block for the left, right and top edges. The input register block for the bottom edge contains one element to register the input signal and no DDR registers. The following description applies to the input register block for PIOs in the left, right and top edges only. 2-32 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Input signals are fed from the sysI/O buffer to the input register block (as signal DI). If desired, the input signal can bypass the register and delay elements and be used directly as a combinatorial signal (INDD), a clock (INCK) and, in selected blocks, the input to the DQS delay block. If an input delay is desired, designers can select either a fixed delay or a dynamic delay DEL[3:0]. The delay, if selected, reduces input register hold time requirements when using a global clock. The input block allows three modes of operation. In single data rate (SDR) the data is registered with the system clock by one of the registers in the single data rate sync register block. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N In DDR mode, two registers are used to sample the data on the positive and negative edges of the modified DQS (ECLKDQSR) in the DDR Memory mode or ECLK signal when using DDR Generic mode, creating two data streams. Before entering the core, these two data streams are synchronized to the system clock to generate two data streams. A gearbox function can be implemented in each of the input registers on the left and right sides. The gearbox function takes a double data rate signal applied to PIOA and converts it as four data streams, INA, IPA, INB and IPB. The two data streams from the first set of DDR registers are synchronized to the edge clock and then to the system clock before entering the core. Figure 2-30 provides further information on the use of the gearbox function. The signal DDRCLKPOL controls the polarity of the clock used in the synchronization registers. It ensures adequate timing when data is transferred to the system clock domain from the ECLKDQSR (DDR Memory Interface mode) or ECLK (DDR Generic mode). The DDRLAT signal is used to ensure the data transfer from the synchronization registers to the clock transfer and gearbox registers. The ECLKDQSR, DDRCLKPOL and DDRLAT signals are generated in the DQS Read Control Logic Block. See Figure 2-37 for an overview of the DQS read control logic. Further discussion about using the DQS strobe in this module is discussed in the DDR Memory section of this data sheet. Please see TN1180, LatticeECP3 High-Speed I/O Interface for more information on this topic. 2-33 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-33. ECP3-70/95 (E or EA) Input Register Block for Left, Right and Top Edges Clock Transfer & Gearing Registers* INCLK** INDD To DQSI** Fixed Delay DI Dynamic Delay (From sysIO Buffer) Synch Registers DDR Registers 0 1 A D D Q D Q F D Q DDRLAT H D Q Config bit X0 01 11 L D Q CE INB R L B DEL[3:0] D Q C D Q E D Q G D Q X0 01 11 K D Q IPB SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N D Q L L ECLKDQSR ECLK2 D Q J D Q INA D Q IPA CLKP L DDRCLKPOL ECLK1 ECLK2 D Q 1 0 10 D Q I L L SCLK * Only on the left and right sides. ** Selected PIO. Note: Simplified diagram does not show CE/SET/REST details. Output Register Block The output register block registers signals from the core of the device before they are passed to the sysI/O buffers. The blocks on the left and right PIOs contain registers for SDR and full DDR operation. The topside PIO block is the same as the left and right sides except it does not support ODDRX2 gearing of output logic. ODDRX2 gearing is used in DDR3 memory interfaces.The PIO blocks on the bottom contain the SDR registers and generic DDR interface without gearing. Figure 2-34 shows the Output Register Block for PIOs on the left and right edges. In SDR mode, OPOSA feeds one of the flip-flops that then feeds the output. The flip-flop can be configured as a Dtype or latch. In DDR mode, two of the inputs are fed into registers on the positive edge of the clock. At the next clock cycle, one of the registered outputs is also latched. A multiplexer running off the same clock is used to switch the mux between the 11 and 01 inputs that will then feed the output. A gearbox function can be implemented in the output register block that takes four data streams: OPOSA, ONEGA, OPOSB and ONEGB. All four data inputs are registered on the positive edge of the system clock and two of them are also latched. The data is then output at a high rate using a multiplexer that runs off the DQCLK0 and DQCLK1 clocks. DQCLK0 and DQCLK1 are used in this case to transfer data from the system clock to the edge clock domain. These signals are generated in the DQS Write Control Logic block. See Figure 2-37 for an overview of the DQS write control logic. Please see TN1180, LatticeECP3 High-Speed I/O Interface for more information on this topic. Further discussion on using the DQS strobe in this module is discussed in the DDR Memory section of this data sheet. 2-34 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-34. ECP3-70/95 (E or EA) Output and Tristate Block for Left and Right Edges Tristate Logic TS TO D Q D Q CE R SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Output Logic OPOSA D Q CE R ONEGA D Q A B OPOSB C1 D Q D Q 11 DO 10 C 00 D 01 ISI L ONEGB D Q D1 D Q L DDR Gearing & ISI Correction Clock Transfer Registers SCLK DQCLK1 Config Bit DQCLK0 Tristate Register Block The tristate register block registers tri-state control signals from the core of the device before they are passed to the sysI/O buffers. The block contains a register for SDR operation and an additional register for DDR operation. In SDR and non-gearing DDR modes, TS input feeds one of the flip-flops that then feeds the output. In DDRX2 mode, the register TS input is fed into another register that is clocked using the DQCLK0 and DQCLK1 signals. The output of this register is used as a tristate control. ISI Calibration The setting for Inter-Symbol Interference (ISI) cancellation occurs in the output register block. ISI correction is only available in the DDRX2 modes. ISI calibration settings exist once per output register block, so each I/O in a DQS12 group may have a different ISI calibration setting. The ISI block extends output signals at certain times, as a function of recent signal history. So, if the output pattern consists of a long strings of 0's to long strings of 1's, there are no delays on output signals. However, if there are quick, successive transitions from 010, the block will stretch out the binary 1. This is because the long trail of 0's will cause these symbols to interfere with the logic 1. Likewise, if there are quick, successive transitions from 101, the block will stretch out the binary 0. This block is controlled by a 3-bit delay control that can be set in the DQS control logic block. For more information about this topic, please see the list of technical documentation at the end of this data sheet. 2-35 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Control Logic Block The control logic block allows the selection and modification of control signals for use in the PIO block. DDR Memory Support Certain PICs have additional circuitry to allow the implementation of high-speed source synchronous and DDR1, DDR2 and DDR3 memory interfaces. The support varies by the edge of the device as detailed below. Left and Right Edges SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N The left and right sides of the PIC have fully functional elements supporting DDR1, DDR2, and DDR3 memory interfaces. One of every 12 PIOs supports the dedicated DQS pins with the DQS control logic block. Figure 2-35 shows the DQS bus spanning 11 I/O pins. Two of every 12 PIOs support the dedicated DQS and DQS# pins with the DQS control logic block. Bottom Edge PICs on the bottom edge of the device do not support DDR memory and Generic DDR interfaces. Top Edge PICs on the top side are similar to the PIO elements on the left and right sides but do not support gearing on the output registers. Hence, the modes to support output/tristate DDR3 memory are removed on the top side. The exact DQS pins are shown in a dual function in the Logic Signal Connections table in this data sheet. Additional detail is provided in the Signal Descriptions table. The DQS signal from the bus is used to strobe the DDR data from the memory into input register blocks. Interfaces on the left, right and top edges are designed for DDR memories that support 10 bits of data. Figure 2-35. DQS Grouping on the Left, Right and Top Edges PIO A PADA "T" PIO B PADB "C" LVDS Pair PIO A PADA "T" PIO B PADB "C" PIO A PADA "T" PIO B PADB "C" LVDS Pair LVDS Pair PIO A DQS sysIO Buffer Delay PIO B Assigned DQS Pin PADA "T" LVDS Pair PADB "C" PIO A PADA "T" PIO B PADB "C" PIO A PADA "T" PIO B PADB "C" LVDS Pair LVDS Pair DLL Calibrated DQS Delay Block Source synchronous interfaces generally require the input clock to be adjusted in order to correctly capture data at the input register. For most interfaces, a PLL is used for this adjustment. However, in DDR memories the clock 2-36 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor (referred to as DQS) is not free-running so this approach cannot be used. The DQS Delay block provides the required clock alignment for DDR memory interfaces. The delay required for the DQS signal is generated by two dedicated DLLs (DDR DLL) on opposite side of the device. Each DLL creates DQS delays in its half of the device as shown in Figure 2-36. The DDR DLL on the left side will generate delays for all the DQS Strobe pins on Banks 0, 7 and 6 and DDR DLL on the right will generate delays for all the DQS pins on Banks 1, 2 and 3. The DDR DLL loop compensates for temperature, voltage and process variations by using the system clock and DLL feedback loop. DDR DLL communicates the required delay to the DQS delay block using a 7-bit calibration bus (DCNTL[6:0]) SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N The DQS signal (selected PIOs only, as shown in Figure 2-35) feeds from the PAD through a DQS control logic block to a dedicated DQS routing resource. The DQS control logic block consists of DQS Read Control logic block that generates control signals for the read side and DQS Write Control logic that generates the control signals required for the write side. A more detailed DQS control diagram is shown in Figure 2-37, which shows how the DQS control blocks interact with the data paths. The DQS Read control logic receives the delay generated by the DDR DLL on its side and delays the incoming DQS signal by 90 degrees. This delayed ECLKDQSR is routed to 10 or 11 DQ pads covered by that DQS signal. This block also contains a polarity control logic that generates a DDRCLKPOL signal, which controls the polarity of the clock to the sync registers in the input register blocks. The DQS Read control logic also generates a DDRLAT signal that is in the input register block to transfer data from the first set of DDR register to the second set of DDR registers when using the DDRX2 gearbox mode for DDR3 memory interface. The DQS Write control logic block generates the DQCLK0 and DQCLK1 clocks used to control the output gearing in the Output register block which generates the DDR data output and the DQS output. They are also used to control the generation of the DQS output through the DQS output register block. In addition to the DCNTL [6:0] input from the DDR DLL, the DQS Write control block also uses a Dynamic Delay DYN DEL [7:0] attribute which is used to further delay the DQS to accomplish the write leveling found in DDR3 memory. Write leveling is controlled by the DDR memory controller implementation. The DYN DELAY can set 128 possible delay step settings. In addition, the most significant bit will invert the clock for a 180-degree shift of the incoming clock. This will generate the DQSW signal used to generate the DQS output in the DQS output register block. Figure 2-36 and Figure 2-37 show how the DQS transition signals that are routed to the PIOs. Please see TN1180, LatticeECP3 High-Speed I/O Interface for more information on this topic. 2-37 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-36. Edge Clock, DLL Calibration and DQS Local Bus Distribution Bank 0 DQS DQS DQS Bank 1 DQS DQS DQS DQS Configuration Bank DQS DQS DQS DQS Delay Control Bus ECLK1 ECLK2 Bank 7 DQS DQS DDR DLL (Right) DQS DDR DLL (Left) Bank 2 DQS SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N DQS DQS DQCLK0 DQCLK1 DDRLAT DDRCLKPOL ECLKDQSR DATAVALID DQS DQS DQS DQS DQS DQS Strobe and Transition Detect Logic I/O Ring *Includes shared configuration I/Os and dedicated configuration I/Os. 2-38 Bank 3 Bank 6 DQS DQS SERDES Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor DCNTL[6:0] ECLKDQSR DDRCLKPOL DDRLAT DQSW DQCLK1 DQCLK0 Figure 2-37. DQS Local Bus DDR Data Pad SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Data Output Register Block Data Input Register Block DQS Output Register Block DQS Write Control Logic DQS Pad DQS Read Control Logic DQS Delay Block DDR DLL Polarity Control Logic In a typical DDR Memory interface design, the phase relationship between the incoming delayed DQS strobe and the internal system clock (during the READ cycle) is unknown. The LatticeECP3 family contains dedicated circuits to transfer data between these domains. A clock polarity selector is used to prevent set-up and hold violations at the domain transfer between DQS (delayed) and the system clock. This changes the edge on which the data is registered in the synchronizing registers in the input register block. This requires evaluation at the start of each READ cycle for the correct clock polarity. Prior to the READ operation in DDR memories, DQS is in tristate (pulled by termination). The DDR memory device drives DQS low at the start of the preamble state. A dedicated circuit detects the first DQS rising edge after the preamble state. This signal is used to control the polarity of the clock to the synchronizing registers. DDR3 Memory Support LatticeECP3 supports the read and write leveling required for DDR3 memory interfaces. Read leveling is supported by the use of the DDRCLKPOL and the DDRLAT signals generated in the DQS Read Control logic block. These signals dynamically control the capture of the data with respect to the DQS at the input register block. 2-39 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor To accomplish write leveling in DDR3, each DQS group has a slightly different delay that is set by DYN DELAY[7:0] in the DQS Write Control logic block. The DYN DELAY can set 128 possible delay step settings. In addition, the most significant bit will invert the clock for a 180-degree shift of the incoming clock. LatticeECP3 input and output registers can also support DDR gearing that is used to receive and transmit the high speed DDR data from and to the DDR3 Memory. LatticeECP3 supports the 1.5V SSTL I/O standard required for the DDR3 memory interface. In addition, it supports on-chip termination to VTT on the DDR3 memory input pins. For more information, refer to the sysIO section of this data sheet. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Please see TN1180, LatticeECP3 High-Speed I/O Interface for more information on DDR Memory interface implementation in LatticeECP3. sysI/O Buffer Each I/O is associated with a flexible buffer referred to as a sysI/O buffer. These buffers are arranged around the periphery of the device in groups referred to as banks. The sysI/O buffers allow users to implement the wide variety of standards that are found in today’s systems including LVDS, BLVDS, HSTL, SSTL Class I & II, LVCMOS, LVTTL, LVPECL, PCI. sysI/O Buffer Banks LatticeECP3 devices have six sysI/O buffer banks: six banks for user I/Os arranged two per side. The banks on the bottom side are wraparounds of the banks on the lower right and left sides. The seventh sysI/O buffer bank (Configuration Bank) is located adjacent to Bank 2 and has dedicated/shared I/Os for configuration. When a shared pin is not used for configuration it is available as a user I/O. Each bank is capable of supporting multiple I/O standards. Each sysI/O bank has its own I/O supply voltage (VCCIO). In addition, each bank, except the Configuration Bank, has voltage references, VREF1 and VREF2, which allow it to be completely independent from the others. The Configuration Bank top side shares VREF1 and VREF2 from sysI/O bank 1 and right side shares VREF1 and VREF2 from sysI/O bank 2. Figure 2-38 shows the seven banks and their associated supplies. In LatticeECP3 devices, single-ended output buffers and ratioed input buffers (LVTTL, LVCMOS and PCI) are powered using VCCIO. LVTTL, LVCMOS33, LVCMOS25 and LVCMOS12 can also be set as fixed threshold inputs independent of VCCIO. Each bank can support up to two separate VREF voltages, VREF1 and VREF2, that set the threshold for the referenced input buffers. Some dedicated I/O pins in a bank can be configured to be a reference voltage supply pin. Each I/O is individually configurable based on the bank’s supply and reference voltages. 2-40 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-38. LatticeECP3 Banks TOP V REF1(1) VREF2(1) Configuration Bank JTAG Bank Bank 1 GND V REF2(6) V CCIO6 Bank 3 V REF1(6) Bank 6 LEFT V CCIO7 Bank 2 V REF2(7) Bank 7 V REF1(7) GND VREF1(2) V REF2(2) VCCIO2 GND RIGHT SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N VCCIO1 GND VREF1(0) VREF2(0) V CCIO0 GND Bank 0 V REF1(3) V REF2(3) VCCIO3 GND SERDES Quads BOTTOM LatticeECP3 devices contain two types of sysI/O buffer pairs. 1. Top (Bank 0 and Bank 1) and Bottom sysI/O Buffer Pairs (Single-Ended Outputs Only) The sysI/O buffer pairs in the top banks of the device consist of two single-ended output drivers and two sets of single-ended input buffers (both ratioed and referenced). One of the referenced input buffers can also be configured as a differential input. Only the top edge buffers have a programmable PCI clamp.  The two pads in the pair are described as “true” and “comp”, where the true pad is associated with the positive side of the differential input buffer and the comp (complementary) pad is associated with the negative side of the differential input buffer.   On the top and bottom sides, there is no support for programmable on-chip input termination, which is required for DQ and DQS pins for DDR3 interface. This side is ideal for ADDR/CMD signals of DDR3, general purpose  I/O, PCI, TR-LVDS (transition reduced LVDS) or LVDS inputs. Only the top I/O banks support hot socketing with IDK specified under the Hot Socketing Specifications. The configuration bank is not hot-socketable. 2-41 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 2. Left and Right (Banks 2, 3, 6 and 7) sysI/O Buffer Pairs (50% Differential and 100% Single-Ended Outputs) The sysI/O buffer pairs in the left and right banks of the device consist of two single-ended output drivers, two sets of single-ended input buffers (both ratioed and referenced) and one differential output driver. One of the referenced input buffers can also be configured as a differential input. In these banks the two pads in the pair are described as “true” and “comp”, where the true pad is associated with the positive side of the differential I/O, and the comp (complementary) pad is associated with the negative side of the differential I/O.   In addition, programmable on-chip input termination (parallel or differential, static or dynamic) is supported on these sides, which is required for DDR3 interface. However, there is no support for hot-socketing on these sides as the clamp is always present.  LVDS, RSDS, PPLVDS and Mini-LVDS differential output drivers are available on 50% of the buffer pairs on the left and right banks. 3. Configuration Bank sysI/O Buffer Pairs (Single-Ended Outputs, Only on Shared Pins When Not Used by Configuration) The sysI/O buffers in the Configuration Bank consist of single-ended output drivers and single-ended input buffers (both ratioed and referenced). The referenced input buffer can also be configured as a differential input.   The two pads in the pair are described as “true” and “comp”, where the true pad is associated with the positive side of the differential input buffer and the comp (complementary) pad is associated with the negative side of the differential input buffer. Programmable PCI clamps are only available on top banks (PCI clamps are used primarily on inputs and bidirectional pads to reduce ringing on the receiving end) can also be used on inputs. Typical sysI/O I/O Behavior During Power-up The internal power-on-reset (POR) signal is deactivated when VCC, VCCIO8 and VCCAUX have reached satisfactory levels. After the POR signal is deactivated, the FPGA core logic becomes active. It is the user’s responsibility to ensure that all other VCCIO banks are active with valid input logic levels to properly control the output logic states of all the I/O banks that are critical to the application. For more information about controlling the output logic state with valid input logic levels during power-up in LatticeECP3 devices, see the list of technical documentation at the end of this data sheet. The VCC and VCCAUX supply the power to the FPGA core fabric, whereas the VCCIO supplies power to the I/O buffers. In order to simplify system design while providing consistent and predictable I/O behavior, it is recommended that the I/O buffers be powered-up prior to the FPGA core fabric. VCCIO supplies should be powered-up before or together with the VCC and VCCAUX supplies. Supported sysI/O Standards The LatticeECP3 sysI/O buffer supports both single-ended and differential standards. Single-ended standards can be further subdivided into LVCMOS, LVTTL and other standards. The buffers support the LVTTL, LVCMOS 1.2V, 1.5V, 1.8V, 2.5V and 3.3V standards. In the LVCMOS and LVTTL modes, the buffer has individual configuration options for drive strength, slew rates, bus maintenance (weak pull-up, weak pull-down, or a bus-keeper latch) and open drain. Other single-ended standards supported include SSTL and HSTL. Differential standards supported include LVDS, BLVDS, LVPECL, MLVDS, RSDS, Mini-LVDS, PPLVDS (point-to-point LVDS), TRLVDS (Transition Reduced LVDS), differential SSTL and differential HSTL. Tables 2-13 and 2-14 show the I/O standards (together with their supply and reference voltages) supported by LatticeECP3 devices. For further information on utilizing the sysI/O buffer to support a variety of standards please see TN1177, LatticeECP3 sysIO Usage Guide. 2-42 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor On-Chip Programmable Termination The LatticeECP3 supports a variety of programmable on-chip terminations options, including: • Dynamically switchable Single Ended Termination for SSTL15 inputs with programmable resistor values of 40, 50, or 60 ohms. This is particularly useful for low power JEDEC compliant DDR3 memory controller implementations. External termination to Vtt should be used for DDR2 memory controller implementation. • Common mode termination of 80, 100, 120 ohms for differential inputs Figure 2-39. On-Chip Termination SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Vtt Control Signal Z0 + Vtt* Zo - + Z0 - Off-chip Off-chip On-Chip On-Chip *Vtt must be left floating for this termination Programmable resistance (40, 50 and 60 Ohms) Parallel Single-Ended Input Differential Input See Table 2-12 for termination options for input modes. Table 2-12. On-Chip Termination Options for Input Modes IO_TYPE TERMINATE to VTT1, 2 DIFFRENTIAL TERMINATION RESISTOR1 LVDS25 þ 80, 100, 120 BLVDS25 þ 80, 100, 120 MLVDS þ 80, 100, 120 HSTL18_I 40, 50, 60 þ HSTL18_II 40, 50, 60 þ HSTL18D_I 40, 50, 60 þ HSTL18D_II 40, 50, 60 þ HSTL15_I 40, 50, 60 þ HSTL15D_I 40, 50, 60 þ SSTL25_I 40, 50, 60 þ SSTL25_II 40, 50, 60 þ SSTL25D_I 40, 50, 60 þ SSTL25D_II 40, 50, 60 þ SSTL18_I 40, 50, 60 þ SSTL18_II 40, 50, 60 þ SSTL18D_I 40, 50, 60 þ SSTL18D_II 40, 50, 60 þ SSTL15 40, 50, 60 þ SSTL15D 40, 50, 60 þ 1. TERMINATE to VTT and DIFFRENTIAL TERMINATION RESISTOR when turn on can only have one setting per bank. Only left and right banks have this feature. Use of TERMINATE to VTT and DIFFRENTIAL TERMINATION RESISTOR are mutually exclusive in an I/O bank. On-chip termination tolerance +/- 20% 2. External termination to VTT should be used when implementing DDR2 memory controller. 2-43 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Please see TN1177, LatticeECP3 sysIO Usage Guide for on-chip termination usage and value ranges. Equalization Filter SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Equalization filtering is available for single-ended inputs on both true and complementary I/Os, and for differential inputs on the true I/Os on the left, right, and top sides. Equalization is required to compensate for the difficulty of sampling alternating logic transitions with a relatively slow slew rate. It is considered the most useful for the Input DDRX2 modes, used in DDR3 memory, LVDS, or TRLVDS signaling. Equalization filter acts as a tunable filter with settings to determine the level of correction. In the LatticeECP3 devices, there are four settings available: 0 (none), 1, 2 and 3. The default setting is 0. The equalization logic resides in the sysI/O buffers, the two bits of setting is set uniquely in each input IOLOGIC block. Therefore, each sysI/O can have a unique equalization setting within a DQS-12 group. Hot Socketing LatticeECP3 devices have been carefully designed to ensure predictable behavior during power-up and powerdown. During power-up and power-down sequences, the I/Os remain in tri-state until the power supply voltage is high enough to ensure reliable operation. In addition, leakage into I/O pins is controlled within specified limits. Please refer to the Hot Socketing Specifications in the DC and Switching Characteristics in this data sheet. SERDES and PCS (Physical Coding Sublayer) LatticeECP3 devices feature up to 16 channels of embedded SERDES/PCS arranged in quads at the bottom of the devices supporting up to 3.2Gbps data rate. Figure 2-40 shows the position of the quad blocks for the LatticeECP3150 devices. Table 2-14 shows the location of available SERDES Quads for all devices. The LatticeECP3 SERDES/PCS supports a range of popular serial protocols, including: • PCI Express 1.1 • Ethernet (XAUI, GbE - 1000 Base CS/SX/LX and SGMII) • Serial RapidIO • SMPTE SDI (3G, HD, SD) • CPRI • SONET/SDH (STS-3, STS-12, STS-48) Each quad contains four dedicated SERDES for high speed, full duplex serial data transfer. Each quad also has a PCS block that interfaces to the SERDES channels and contains protocol specific digital logic to support the standards listed above. The PCS block also contains interface logic to the FPGA fabric. All PCS logic for dedicated protocol support can also be bypassed to allow raw 8-bit or 10-bit interfaces to the FPGA fabric. Even though the SERDES/PCS blocks are arranged in quads, multiple baud rates can be supported within a quad with the use of dedicated, per channel 1, 2 and 11 rate dividers. Additionally, multiple quads can be arranged together to form larger data pipes. For information on how to use the SERDES/PCS blocks to support specific protocols, as well on how to combine multiple protocols and baud rates within a device, please refer to TN1176, LatticeECP3 SERDES/PCS Usage Guide. 2-44 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 2-40. SERDES/PCS Quads (LatticeECP3-150) sysIO Bank 1 CH0 CH1 CH2 CH3 SERDES/PCS Quad C CH0 CH1 CH2 SERDES/PCS Quad A CH3 CH0 CH1 CH2 SERDES/PCS Quad B CH3 CH0 CH1 CH2 CH3 SERDES/PCS Quad D sysIO Bank 3 sysIO Bank 6 sysIO Bank 2 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N sysIO Bank 7 Configuration Bank sysIO Bank 0 Table 2-13. LatticeECP3 SERDES Standard Support Data Rate (Mbps) Number of General/Link Width PCI Express 1.1 2500 x1, x2, x4 8b10b Gigabit Ethernet 1250, 2500 x1 8b10b SGMII 1250 x1 8b10b XAUI 3125 x4 8b10b Serial RapidIO Type I, Serial RapidIO Type II, Serial RapidIO Type III 1250, 2500, 3125 x1, x4 8b10b 614.4, 1228.8, 2457.6, 3072.0 x1 8b10b 1431, 1771, 270, 360, 540 x1 NRZI/Scrambled Standard CPRI-1, CPRI-2, CPRI-3, CPRI-4 SD-SDI (259M, 344M) Encoding Style HD-SDI (292M) 1483.5, 1485 x1 NRZI/Scrambled 3G-SDI (424M) 2967, 2970 x1 NRZI/Scrambled SONET-STS-32 155.52 x1 N/A SONET-STS-122 622.08 x1 N/A 2488 x1 N/A 2 SONET-STS-48 1. For slower rates, the SERDES are bypassed and CML signals are directly connected to the FPGA routing. 2. The SONET protocol is supported in 8-bit SERDES mode. See TN1176 Lattice ECP3 SERDES/PCS Usage Guide for more information. 2-45 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor Table 2-14. Available SERDES Quads per LatticeECP3 Devices Package ECP3-17 ECP3-35 ECP3-70 ECP3-95 ECP3-150 — 256 ftBGA 1 1 — — 484 ftBGA 1 1 1 1 672 ftBGA — 1 2 2 2 1156 ftBGA — — 3 3 4 SERDES Block SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N A SERDES receiver channel may receive the serial differential data stream, equalize the signal, perform Clock and Data Recovery (CDR) and de-serialize the data stream before passing the 8- or 10-bit data to the PCS logic. The SERDES transmitter channel may receive the parallel 8- or 10-bit data, serialize the data and transmit the serial bit stream through the differential drivers. Figure 2-41 shows a single-channel SERDES/PCS block. Each SERDES channel provides a recovered clock and a SERDES transmit clock to the PCS block and to the FPGA core logic. Each transmit channel, receiver channel, and SERDES PLL shares the same power supply (VCCA). The output and input buffers of each channel have their own independent power supplies (VCCOB and VCCIB). Figure 2-41. Simplified Channel Block Diagram for SERDES/PCS Block SERDES PCS FPGA Core Recovered Clock* RX_REFCLK HDINP Equalizer HDINN Recovered Clock Data Clock/Data Recovery Clock Deserializer 1:8/1:10 Receiver Polarity Adjust Word Alignment 8b10b Decoder Bypass CTC Downsample FIFO Bypass Bypass Receive Data Receive Clock SERDES Transmit Clock* TX REFCLK HDOUTP SERDES Transmit Clock TX PLL Serializer 8:1/10:1 HDOUTN Transmitter 8b10b Encoder Polarity Adjust Bypass Bypass Upsample FIFO Transmit Data Transmit Clock * 1/8 or 1/10 line rate PCS As shown in Figure 2-41, the PCS receives the parallel digital data from the deserializer and selects the polarity, performs word alignment, decodes (8b/10b), provides Clock Tolerance Compensation and transfers the clock domain from the recovered clock to the FPGA clock via the Down Sample FIFO. For the transmit channel, the PCS block receives the parallel data from the FPGA core, encodes it with 8b/10b, selects the polarity and passes the 8/10 bit data to the transmit SERDES channel. The PCS also provides bypass modes that allow a direct 8-bit or 10-bit interface from the SERDES to the FPGA logic. The PCS interface to the FPGA can also be programmed to run at 1/2 speed for a 16-bit or 20-bit interface to the FPGA logic. SCI (SERDES Client Interface) Bus The SERDES Client Interface (SCI) is an IP interface that allows the SERDES/PCS Quad block to be controlled by registers rather than the configuration memory cells. It is a simple register configuration interface that allows SERDES/PCS configuration without power cycling the device. 2-46 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor The ispLEVER design tools from Lattice support all modes of the PCS. Most modes are dedicated to applications associated with a specific industry standard data protocol. Other more general purpose modes allow users to define their own operation. With ispLEVER, the user can define the mode for each quad in a design. Popular standards such as 10Gb Ethernet, x4 PCI Express and 4x Serial RapidIO can be implemented using IP (available through Lattice), a single quad (Four SERDES channels and PCS) and some additional logic from the core. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N The LatticeECP3 family also supports a wide range of primary and secondary protocols. Within the same quad, the LatticeECP3 family can support mixed protocols with semi-independent clocking as long as the required clock frequencies are integer x1, x2, or x11 multiples of each other. Table 2-15 lists the allowable combination of primary and secondary protocol combinations. Flexible Quad SERDES Architecture The LatticeECP3 family SERDES architecture is a quad-based architecture. For most SERDES settings and standards, the whole quad (consisting of four SERDES) is treated as a unit. This helps in silicon area savings, better utilization and overall lower cost. However, for some specific standards, the LatticeECP3 quad architecture provides flexibility; more than one standard can be supported within the same quad. Table 2-15 shows the standards can be mixed and matched within the same quad. In general, the SERDES standards whose nominal data rates are either the same or a defined subset of each other, can be supported within the same quad. In Table 2-15, the Primary Protocol column refers to the standard that determines the reference clock and PLL settings. The Secondary Protocol column shows the other standard that can be supported within the same quad. Furthermore, Table 2-15 also implies that more than two standards in the same quad can be supported, as long as they conform to the data rate and reference clock requirements. For example, a quad may contain PCI Express 1.1, SGMII, Serial RapidIO Type I and Serial RapidIO Type II, all in the same quad. Table 2-15. LatticeECP3 Primary and Secondary Protocol Support Primary Protocol Secondary Protocol PCI Express 1.1 SGMII PCI Express 1.1 Gigabit Ethernet PCI Express 1.1 Serial RapidIO Type I PCI Express 1.1 Serial RapidIO Type II Serial RapidIO Type I SGMII Serial RapidIO Type I Gigabit Ethernet Serial RapidIO Type II SGMII Serial RapidIO Type II Gigabit Ethernet Serial RapidIO Type II Serial RapidIO Type I CPRI-3 CPRI-2 and CPRI-1 3G-SDI HD-SDI and SD-SDI For further information on SERDES, please see TN1176, LatticeECP3 SERDES/PCS Usage Guide. IEEE 1149.1-Compliant Boundary Scan Testability All LatticeECP3 devices have boundary scan cells that are accessed through an IEEE 1149.1 compliant Test Access Port (TAP). This allows functional testing of the circuit board on which the device is mounted through a serial scan path that can access all critical logic nodes. Internal registers are linked internally, allowing test data to be shifted in and loaded directly onto test nodes, or test data to be captured and shifted out for verification. The test 2-47 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor access port consists of dedicated I/Os: TDI, TDO, TCK and TMS. The test access port has its own supply voltage VCCJ and can operate with LVCMOS3.3, 2.5, 1.8, 1.5 and 1.2 standards. For more information, please see TN1169, LatticeECP3 sysCONFIG Usage Guide. Device Configuration SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N All LatticeECP3 devices contain two ports that can be used for device configuration. The Test Access Port (TAP), which supports bit-wide configuration, and the sysCONFIG port, support dual-byte, byte and serial configuration. The TAP supports both the IEEE Standard 1149.1 Boundary Scan specification and the IEEE Standard 1532 InSystem Configuration specification. The sysCONFIG port includes seven I/Os used as dedicated pins with the remaining pins used as dual-use pins. See TN1169, LatticeECP3 sysCONFIG Usage Guide for more information about using the dual-use pins as general purpose I/Os. There are various ways to configure a LatticeECP3 device: 1. JTAG 2. Standard Serial Peripheral Interface (SPI and SPIm modes) - interface to boot PROM memory 3. System microprocessor to drive a x8 CPU port (PCM mode) 4. System microprocessor to drive a serial slave SPI port (SSPI mode) 5. Generic byte wide flash with a MachXO™ device, providing control and addressing On power-up, the FPGA SRAM is ready to be configured using the selected sysCONFIG port. Once a configuration port is selected, it will remain active throughout that configuration cycle. The IEEE 1149.1 port can be activated any time after power-up by sending the appropriate command through the TAP port. LatticeECP3 devices also support the Slave SPI Interface. In this mode, the FPGA behaves like a SPI Flash device (slave mode) with the SPI port of the FPGA to perform read-write operations. Enhanced Configuration Options LatticeECP3 devices have enhanced configuration features such as: decryption support, TransFR™ I/O and dualboot image support. 1. TransFR (Transparent Field Reconfiguration) TransFR I/O (TFR) is a unique Lattice technology that allows users to update their logic in the field without interrupting system operation using a single ispVM command. TransFR I/O allows I/O states to be frozen during device configuration. This allows the device to be field updated with a minimum of system disruption and downtime. See TN1087, Minimizing System Interruption During Configuration Using TransFR Technology for details. 2. Dual-Boot Image Support Dual-boot images are supported for applications requiring reliable remote updates of configuration data for the system FPGA. After the system is running with a basic configuration, a new boot image can be downloaded remotely and stored in a separate location in the configuration storage device. Any time after the update the LatticeECP3 can be re-booted from this new configuration file. If there is a problem, such as corrupt data during download or incorrect version number with this new boot image, the LatticeECP3 device can revert back to the original backup golden configuration and try again. This all can be done without power cycling the system. For more information, please see TN1169, LatticeECP3 sysCONFIG Usage Guide. Soft Error Detect (SED) Support LatticeECP3 devices have dedicated logic to perform Cycle Redundancy Code (CRC) checks. During configuration, the configuration data bitstream can be checked with the CRC logic block. In addition, the LatticeECP3 device 2-48 Architecture LatticeECP3 Family Data Sheet Lattice Semiconductor can also be programmed to utilize a Soft Error Detect (SED) mode that checks for soft errors in configuration SRAM. The SED operation can be run in the background during user mode. If a soft error occurs, during user mode (normal operation) the device can be programmed to generate an error signal. For further information on SED support, please see TN1184, LatticeECP3 Soft Error Detection (SED) Usage Guide. External Resistor SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LatticeECP3 devices require a single external, 10K ohm ±1% value between the XRES pin and ground. Device configuration will not be completed if this resistor is missing. There is no boundary scan register on the external resistor pad. On-Chip Oscillator Every LatticeECP3 device has an internal CMOS oscillator which is used to derive a Master Clock (MCLK) for configuration. The oscillator and the MCLK run continuously and are available to user logic after configuration is completed. The software default value of the MCLK is nominally 2.5MHz. Table 2-16 lists all the available MCLK frequencies. When a different Master Clock is selected during the design process, the following sequence takes place: 1. Device powers up with a nominal Master Clock frequency of 3.1MHz. 2. During configuration, users select a different master clock frequency. 3. The Master Clock frequency changes to the selected frequency once the clock configuration bits are received. 4. If the user does not select a master clock frequency, then the configuration bitstream defaults to the MCLK frequency of 2.5MHz. This internal CMOS oscillator is available to the user by routing it as an input clock to the clock tree. For further information on the use of this oscillator for configuration or user mode, please see TN1169, LatticeECP3 sysCONFIG Usage Guide. Table 2-16. Selectable Master Clock (MCLK) Frequencies During Configuration (Nominal) MCLK (MHz) MCLK (MHz) MCLK (MHz) 1 2.5 10 41 3.1 13 45 4.3 15 51 5.4 20 55 6.9 26 60 8.1 30 130 9.2 34 — 1. Software default MCLK frequency. Hardware default is 3.1MHz. Density Shifting The LatticeECP3 family is designed to ensure that different density devices in the same family and in the same package have the same pinout. Furthermore, the architecture ensures a high success rate when performing design migration from lower density devices to higher density devices. In many cases, it is also possible to shift a lower utilization design targeted for a high-density device to a lower density device. However, the exact details of the final resource utilization will impact the likelihood of success in each case. An example is that some user I/Os may become No Connects in smaller devices in the same packge. 2-49 LatticeECP3 Family Data Sheet DC and Switching Characteristics March 2010 Preliminary Data Sheet DS1021 Absolute Maximum Ratings1, 2, 3 Supply Voltage VCC . . . . . . . . . . . . . . . . . . . -0.5 to 1.32V Supply Voltage VCCAUX . . . . . . . . . . . . . . . . -0.5 to 3.75V SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Supply Voltage VCCJ . . . . . . . . . . . . . . . . . . -0.5 to 3.75V Output Supply Voltage VCCIO . . . . . . . . . . . -0.5 to 3.75V Input or I/O Tristate Voltage Applied4 . . . . . . -0.5 to 3.75V Storage Temperature (Ambient) . . . . . . . . . -65 to 150°C Junction Temperature (Tj) . . . . . . . . . . . . . . . . . . +125°C 1. Stress above those listed under the “Absolute Maximum Ratings” may cause permanent damage to the device. Functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. 2. Compliance with the Lattice Thermal Management document is required. 3. All voltages referenced to GND. 4. Overshoot and undershoot of -2V to (VIHMAX + 2) volts is permitted for a duration of 10 Bits Wide) Centered at Pin (GDDRX1_RX.SCLK.Centered) Using PCLK Pin for Clock Input Data Left, Right and Top Sides & Clock Left, Right and Top Sides tSUGDDR Data Setup Before CLK ECP3-150EA — — — ps tHGDDR Data Hold After CLK ECP3-150EA — — — ps fMAX_GDDR DDRX1 Clock Frequency ECP3-150EA — — — MHz Generic DDRX1 Inputs with Clock in the Center of Data Window, without DLL (GDDRX1_RX.ECLK.Centered) tSUGDDR Data Setup Before CLK ECP3-70E/95E 515 — 515 — 515 — ps tHOGDDR Data Hold After CLK ECP3-70E/95E 515 — 515 — 515 — ps fMAX_GDDR DDRX1 Clock Frequency ECP3-70E/95E — 250 — 250 — 250 MHz Generic DDRX1 Inputs with Clock and Data (> 10 Bits Wide) Aligned at Pin (GDDRX1_RX.SCLK.Aligned) using DLLCLKIN Pin for Clock Input Data Left, Right and Top Sides & Clock Left and Right Sides tDVACLKGDDR Data Setup Before CLK ECP3-150EA tDVECLKGDDR Data Hold After CLK ECP3-150EA fMAX_GDDR DDRX1 Clock Frequency ECP3-150EA — — — — — — — UI — — UI MHz Generic DDRX1 Inputs with Clock and Data Aligned, with DLL (GDDRX1_RX.ECLK.Aligned) tDVACLKGDDR Data Setup Before CLK ECP3-70E/95E tDVECLKGDDR Data Hold After CLK ECP3-70E/95E 0.765 3-17 — 0.235 — 0.235 — 0.235 UI — 0.765 — 0.765 — UI DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 External Switching Characteristics (Continued)1, 2 Over Recommended Commercial Operating Conditions -8 Parameter fMAX_GDDR Description DDRX1 Clock Frequency -7 -6 Device Min. Max. Min. Max. Min. ECP3-70E/95E — 250 — 250 — Max. Units 250 MHz Generic DDRX1 Inputs with Clock and Data (10 Bits Wide) Aligned at Pin (GDDRX2_RX.ECLK.Aligned) Left and Right Side Using DLLCLKIN Pin for Clock Input tDVACLKGDDR Data Setup Before CLK (Left and Right Side) ECP3-150EA tDVECLKGDDR Data Hold After CLK (Left and Right Side) ECP3-150EA fMAX_GDDR DDRX1 Clock Frequency (Left and Right Side) ECP3-150EA — — — MHz — — — UI — — — — — UI — UI Top Side Using PCLK Pin for Clock Input tDVACLKGDDR Data Setup Before CLK (Top Side) ECP3-150EA tDVECLKGDDR Data Hold After CLK (Top Side) ECP3-150EA fMAX_GDDR DDRX1 Clock Frequency (Top Side) ECP3-150EA — — — — — — UI MHz Generic DDRX2 Inputs with Clock and Data Edges Aligned, with DLLDEL3 (GDDRX2_RX.ECLK.Aligned) tDVACLKGDDR Data Valid After CLK ECP3-70E/95E 3-18 — 0.235 — 0.235 — 0.235 UI DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 External Switching Characteristics (Continued)1, 2 Over Recommended Commercial Operating Conditions -8 Parameter Description Device Min. tDVECLKGDDR Data Hold After CLK ECP3-70E/95E 0.765 fMAX_GDDR DDR/DDRX2 Clock Frequency8 ECP3-70E/95E — -7 Max. Min. — 500 -6 Max. Min. Max. Units 0.765 — 0.765 — UI — 420 — 375 MHz Generic DDRX2 Inputs with Clock and Data ( 10 Bits Wide) Aligned at Pin (GDDRX1_TX.SCLK.Aligned) Left, Right and Top Sides tDIBGDDR Data Hold After CLK ECP3-150EA — — — tDIAGDDR Data Setup Before CLK ECP3-150EA — — — fMAX_GDDR DDRX1 Clock Frequency ECP3-150EA — — — Generic DDRX1 Outputs with clock and data edge aligned, without PLL tDIBGDDR Data Invalid Before CLK ECP3-70E/95E — 330 — 330 — 330 tDIAGDDR Data Invalid After CLK ECP3-70E/95E — 330 — 330 — 330 ps fMAX_GDDR DDRX1 Clock Frequency ECP3-70E/95E — 250 — 250 — 250 MHz Generic DDRX1 Output with Clock and Data ( 10 Bits Wide) Aligned at Pin (GDDRX2_TX.ECLK.Aligned) Left and Right Sides Data Setup Before CLK ECP3-150EA — — — ps tDIAGDDR Data Hold After CLK ECP3-150EA — — — ps fMAX_GDDR DDRX2 Clock Frequency ECP3-150EA — — — MHz SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N tDIBGDDR Generic DDRX2 Outputs with Clock and Data Edges Aligned, Without PLL 90-degree shifted clock output5 (GDDRX2_TX.Aligned) tDIBGDDR Data Invalid Before Clock ECP3-70E/95E — 200 — 225 — 250 ps tDIAGDDR Data Invalid After Clock ECP3-70E/95E — 200 — 225 — 250 ps fMAX_GDDR DDR/DDRX2 Clock Frequency8 ECP3-70E/95E — 500 — 420 — 375 MHz Generic DDRX2 Output with Clock and Data (> 10 Bits Wide) Centered at Pin Using DQSDLL (GDDRX2_TX.DQSDLL.Centered) Left and Right Sides tDVBGDDR Data Valid Before CLK ECP3-150EA tDVAGDDR Data Valid After CLK ECP3-150EA fMAX_GDDR DDRX2 Clock Frequency ECP3-150EA — — — — — — — ns — ns — ns Generic DDRX2 Output with Clock and Data (> 10 Bits Wide) Centered at Pin Using PLL (GDDRX2_TX.PLL.Centered) Left and Right Sides tDVBGDDR Data Valid Before CLK ECP3-150EA — — — ns tDVAGDDR Data Valid After CLK ECP3-150EA — — — ns fMAX_GDDR DDRX2 Clock Frequency ECP3-150EA — — — ns Generic DDRX2 Outputs with Clock Edge in the Center of Data Window, with PLL 90-degree Shifted Clock Output6 (GDDRX2_TX.PLL.Centered) tDVBGDDR Data Valid Before CLK ECP3-70E/95E 300 — 370 tDVAGDDR Data Valid After CLK ECP3-70E/95E fMAX_GDDR DDR/DDRX2 Clock Frequency8 ECP3-70E/95E — 417 300 — — 500 370 — 417 — ps — 420 — 375 MHz -8 Parameter Description Device Min. -7 Max. Min. — ps -6 Max. Min. Max. Units Memory Interface DDR/DDR2 SDRAM I/O Pin Parameters (Input Data are Strobe Edge Aligned, Output Strobe Edge is Data Centered)4 tDVADQ Data Valid After DQS (DDR Read) ECP3-150EA — 0.225 — 0.225 — 0.225 UI tDVEDQ Data Hold After DQS (DDR Read) ECP3-150EA 0.64 — 0.64 — 0.64 — UI tDQVBS Data Valid Before DQS ECP3-150EA 0.25 — 0.25 — 0.25 — UI tDQVAS Data Valid After DQS ECP3-150EA 0.25 — 0.25 — 0.25 — UI fMAX_DDR DDR Clock Frequency ECP3-150EA 95 200 95 200 95 166 MHz fMAX_DDR2 DDR2 clock frequency ECP3-150EA 133 266 133 200 133 166 MHz tDVADQ Data Valid After DQS (DDR Read) ECP3-70E/95E — 0.225 — 0.225 — 0.225 UI tDVEDQ Data Hold After DQS (DDR Read) ECP3-70E/95E 0.64 — 0.64 — 0.64 — UI tDQVBS Data Valid Before DQS ECP3-70E/95E 0.25 — 0.25 — 0.25 — UI tDQVAS Data Valid After DQS ECP3-70E/95E 0.25 — 0.25 — 0.25 — UI fMAX_DDR DDR Clock Frequency ECP3-70E/95E 95 200 95 200 95 133 MHz 3-20 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 External Switching Characteristics (Continued)1, 2 Over Recommended Commercial Operating Conditions -8 Parameter fMAX_DDR2 Description DDR2 Clock Frequency -7 -6 Device Min. Max. Min. Max. Min. Max. Units ECP3-70E/95E 133 266 133 200 133 166 MHz DDR3 (Using PLL for SCLK) I/O Pin Parameters Data Valid After DQS (DDR Read) ECP3-150EA — 0.225 — 0.225 — 0.225 UI tDVEDQ Data Hold After DQS (DDR Read) ECP3-150EA 0.64 — 0.64 — 0.64 — UI tDQVBS Data Valid Before DQS ECP3-150EA 0.25 — 0.25 — 0.25 — UI tDQVAS Data Valid After DQS ECP3-150EA 0.25 — 0.25 — 0.25 — UI fMAX_DDR3 DDR3 clock frequency ECP3-150EA 266 400 266 333 266 300 MHz 1. 2. 3. 4. 5. 6. 7. 8. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N tDVADQ Commercial timing numbers are shown. Industrial numbers are typically slower and can be extracted from the ispLEVER software. General I/O timing numbers based on LVCMOS 2.5, 12mA, 0pf load. Generic DDR timing numbers based on LVDS I/O. DDR timing numbers based on SSTL25. DDR2 timing numbers based on SSTL18. DDR3 timing numbers based on SSTL15. Uses LVDS I/O standard. The current version of software does not support per bank skew numbers; this will be supported in a future release. Maximum clock frequencies are tested under best case conditions. System performance may vary upon the user environment. 3-21 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-6. Generic DDR/DDR2 (With Clock and Data Edges Aligned) Transmit Parameters t DIBGDDR t DIAGDDR CLK SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Data (TDAT, TCTL) t DIAGDDR t DIBGDDR Receive Parameters RDTCLK Data (RDAT, RCTL) t DVACLKGDDR t DVACLKGDDR t DVECLKGDDR t DVECLKGDDR 3-22 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-7. DDR/DDR2/DDR3 SDRAM Transmit Parameters DQS DQ t DQVAS SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N t DQVBS t DQVAS t DQVBS Receive Parameters DQS DQ t DVADQ t DVADQ t DVEDQ t DVEDQ Figure 3-8. Generic DDR/DDR2 Parameters (With Clock Center on Data Window) Transmit Parameters CLOCK DATA tDVBCKGDDR t DVACKGDDR t DVACKGDDR t DVBCKGDDR Receive Parameters CLOCK DATA t SUGDDR t SUGDDR t HGDDR t HGDDR 3-23 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Internal Switching Characteristics1, 2 Over Recommended Commercial Operating Conditions -8 Parameter Description Min. -7 Max. Min. -6 Max. Min. Max. Units. PFU/PFF Logic Mode Timing LUT4 delay (A to D inputs to F output) — 0.147 — 0.163 — 0.179 ns tLUT6_PFU LUT6 delay (A to D inputs to OFX output) — 0.273 — 0.307 — 0.342 ns tLSR_PFU Set/Reset to output of PFU (Asynchronus) — 0.593 — 0.674 — 0.756 ns tLSRREC_PFU Asynchronous Set/Reset recovery time for PFU Logic — 0.298 tSUM_PFU Clock to Mux (M0,M1) Input Setup Time 0.134 tHM_PFU Clock to Mux (M0,M1) Input Hold Time -0.097 tSUD_PFU Clock to D input setup time tHD_PFU Clock to D input hold time tCK2Q_PFU Clock to Q delay, (D-type Register  Configuration) SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N tLUT4_PFU — 0.345 — 0.391 ns — 0.144 — -0.103 — 0.153 — ns — -0.109 — ns 0.061 — 0.068 — 0.075 — ns 0.019 — 0.013 — 0.015 — ns — 0.243 — 0.273 — 0.303 ns ns PFU Dual Port Memory Mode Timing tCORAM_PFU Clock to Output (F Port) — 0.710 — 0.803 — 0.897 tSUDATA_PFU Data Setup Time -0.137 — -0.155 — -0.174 — ns tHDATA_PFU Data Hold Time 0.188 — 0.217 — 0.246 — ns -0.227 — -0.257 — -0.286 — ns tSUADDR_PFU Address Setup Time tHADDR_PFU Address Hold Time 0.240 — 0.275 — 0.310 — ns tSUWREN_PFU Write/Read Enable Setup Time -0.055 — -0.055 — -0.063 — ns tHWREN_PFU Write/Read Enable Hold Time 0.059 — 0.059 — 0.071 — ns PIC Timing PIO Input/Output Buffer Timing tIN_PIO Input Buffer Delay (LVCMOS25) — 0.423 — 0.466 — 0.508 ns tOUT_PIO Output Buffer Delay (LVCMOS25) — 1.115 — 1.155 — 1.196 ns — 1.124 — 1.293 — ns IOLOGIC Input/Output Timing tSUI_PIO Input Register Setup Time (Data Before Clock) 0.956 tHI_PIO Input Register Hold Time (Data after Clock) 0.313 — 0.395 — 0.378 — ns tCOO_PIO Output Register Clock to Output Delay4 — 1.455 — 1.564 — 1.674 ns tSUCE_PIO Input Register Clock Enable Setup Time 0.220 — 0.185 — 0.150 — ns tHCE_PIO Input Register Clock Enable Hold Time -0.085 — -0.072 — -0.058 — ns tSULSR_PIO Set/Reset Setup Time 0.117 — 0.103 — 0.088 — ns tHLSR_PIO Set/Reset Hold Time -0.107 — -0.094 — -0.081 — ns EBR Timing tCO_EBR Clock (Read) to output from Address or Data — 2.78 — 2.89 — 2.99 ns tCOO_EBR Clock (Write) to output from EBR output Register — 0.31 — 0.32 — 0.33 ns tSUDATA_EBR Setup Data to EBR Memory -0.218 — -0.227 — -0.237 — ns tHDATA_EBR Hold Data to EBR Memory 0.249 — 0.257 — 0.265 — ns tSUADDR_EBR Setup Address to EBR Memroy -0.071 — -0.070 — -0.068 — ns tHADDR_EBR Hold Address to EBR Memory 0.118 — 0.098 — 0.077 — ns tSUWREN_EBR Setup Write/Read Enable to PFU Memory -0.107 — -0.106 — -0.106 — ns 3-24 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Internal Switching Characteristics1, 2 (Continued) Over Recommended Commercial Operating Conditions -8 Description -6 Min. Max. Min. Max. Min. Max. Units. tHWREN_EBR Hold Write/Read Enable to PFU Memory 0.141 — 0.145 — 0.149 — ns tSUCE_EBR Clock Enable Setup Time to EBR Output Register 0.087 0.096 0.104 ns tHCE_EBR Clock Enable Hold Time to EBR Output Register -0.066 -0.080 -0.094 ns SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Parameter -7 tSUBE_EBR Byte Enable Set-Up Time to EBR Output Register -0.071 -0.070 -0.068 ns tHBE_EBR Byte Enable Hold Time to EBR Output Register 0.118 0.098 0.077 ns DSP Block Timing3 tSUI_DSP Input Register Setup Time 0.32 — 0.36 — 0.39 — ns tHI_DSP Input Register Hold Time -0.17 — -0.19 — -0.21 — ns tSUP_DSP Pipeline Register Setup Time 2.23 — 2.30 — 2.37 — ns tHP_DSP Pipeline Register Hold Time -1.02 — -1.09 — -1.15 — ns tSUO_DSP Output Register Setup Time 3.09 — 3.22 — 3.34 — ns -1.67 — -1.76 — -1.84 — ns tHO_DSP Output Register Hold Time tCOI_DSP Input Register Clock to Output Time — 3.68 — 4.03 — 4.38 ns tCOP_DSP Pipeline Register Clock to Output Time — 1.30 — 1.47 — 1.64 ns tCOO_DSP Output Register Clock to Output Time — 0.58 — 0.60 — 0.62 ns tSUOPT_DSP Opcode Register Setup Time 0.31 — 0.35 — 0.39 — ns tHOPT_DSP Opcode Register Hold Time -0.20 — -0.24 — -0.27 — ns tSUDATA_DSP Cascade_data through ALU to Output Register Setup Time 1.55 — 1.67 — 1.78 — ns tHPDATA_DSP Cascade_data through ALU to Output Register Hold Time -0.44 — -0.53 — -0.61 — ns 1. 2. 3. 4. Internal parameters are characterized but not tested on every device. Commercial timing numbers are shown. Industrial timing numbers are typically slower and can be extracted from the ispLEVER software. DSP slice is configured in Multiply Add/Sub 18x18 mode. The output register is in Flip-flop mode. 3-25 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Timing Diagrams Figure 3-9. Read/Write Mode (Normal) CLKA SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N CSA WEA ADA A0 A1 A0 A0 A1 tSU tH DIA D0 D1 tCO_EBR tCO_EBR D0 DOA tCO_EBR D1 D0 Note: Input data and address are registered at the positive edge of the clock and output data appears after the positive edge of the clock. Figure 3-10. Read/Write Mode with Input and Output Registers CLKA CSA WEA ADA A0 tSU DIA A1 A0 A1 A0 tH D0 D1 tCOO_EBR DOA (Regs) Mem(n) data from previous read output is only updated during a read cycle 3-26 tCOO_EBR D0 D1 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-11. Write Through (SP Read/Write on Port A, Input Registers Only) CLKA CSA SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N WEA Three consecutive writes to A0 ADA A0 tSU DIA A1 tH D0 D2 D1 tACCESS DOA A0 Data from Prev Read or Write tACCESS D0 D3 D4 tACCESS D1 tACCESS D2 D3 D4 Note: Input data and address are registered at the positive edge of the clock and output data appears after the positive edge of the clock. 3-27 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Family Timing Adders1, 2, 3, 4, 5 Over Recommended Commercial Operating Conditions Buffer Type Description -8 -7 -6 Units LVDS, Emulated, VCCIO = 2.5V 0.03 -0.01 -0.03 ns LVDS25 LVDS, VCCIO = 2.5V 0.03 0.00 -0.04 ns BLVDS25 BLVDS, Emulated, VCCIO = 2.5V 0.03 0.00 -0.04 ns MLVDS25 MLVDS, Emulated, VCCIO = 2.5V 0.03 0.00 -0.04 ns Input Adjusters SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LVDS25E RSDS25 RSDS, VCCIO = 2.5V 0.03 0.00 -0.03 ns PPLVDS Point-to-Point LVDS 0.03 -0.01 -0.03 ns TRLVDS Transition-Reduced LVDS 0.03 0.00 -0.04 ns Mini MLVDS Mini LVDS 0.03 -0.01 -0.03 ns LVPECL33 LVPECL, Emulated, VCCIO = 3.0V 0.17 0.07 -0.04 ns HSTL18_I HSTL_18 class I, VCCIO = 1.8V 0.20 0.17 0.13 ns HSTL18_II HSTL_18 class II, VCCIO = 1.8V 0.20 0.17 0.13 ns HSTL18D_I Differential HSTL 18 class I 0.20 0.17 0.13 ns HSTL18D_II Differential HSTL 18 class II 0.20 0.17 0.13 ns HSTL15_I HSTL_15 class I, VCCIO = 1.5V 0.10 0.12 0.13 ns HSTL15D_I Differential HSTL 15 class I 0.10 0.12 0.13 ns SSTL33_I SSTL_3 class I, VCCIO = 3.0V 0.17 0.23 0.28 ns SSTL33_II SSTL_3 class II, VCCIO = 3.0V 0.17 0.23 0.28 ns SSTL33D_I Differential SSTL_3 class I 0.17 0.23 0.28 ns SSTL33D_II Differential SSTL_3 class II 0.17 0.23 0.28 ns SSTL25_I SSTL_2 class I, VCCIO = 2.5V 0.12 0.14 0.16 ns SSTL25_II SSTL_2 class II, VCCIO = 2.5V 0.12 0.14 0.16 ns SSTL25D_I Differential SSTL_2 class I 0.12 0.14 0.16 ns SSTL25D_II Differential SSTL_2 class II 0.12 0.14 0.16 ns SSTL18_I SSTL_18 class I, VCCIO = 1.8V 0.08 0.06 0.04 ns SSTL18_II SSTL_18 class II, VCCIO = 1.8V 0.08 0.06 0.04 ns SSTL18D_I Differential SSTL_18 class I 0.08 0.06 0.04 ns SSTL18D_II Differential SSTL_18 class II 0.08 0.06 0.04 ns SSTL15 SSTL_15, VCCIO = 1.5V 0.087 0.059 0.032 ns SSTL15D Differential SSTL_15 0.087 0.025 -0.036 ns LVTTL33 LVTTL, VCCIO = 3.0V 0.05 0.05 0.05 ns LVCMOS33 LVCMOS, VCCIO = 3.0V 0.05 0.05 0.05 ns LVCMOS25 LVCMOS, VCCIO = 2.5V 0.00 0.00 0.00 ns LVCMOS18 LVCMOS, VCCIO = 1.8V 0.06 0.08 0.11 ns LVCMOS15 LVCMOS, VCCIO = 1.5V 0.17 0.21 0.25 ns LVCMOS12 LVCMOS, VCCIO = 1.2V 0.01 0.05 0.08 ns PCI33 PCI, VCCIO = 3.0V 0.05 0.05 0.05 ns LVDS25E LVDS, Emulated, VCCIO = 2.5V 0.15 0.15 0.16 ns LVDS25 LVDS, VCCIO = 2.5V 0.02 0.08 0.13 ns BLVDS25 BLVDS, Emulated, VCCIO = 2.5V 0.00 -0.02 -0.04 ns MLVDS25 MLVDS, Emulated, VCCIO = 2.5V 0.00 -0.01 -0.03 ns Output Adjusters 3-28 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Family Timing Adders1, 2, 3, 4, 5 (Continued) Over Recommended Commercial Operating Conditions Buffer Type Description -8 -7 -6 Units 0.05 0.10 0.16 ns Point-to-Point LVDS, Emulated, VCCIO = 2.5V -0.10 -0.05 0.01 ns LVPECL, Emulated, VCCIO = 3.0V -0.02 -0.04 -0.06 ns RSDS25 RSDS, VCCIO = 2.5V PPLVDS LVPECL33 HSTL_18 class I 8mA drive, VCCIO = 1.8V -0.19 -0.16 -0.12 ns HSTL18_II HSTL_18 class II, VCCIO = 1.8V -0.30 -0.28 -0.25 ns HSTL18D_I Differential HSTL 18 class I 8mA drive -0.19 -0.16 -0.12 ns HSTL18D_II Differential HSTL 18 class II -0.30 -0.28 -0.25 ns SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N HSTL18_I HSTL15_I HSTL_15 class I 4mA drive, VCCIO = 1.5V -0.22 -0.19 -0.16 ns HSTL15D_I Differential HSTL 15 class I 4mA drive -0.22 -0.19 -0.16 ns SSTL33_I SSTL_3 class I, VCCIO = 3.0V 0.08 0.13 0.19 ns SSTL33_II SSTL_3 class II, VCCIO = 3.0V -0.20 -0.17 -0.14 ns SSTL33D_I Differential SSTL_3 class I 0.08 0.13 0.18 ns SSTL33D_II Differential SSTL_3 class II -0.20 -0.17 -0.14 ns SSTL25_I SSTL_2 class I 8mA drive, VCCIO = 2.5V -0.06 -0.02 0.02 ns SSTL25_II SSTL_2 class II 16mA drive, VCCIO = 2.5V -0.19 -0.15 -0.12 ns SSTL25D_I Differential SSTL_2 class I 8mA drive -0.06 -0.02 0.02 ns SSTL25D_II Differential SSTL_2 class II 16mA drive -0.19 -0.15 -0.12 ns SSTL18_I SSTL_1.8 class I, VCCIO = 1.8V -0.14 -0.10 -0.07 ns SSTL18_II SSTL_1.8 class II 8mA drive, VCCIO = 1.8V -0.20 -0.17 -0.14 ns SSTL18D_I Differential SSTL_1.8 class I -0.14 -0.10 -0.07 ns SSTL18D_II Differential SSTL_1.8 class II 8mA drive -0.20 -0.17 -0.14 ns SSTL15 SSTL_1.5, VCCIO = 1.5V 0.07 0.08 0.08 ns SSTL15D Differential SSTL_15 0.07 0.08 0.08 ns LVTTL33_4mA LVTTL 4mA drive, VCCIO = 3.0V 0.21 0.23 0.25 ns LVTTL33_8mA LVTTL 8mA drive, VCCIO = 3.0V 0.09 0.09 0.10 ns LVTTL33_12mA LVTTL 12mA drive, VCCIO = 3.0V 0.02 0.03 0.03 ns LVTTL33_16mA LVTTL 16mA drive, VCCIO = 3.0V 0.12 0.13 0.13 ns LVTTL33_20mA LVTTL 20mA drive, VCCIO = 3.0V 0.08 0.08 0.09 ns LVCMOS33_4mA LVCMOS 3.3 4mA drive, fast slew rate 0.21 0.23 0.25 ns LVCMOS33_8mA LVCMOS 3.3 8mA drive, fast slew rate 0.09 0.09 0.10 ns LVCMOS33_12mA LVCMOS 3.3 12mA drive, fast slew rate 0.02 0.03 0.03 ns LVCMOS33_16mA LVCMOS 3.3 16mA drive, fast slew rate 0.12 0.13 0.13 ns LVCMOS33_20mA LVCMOS 3.3 20mA drive, fast slew rate 0.08 0.08 0.09 ns LVCMOS25_4mA LVCMOS 2.5 4mA drive, fast slew rate 0.12 0.12 0.12 ns LVCMOS25_8mA LVCMOS 2.5 8mA drive, fast slew rate 0.05 0.05 0.05 ns LVCMOS25_12mA LVCMOS 2.5 12mA drive, fast slew rate 0.00 0.00 0.00 ns LVCMOS25_16mA LVCMOS 2.5 16mA drive, fast slew rate 0.08 0.08 0.08 ns LVCMOS25_20mA LVCMOS 2.5 20mA drive, fast slew rate 0.04 0.04 0.04 ns LVCMOS18_4mA LVCMOS 1.8 4mA drive, fast slew rate 0.08 0.09 0.09 ns LVCMOS18_8mA LVCMOS 1.8 8mA drive, fast slew rate 0.02 0.01 0.01 ns LVCMOS18_12mA LVCMOS 1.8 12mA drive, fast slew rate -0.03 -0.03 -0.03 ns LVCMOS18_16mA LVCMOS 1.8 16mA drive, fast slew rate 0.03 0.03 0.03 ns 3-29 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Family Timing Adders1, 2, 3, 4, 5 (Continued) Over Recommended Commercial Operating Conditions -8 -7 -6 Units LVCMOS15_4mA Buffer Type LVCMOS 1.5 4mA drive, fast slew rate Description 0.09 0.10 0.10 ns LVCMOS15_8mA LVCMOS 1.5 8mA drive, fast slew rate 0.01 0.01 0.00 ns LVCMOS12_2mA LVCMOS 1.2 2mA drive, fast slew rate 0.08 0.08 0.08 ns LVCMOS12_6mA LVCMOS 1.2 6mA drive, fast slew rate -0.02 -0.02 -0.02 ns LVCMOS33_4mA LVCMOS 3.3 4mA drive, slow slew rate 1.64 1.71 1.77 ns LVCMOS 3.3 8mA drive, slow slew rate 1.39 1.45 1.51 ns LVCMOS33_12mA LVCMOS 3.3 12mA drive, slow slew rate 1.21 1.27 1.33 ns LVCMOS33_16mA LVCMOS 3.3 16mA drive, slow slew rate 1.43 1.49 1.55 ns LVCMOS33_20mA LVCMOS 3.3 20mA drive, slow slew rate 1.23 1.28 1.34 ns LVCMOS25_4mA LVCMOS 2.5 4mA drive, slow slew rate 1.66 1.70 1.74 ns LVCMOS25_8mA LVCMOS 2.5 8mA drive, slow slew rate 1.39 1.43 1.46 ns LVCMOS25_12mA LVCMOS 2.5 12mA drive, slow slew rate 1.20 1.24 1.28 ns LVCMOS25_16mA LVCMOS 2.5 16mA drive, slow slew rate 1.42 1.45 1.49 ns LVCMOS25_20mA LVCMOS 2.5 20mA drive, slow slew rate 1.22 1.26 1.29 ns LVCMOS18_4mA LVCMOS 1.8 4mA drive, slow slew rate 1.61 1.65 1.68 ns SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LVCMOS33_8mA LVCMOS18_8mA LVCMOS 1.8 8mA drive, slow slew rate 1.32 1.36 1.39 ns LVCMOS18_12mA LVCMOS 1.8 12mA drive, slow slew rate 1.14 1.17 1.21 ns LVCMOS18_16mA LVCMOS 1.8 16mA drive, slow slew rate 1.35 1.38 1.42 ns LVCMOS15_4mA LVCMOS 1.5 4mA drive, slow slew rate 1.57 1.60 1.64 ns LVCMOS15_8mA LVCMOS 1.5 8mA drive, slow slew rate 0.01 0.01 0.00 ns LVCMOS12_2mA LVCMOS 1.2 2mA drive, slow slew rate 1.51 1.54 1.58 ns LVCMOS12_6mA LVCMOS 1.2 6mA drive, slow slew rate -0.02 -0.02 -0.02 ns PCI33 PCI, VCCIO = 3.0V 0.19 0.21 0.24 ns 1. 2. 3. 4. 5. Timing adders are characterized but not tested on every device. LVCMOS timing measured with the load specified in Switching Test Condition table. All other standards tested according to the appropriate specifications. Not all I/O standards and drive strengths are supported for all banks. See the Architecture section of this data sheet for details. Commercial timing numbers are shown. Industrial numbers are typically slower and can be extracted from the ispLEVER software. 3-30 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Maximum I/O Buffer Speed 1, 2, 3, 4, 5, 6 Over Recommended Operating Conditions Buffer Description Max. Units 400 MHz Maximum Input Frequency LVDS, VCCIO = 2.5V MLVDS, Emulated, VCCIO = 2.5V 400 MHz BLVDS25 BLVDS, Emulated, VCCIO = 2.5V 400 MHz PPLVDS Point-to-Point LVDS 400 MHz TRLVDS Transition-Reduced LVDS 612 MHz Mini LVDS Mini LVDS 400 MHz 400 MHz SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LVDS25 MLVDS25 LVPECL33 LVPECL, Emulated, VCCIO = 3.0V HSTL18 (all supported classed) HSTL_18 class I, II, VCCIO = 1.8V 400 MHz HSTL15 HSTL_15 class I, VCCIO = 1.5V 400 MHz SSTL33 (all supported classed) SSTL_3 class I, II, VCCIO = 3.0V 400 MHz SSTL25 (all supported classed) SSTL_2 class I, II, VCCIO = 2.5V 400 MHz SSTL18 (all supported classed) SSTL_18 class I, II, VCCIO = 1.8V 400 MHz LVTTL33 LVTTL, VCCIO = 3.0V 166 MHz LVCMOS33 LVCMOS, VCCIO = 3.0V 166 MHz LVCMOS25 LVCMOS, VCCIO = 2.5V 166 MHz LVCMOS18 LVCMOS, VCCIO = 1.8V 166 MHz LVCMOS15 LVCMOS 1.5, VCCIO = 1.5V 166 MHz LVCMOS12 LVCMOS 1.2, VCCIO = 1.2V 166 MHz PCI33 PCI, VCCIO = 3.3V 66 MHz LVDS25E LVDS, Emulated, VCCIO = 2.5V 300 MHz LVDS25 LVDS, VCCIO = 2.5V 612 MHz MLVDS25 MLVDS, Emulated, VCCIO = 2.5V 300 MHz RSDS25 RSDS, Emulated, VCCIO = 2.5V 612 MHz Maximum Output Frequency BLVDS25 BLVDS, Emulated, VCCIO = 2.5V 300 MHz PPLVDS Point-to-point LVDS 612 MHz LVPECL33 LVPECL, Emulated, VCCIO = 3.0V 612 MHz Mini-LVDS Mini LVDS 612 MHz HSTL18 (all supported classed) HSTL_18 class I, II, VCCIO = 1.8V 200 MHz HSTL15 (all supported classed) HSTL_15 class I, VCCIO = 1.5V 200 MHz SSTL33 (all supported classed) SSTL_3 class I, II, VCCIO = 3.0V 233 MHz SSTL25 (all supported classed) SSTL_2 class I, II, VCCIO = 2.5V 233 MHz SSTL18 (all supported classed) SSTL_18 class I, II, VCCIO = 1.8V 266 MHz LVTTL33 LVTTL, VCCIO = 3.0V 166 MHz LVCMOS33 (For all drives) LVCMOS, 3.3V 166 MHz LVCMOS25 (For all drives) LVCMOS, 2.5V 166 MHz LVCMOS18 (For all drives) LVCMOS, 1.8V 166 MHz LVCMOS15 (For all drives) LVCMOS, 1.5V 166 MHz LVCMOS12 (For all drives except 2mA) LVCMOS, VCCIO = 1.2V 166 MHz LVCMOS12 (2mA drive) LVCMOS, VCCIO = 1.2V 100 MHz 3-31 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Maximum I/O Buffer Speed (Continued)1, 2, 3, 4, 5, 6 Over Recommended Operating Conditions Buffer PCI33 PCI, VCCIO = 3.3V Max. Units 66 MHz These maximum speeds are characterized but not tested on every device. Maximum I/O speed for differential output standards emulated with resistors depends on the layout. LVCMOS timing is measured with the load specified in the Switching Test Conditions table of this document. All speeds are measured at fast slew. Actual system operation may vary depending on user logic implementation. Maximum data rate equals 2 times the clock rate when utilizing DDR. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 1. 2. 3. 4. 5. 6. Description 3-32 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor sysCLOCK PLL Timing Over Recommended Operating Conditions Parameter Descriptions Conditions Clock Min. Typ. Max. Units 2 — 500 MHz — 420 MHz fIN Input clock frequency (CLKI, CLKFB) Edge clock Primary clock 2 fOUT Output clock frequency (CLKOP, CLKOS) Edge clock 4 — 500 MHz Primary clock 4 — 420 MHz MHz K-Divider output frequency CLKOK 0.03125 — 250 K2-Divider output frequency CLKOK2 0.667 — 166 MHz fVCO PLL VCO frequency 500 — 1000 MHz fPFD3 Phase detector input frequency SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N fOUT1 fOUT2 Edge clock 2 — 500 MHz Primary clock 2 — 420 MHz ps AC Characteristics tPA tDT Programmable delay unit Output clock duty cycle (CLKOS, at 50% setting) 65 130 260 Edge clock 45 50 55 % fOUT 250 MHz Primary clock 45 50 55 % fOUT > 250MHz Primary clock 30 50 70 % tCPA Coarse phase shift error (CLKOS, at all settings) -5 0 +5 % of period tOPW Output clock pulse width high or low (CLKOS) 1.8 — — ns — — 200 p-p fOUT  420MHz tOPJIT1 Output clock period jitter tSK Input clock to output clock skew when N/M = integer tLOCK2 Lock time tUNLOCK Reset to PLL unlock time to ensure fast reset tHI Input clock high time tLO Input clock low time tIPJIT tRST 420MHz > fOUT  100MHz — — 250 p-p fOUT < 100MHz — — 0.025 UIPP — — 500 p-p 2 to 25 MHz — — 200 us 25 to 500 MHz — — 50 us — — 50 ns 90% to 90% 0.5 — — ns 10% to 10% 0.5 — — ns Input clock period jitter — — 400 p-p Reset signal pulse width high, RESETM, RESETK 10 — — ns — — ns Reset signal pulse width high, CNTRST 500 1. Jitter sample is taken over 10,000 samples of the primary PLL output with clean reference clock with no additional I/O toggling. 2. Output clock is valid after tLOCK for PLL reset and dynamic delay adjustment. 3. Period jitter and cycle-to-cycle jitter numbers are guaranteed for fPFD > 4MHz. For fPFD < 4MHz, the jitter numbers may not be met in certain conditions. Please contact the factory for fPFD < 4MHz. 3-33 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor DLL Timing Over Recommended Operating Conditions Parameter fREF fFB Min. Typ. Max. Units Input reference clock frequency (on-chip or  off-chip) Description Condition 133 — 500 MHz Feedback clock frequency (on-chip or off-chip) 133 — 500 MHz 1 fCLKOP Output clock frequency, CLKOP 133 — 500 MHz fCLKOS2 Output clock frequency, CLKOS 33.3 tPJIT Output clock period jitter (clean input) tDUTY Output clock duty cycle (at 50% levels, 50% duty Edge Clock cycle input clock, 50% duty cycle circuit turned Primary Clock off, time reference delay mode) tDUTYTRD Output clock duty cycle (at 50% levels, arbitrary duty cycle input clock, 50% duty cycle circuit enabled, time reference delay mode) 500 MHz 200 ps p-p 40 60 % 30 70 % Primary Clock < 250MHz 45 55 % Primary Clock 250MHz 30 70 % Edge Clock 45 55 % 40 60 % 30 70 % 45 55 % SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N — — tDUTYCIR Output clock duty cycle (at 50% levels, arbitrary Primary Clock < 250MHz duty cycle input clock, 50% duty cycle circuit Primary Clock  250MHz enabled, clock injection removal mode) with DLL Edge Clock cascading tSKEW3 Output clock to clock skew between two outputs with the same phase setting — — 100 ps tPHASE Phase error measured at device pads between off-chip reference clock and feedback clocks — — +/-400 ps tPWH Input clock minimum pulse width high (at 80% level) 550 — — ps tPWL Input clock minimum pulse width low (at 20% level) 550 — — ps tINSTB Input clock period jitter — — 500 p-p tLOCK DLL lock time 8 — 8200 cycles tRSWD Digital reset minimum pulse width (at 80% level) 3 — — ns tDEL Delay step size 27 45 70 ps tRANGE1 Max. delay setting for single delay block  (64 taps) 1.9 3.1 4.4 ns tRANGE4 Max. delay setting for four chained delay blocks 7.6 12.4 17.6 ns 1. CLKOP runs at the same frequency as the input clock. 2. CLKOS minimum frequency is obtained with divide by 4. 3. This is intended to be a “path-matching” design guideline and is not a measurable specification. 3-34 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor SERDES High-Speed Data Transmitter1 Table 3-6. Serial Output Timing and Levels Symbol Description Frequency Min. Typ. Max. Units 0.25 to 3.125 Gbps 1150 1440 1730 mV, p-p 0.25 to 3.125 Gbps 1080 1350 1620 mV, p-p 0.25 to 3.125 Gbps 1000 1260 1510 mV, p-p 1, 2 0.25 to 3.125 Gbps 840 1130 1420 mV, p-p VTX-DIFF-P-P-1.04 Differential swing (1.04V setting)1, 2 0.25 to 3.125 Gbps 780 1040 1300 VTX-DIFF-P-P-1.44 Differential swing (1.44V setting) 1, 2 VTX-DIFF-P-P-1.35 Differential swing (1.35V setting) 1, 2 VTX-DIFF-P-P-1.26 Differential swing (1.26V setting)1, 2 mV, p-p SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N VTX-DIFF-P-P-1.13 Differential swing (1.13V setting) VTX-DIFF-P-P-0.92 Differential swing (0.92V setting)1, 2 0.25 to 3.125 Gbps 690 920 1150 mV, p-p VTX-DIFF-P-P-0.87 Differential swing (0.87V setting)1, 2 0.25 to 3.125 Gbps 650 870 1090 mV, p-p VTX-DIFF-P-P-0.78 Differential swing (0.78V setting)1, 2 0.25 to 3.125 Gbps 585 780 975 mV, p-p VTX-DIFF-P-P-0.64 Differential swing (0.64V setting)1, 2 0.25 to 3.125 Gbps 480 640 800 mV, p-p VOCM Output common mode voltage — VCCOB -0.75 VCCOB -0.60 VCCOB -0.45 V TTX-R Rise time (20% to 80%) — 145 185 265 ps TTX-F Fall time (80% to 20%) — 145 185 265 ps ZTX-OI-SE Output Impedance 50/75/HiZ Ohms  (single ended) — -20% 50/75/ Hi Z +20% Ohms RLTX-RL Return loss (with package) — 10 TTX-INTRASKEW Lane-to-lane TX skew within a  SERDES quad block (intra-quad) — — — 200 ps TTX-INTERSKEW3 Lane-to-lane skew between SERDES quad blocks (inter-quad) — — — 1UI +200 ps dB 1. All measurements are with 50 ohm impedance. 2. See TN1176, LatticeECP3 SERDES/PCS Usage Guide for actual binary settings and the min-max range. 3. Inter-quad skew is between all SERDES channels on the device and requires the use of a low skew internal reference clock. Table 3-7. Channel Output Jitter Min. Typ. Max. Units Deterministic Description 3.125 Gbps Frequency — — 0.17 UI, p-p Random 3.125 Gbps — — 0.25 UI, p-p Total 3.125 Gbps — — 0.35 UI, p-p Deterministic 2.5Gbps — — 0.17 UI, p-p Random 2.5Gbps — — 0.20 UI, p-p Total 2.5Gbps — — 0.35 UI, p-p Deterministic 1.25 Gbps — — 0.10 UI, p-p Random 1.25 Gbps — — 0.22 UI, p-p Total 1.25 Gbps — — 0.24 UI, p-p Deterministic 622 Mbps — — 0.10 UI, p-p Random 622 Mbps — — 0.20 UI, p-p Total 622 Mbps — — 0.24 UI, p-p Deterministic 250 Mbps — — 0.10 UI, p-p Random 250 Mbps — — 0.18 UI, p-p Total 250 Mbps — — 0.24 UI, p-p Note: Values are measured with PRBS 27-1, all channels operating, FPGA logic active, I/Os around SERDES pins quiet, reference clock @ 10X mode. 3-35 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor SERDES/PCS Block Latency Table 3-8 describes the latency of each functional block in the transmitter and receiver. Latency is given in parallel clock cycles. Figure 3-12 shows the location of each block. Table 3-8. SERDES/PCS Latency Breakdown Item Description Min. Avg. Max. Fixed Bypass Units Transmit Data Latency1 FPGA Bridge - Gearing disabled with different clocks 1 3 5 — 1 word clk FPGA Bridge - Gearing disabled with same clocks — — — 3 1 word clk SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N T1 T2 T3 T4 T5 FPGA Bridge - Gearing enabled 1 3 5 — — word clk 8b10b Encoder — — — 2 1 word clk SERDES Bridge transmit — — — 2 1 word clk Serializer: 8-bit mode — — — 15 + 1 — UI + ps Serializer: 10-bit mode — — — 18 + 1 — UI + ps Pre-emphasis ON — — — 1 + 2 — UI + ps Pre-emphasis OFF — — — 0 + 3 — UI + ps Equalization ON — — — 1 — UI + ps Equalization OFF — — — 2 — UI + ps Receive Data Latency2 R1 R2 Deserializer: 8-bit mode — — — 10 + 3 — UI + ps Deserializer: 10-bit mode — — — 12 + 3 — UI + ps R3 SERDES Bridge receive — — — 2 — word clk R4 Word alignment 3.1 — 4 — — word clk R5 8b10b decoder — — — 1 — word clk R6 Clock Tolerance Compensation 7 15 23 1 1 word clk R7 FPGA Bridge - Gearing disabled with different clocks 1 3 5 — 1 word clk FPGA Bridge - Gearing disabled with same clocks — — — 3 1 word clk FPGA Bridge - Gearing enabled 1 3 5 — — word clk 1. 1 = -245ps, 2 = +88ps, 3 = +112ps. 2. 1 = +118ps, 2 = +132ps, 3 = +700ps. Figure 3-12. Transmitter and Receiver Latency Block Diagram SERDES SERDES Bridge PCS R1 EQ Deserializer 1:8/1:10 CDR HDINNi REFCLK DEC Polarity Adjust BYPASS Receiver R4 R3 R2 FPGA Core FPGA EBRD Clock WA HDINPi FPGA Bridge Recovered Clock REFCLK R5 Elastic Buffer FIFO BYPASS R6 Down Sample FIFO Receive Data BYPASS BYPASS FPGA Receive Clock Transmit Clock TX PLL T2 T1 FPGA Transmit Clock T3 T4 HDOUTPi Serializer 8:1/10:1 HDOUTNi Transmitter Encoder Polarity Adjust Up Sample FIFO BYPASS BYPASS BYPASS 3-36 Transmit Data DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor SERDES High Speed Data Receiver Table 3-9. Serial Input Data Specifications Symbol Description Stream of nontransitions  (CID = Consecutive Identical Digits) @ 10-12 BER 1 Typ. Max. — — 136 2.5G — — 144 1.485G — — 160 622M — — 204 270M — — 228 Units Bits SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N RX-CIDS Min. 3.125G 155M — — 150 — 1760 mV, p-p 0 — VCCA +0.54 V — VCCA V — VCCA +0.2 V 1000 — Bits -20% 50/75/HiZ +20% Ohms 10 — — dB VRX-DIFF-S Differential input sensitivity VRX-IN Input levels VRX-CM-DC Input common mode range (DC coupled) 0.6 VRX-CM-AC Input common mode range (AC coupled)3 0.1 — TRX-RELOCK SCDR re-lock time2 ZRX-TERM Input termination 50/75 Ohm/High Z RLRX-RL Return loss (without package) 296 1. This is the number of bits allowed without a transition on the incoming data stream when using DC coupling. 2. This is the typical number of bit times to re-lock to a new phase or frequency within +/- 300 ppm, assuming 8b10b encoded data. 3. AC coupling is used to interface to LVPECL and LVDS. LVDS interfaces are found in laser drivers and Fibre Channel equipment. LVDS interfaces are generally found in 622 Mbps SERDES devices. 4. Up to 1.76V. Input Data Jitter Tolerance A receiver’s ability to tolerate incoming signal jitter is very dependent on jitter type. High speed serial interface standards have recognized the dependency on jitter type and have specifications to indicate tolerance levels for different jitter types as they relate to specific protocols. Sinusoidal jitter is considered to be a worst case jitter type. Table 3-10. Receiver Total Jitter Tolerance Specification Description Frequency Deterministic Random Condition 600 mV differential eye 3.125 Gbps Min. Typ. Max. Units — — 0.47 UI, p-p 600 mV differential eye — — 0.18 UI, p-p 600 mV differential eye — — 0.65 UI, p-p 600 mV differential eye — — 0.47 UI, p-p 600 mV differential eye — — 0.18 UI, p-p Total 600 mV differential eye — — 0.65 UI, p-p Deterministic 600 mV differential eye — — 0.47 UI, p-p Total Deterministic Random Random 2.5 Gbps 1.25 Gbps Total Deterministic Random Total 622 Mbps 600 mV differential eye — — 0.18 UI, p-p 600 mV differential eye — — 0.65 UI, p-p 600 mV differential eye — — 0.47 UI, p-p 600 mV differential eye — — 0.18 UI, p-p 600 mV differential eye — — 0.65 UI, p-p Note: Values are measured with CJPAT, all channels operating, FPGA Logic active, I/Os around SERDES pins quiet, voltages are nominal, room temperature. 3-37 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Table 3-11. Periodic Receiver Jitter Tolerance Specification Description Frequency Condition Min. Typ. Max. Units Periodic 2.97 Gbps 600 mV differential eye — — 0.24 UI, p-p Periodic 2.5 Gbps 600 mV differential eye — — 0.22 UI, p-p Periodic 1.485 Gbps 600 mV differential eye — — 0.24 UI, p-p Periodic 622 Mbps 600 mV differential eye — — 0.15 UI, p-p Periodic 155 Mbps 600 mV differential eye — — 0.5 UI, p-p SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Note: Values are measured with PRBS 27-1, all channels operating, FPGA Logic active, I/Os around SERDES pins quiet, voltages are nominal, room temperature. 3-38 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor SERDES External Reference Clock The external reference clock selection and its interface are a critical part of system applications for this product. Table 3-12 specifies reference clock requirements, over the full range of operating conditions. Table 3-12. External Reference Clock Specification (refclkp/refclkn) Symbol FREF Description Frequency range 4 Frequency tolerance VREF-IN-SE Input swing, single-ended clock1 Typ. Max. Units 15 — 320 MHz -1000 — 1000 ppm 200 — VCCA mV, p-p 200 — 2*VCCA mV, p-p differential 0 — VCCA + 0.3 V 0.125 — VCCA V SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N FREF-PPM Min. VREF-IN-DIFF Input swing, differential clock VREF-IN Input levels VREF-CM-AC Input common mode range (AC coupled)2 3 DREF Duty cycle 40 — 60 % TREF-R Rise time (20% to 80%) 200 500 1000 ps TREF-F Fall time (80% to 20%) ZREF-IN-TERM-DIFF Differential input termination CREF-IN-CAP Input capacitance 200 500 1000 ps -20% 100/2K +20% Ohms — — 7 pF 1. The signal swing for a single-ended input clock must be as large as the p-p differential swing of a differential input clock to get the same gain at the input receiver. Lower swings for the clock may be possible, but will tend to increase jitter. 2. When AC coupled, the input common mode range is determined by:  (Min input level) + (Peak-to-peak input swing)/2  (Input common mode voltage)  (Max input level) - (Peak-to-peak input swing)/2 3. Measured at 50% amplitude. 4. Depending on the application, the PLL_LOL_SET and CDR_LOL_SET control registers may be adjusted for other tolerance values as described in TN1176, LatticeECP3 SERDES/PCS Usage Guide. Figure 3-13. SERDES External Reference Clock Waveforms 3-39 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor PCI Express Electrical and Timing Characteristics AC and DC Characteristics Over Recommended Operating Conditions Symbol Description Test Conditions Min Typ Max Units 399.88 400 400.12 ps 1 Transmit Unit interval VTX-DIFF_P-P Differential peak-to-peak output voltage 0.8 1.0 1.2 V VTX-DE-RATIO De-emphasis differential output voltage ratio -3 -3.5 -4 dB VTX-CM-AC_P RMS AC peak common-mode output voltage — — 20 mV VTX-RCV-DETECT Amount of voltage change allowed during receiver detection — — 600 mV VTX-DC-CM Tx DC common mode voltage 0 — VCCOB + 5% V ITX-SHORT Output short circuit current — — 90 mA SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N UI VTX-D+=0.0V VTX-D-=0.0V ZTX-DIFF-DC Differential output impedance 80 100 120 Ohms RLTX-DIFF Differential return loss 10 — — dB RLTX-CM Common mode return loss 6.0 — — dB TTX-RISE Tx output rise time 20 to 80% 0.125 — — UI TTX-FALL Tx output fall time 20 to 80% 0.125 — — UI LTX-SKEW Lane-to-lane static output skew for all lanes in port/link — — 1.3 ns TTX-EYE Transmitter eye width 0.75 — — UI TTX-EYE-MEDIAN-TO-MAX-JITTER Maximum time between jitter median and maximum deviation from median — — 0.125 UI 400 400.12 ps Receive1, 2 UI Unit Interval 399.88 3 VRX-DIFF_P-P Differential peak-to-peak input voltage 0.34 — 1.2 V VRX-IDLE-DET-DIFF_P-P Idle detect threshold voltage 65 — 3403 mV VRX-CM-AC_P Receiver common mode voltage for AC coupling — — 150 mV ZRX-DIFF-DC DC differential input impedance 80 100 120 Ohms ZRX-DC DC input impedance 40 50 60 Ohms ZRX-HIGH-IMP-DC Power-down DC input impedance 200K — — Ohms RLRX-DIFF Differential return loss 10 — — dB RLRX-CM Common mode return loss 6.0 — — dB TRX-IDLE-DET-DIFF-ENTERTIME Maximum time required for receiver to recognize and signal an unexpected idle on link — — — ms 1. Values are measured at 2.5 Gbps. 2. Measured with external AC-coupling on the receiver. 3.Not in compliance with PCI Express 1.1 standard. 3-40 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor XAUI/Serial Rapid I/O Type 3 Electrical and Timing Characteristics AC and DC Characteristics Table 3-13. Transmit Over Recommended Operating Conditions Symbol Description Test Conditions Min. Typ. Max. Units 20%-80% — 80 — ps Differential impedance 80 100 120 Ohms Output data deterministic jitter — — 0.17 UI Total output data jitter — — 0.35 UI Differential rise/fall time ZTX_DIFF_DC JTX_DDJ2, 3, 4 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N TRF JTX_TJ 1. 2. 3. 4. 1, 2, 3, 4 Total jitter includes both deterministic jitter and random jitter. Jitter values are measured with each CML output AC coupled into a 50-ohm impedance (100-ohm differential impedance). Jitter and skew are specified between differential crossings of the 50% threshold of the reference signal. Values are measured at 2.5 Gbps. Table 3-14. Receive and Jitter Tolerance Over Recommended Operating Conditions Symbol Description Test Conditions Min. Typ. Max. Units RLRX_DIFF Differential return loss From 100 MHz to 3.125 GHz 10 — — dB RLRX_CM Common mode return loss From 100 MHz to 3.125 GHz 6 — — dB ZRX_DIFF Differential termination resistance 80 100 120 Ohms JRX_DJ1, 2, 3 Deterministic jitter tolerance (peak-to-peak) — — 0.37 UI 1, 2, 3 JRX_RJ Random jitter tolerance (peak-to-peak) — — 0.18 UI JRX_SJ1, 2, 3 Sinusoidal jitter tolerance (peak-to-peak) — — 0.10 UI JRX_TJ1, 2, 3 Total jitter tolerance (peak-to-peak) — — 0.65 UI TRX_EYE Receiver eye opening 0.35 — — UI 1. 2. 3. 4. 5. Total jitter includes deterministic jitter, random jitter and sinusoidal jitter. The sinusoidal jitter tolerance mask is shown in Figure 3-14. Jitter values are measured with each high-speed input AC coupled into a 50-ohm impedance. Jitter and skew are specified between differential crossings of the 50% threshold of the reference signal. Jitter tolerance parameters are characterized when Full Rx Equalization is enabled. Values are measured at 2.5 Gbps. 3-41 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor SJ Amplitude Figure 3-14. XAUI Sinusoidal Jitter Tolerance Mask 8.5UI 20dB/dec SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 0.1UI Data_rate/ 1667 20MHz SJ Frequency Note: The sinusoidal jitter tolerance is measured with at least 0.37UIpp of Deterministic jitter (Dj) and the sum of Dj and Rj (random jitter) is at least 0.55UIpp. Therefore, the sum of Dj, Rj and Sj (sinusoidal jitter) is at least 0.65UIpp (Dj = 0.37, Rj = 0.18, Sj = 0.1). 3-42 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Serial Rapid I/O Type 2 Electrical and Timing Characteristics AC and DC Characteristics Table 3-15. Transmit Symbol Description Test Conditions Min. Typ. Max. Units 20%-80% — 80 — ps Differential impedance 80 100 120 Ohms Output data deterministic jitter — — 0.17 UI Total output data jitter — — 0.35 UI TRF1 Differential rise/fall time ZTX_DIFF_DC JTX_DDJ3, 4, 5 1. 2. 3. 4. 5. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N JTX_TJ 2, 3, 4, 5 Rise and Fall times measured with board trace, connector and approximately 2.5pf load. Total jitter includes both deterministic jitter and random jitter. The random jitter is the total jitter minus the actual deterministic jitter. Jitter values are measured with each CML output AC coupled into a 50-ohm impedance (100-ohm differential impedance). Jitter and skew are specified between differential crossings of the 50% threshold of the reference signal. Values are measured at 2.5 Gbps. Table 3-16. Receive and Jitter Tolerance Symbol Description Test Conditions Min. Typ. Max. Units RLRX_DIFF Differential return loss From 100 MHz to 2.5 GHz 10 — — dB RLRX_CM Common mode return loss From 100 MHz to 2.5 GHz 6 — — dB ZRX_DIFF Differential termination resistance 80 100 120 Ohms JRX_DJ2, 3, 4, 5 Deterministic jitter tolerance (peak-to-peak) — — 0.37 UI 2, 3, 4, 5 JRX_RJ Random jitter tolerance (peak-to-peak) — — 0.18 UI JRX_SJ2, 3, 4, 5 Sinusoidal jitter tolerance (peak-to-peak) — — 0.10 UI — — 0.65 UI 0.35 — — UI JRX_TJ1, 2, 3, 4, 5 Total jitter tolerance (peak-to-peak) TRX_EYE 1. 2. 3. 4. 5. Receiver eye opening Total jitter includes deterministic jitter, random jitter and sinusoidal jitter. The sinusoidal jitter tolerance mask is shown in Figure 3-14. Jitter values are measured with each high-speed input AC coupled into a 50-ohm impedance. Jitter and skew are specified between differential crossings of the 50% threshold of the reference signal. Jitter tolerance, Differential Input Sensitivity and Receiver Eye Opening parameters are characterized when Full Rx Equalization is enabled. Values are measured at 2.5 Gbps. 3-43 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Gigabit Ethernet/Serial Rapid I/O Type 1/SGMII Electrical and Timing  Characteristics AC and DC Characteristics Table 3-17. Transmit Symbol Description Test Conditions Min. Typ. Max. Units TRF Differential rise/fall time — 80 — ps ZTX_DIFF_DC Differential impedance 80 100 120 Ohms JTX_DDJ3, 4, 5 Output data deterministic jitter — — 0.10 UI JTX_TJ2, 3, 4, 5 Total output data jitter SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 1. 2. 3. 4. 5. 20%-80% — — 0.24 UI Rise and fall times measured with board trace, connector and approximately 2.5pf load. Total jitter includes both deterministic jitter and random jitter. The random jitter is the total jitter minus the actual deterministic jitter. Jitter values are measured with each CML output AC coupled into a 50-ohm impedance (100-ohm differential impedance). Jitter and skew are specified between differential crossings of the 50% threshold of the reference signal. Values are measured at 1.25 Gbps. Table 3-18. Receive and Jitter Tolerance Symbol Description Test Conditions RLRX_DIFF Differential return loss From 100 MHz to 1.25 GHz RLRX_CM Common mode return loss From 100 MHz to 1.25 GHz ZRX_DIFF Differential termination resistance Min. Typ. Max. Units 10 — — dB 6 — — dB 80 100 120 Ohms JRX_DJ1, 2, 3, 4, 5 Deterministic jitter tolerance (peak-to-peak) — — 0.34 UI JRX_RJ1, 2, 3, 4, 5 Random jitter tolerance (peak-to-peak) — — 0.26 UI 1, 2, 3, 4, 5 JRX_SJ Sinusoidal jitter tolerance (peak-to-peak) JRX_TJ1, 2, 3, 4, 5 Total jitter tolerance (peak-to-peak) TRX_EYE 1. 2. 3. 4. 5. Receiver eye opening — — 0.11 UI — — 0.71 UI 0.29 — — UI Total jitter includes deterministic jitter, random jitter and sinusoidal jitter. The sinusoidal jitter tolerance mask is shown in Figure 3-14. Jitter values are measured with each high-speed input AC coupled into a 50-ohm impedance. Jitter and skew are specified between differential crossings of the 50% threshold of the reference signal. Jitter tolerance, Differential Input Sensitivity and Receiver Eye Opening parameters are characterized when Full Rx Equalization is enabled. Values are measured at 1.25 Gbps. 3-44 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor SMPTE SD/HD-SDI/3G-SDI (Serial Digital Interface) Electrical and Timing Characteristics AC and DC Characteristics Table 3-19. Transmit Symbol Description Test Conditions Min. Typ. Max. Units BRSDO Serial data rate 270 — 2975 Mbps TJALIGNMENT 2 Serial output jitter, alignment 270 Mbps — — 0.20 UI 2 Serial output jitter, alignment 1485 Mbps — — 0.20 UI SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N TJALIGNMENT TJALIGNMENT1, 2 Serial output jitter, alignment 2970Mbps — — 0.30 UI TJTIMING Serial output jitter, timing 270 Mbps — — 0.20 UI TJTIMING Serial output jitter, timing 1485 Mbps — — 1.0 UI TJTIMING Serial output jitter, timing 2970 Mbps — — 2.0 UI Notes: 1. Timing jitter is measured in accordance with SMPTE RP 184-1996, SMPTE RP 192-1996 and the applicable serial data transmission standard, SMPTE 259M-1997 or SMPTE 292M (proposed). A color bar test pattern is used.The value of fSCLK is 270 MHz or 360 MHz for SMPTE 259M, 540 MHz for SMPTE 344M or 1485 MHz for SMPTE 292M serial data rates. See the Timing Jitter Bandpass section. 2. Jitter is defined in accordance with SMPTE RP1 184-1996 as: jitter at an equipment output in the absence of input jitter. 3. All Tx jitter is measured at the output of an industry standard cable driver; connection to the cable driver is via a 50 ohm impedance differential signal from the Lattice SERDES device. 4. The cable driver drives: RL=75 ohm, AC-coupled at 270, 1485, or 2970 Mbps, RREFLVL=RREFPRE=4.75kohm 1%. Table 3-20. Receive Symbol Description BRSDI Serial input data rate CID Stream of non-transitions (=Consecutive Identical Digits) Test Conditions Min. Typ. Max. Units 270 — 2970 Mbps 7(3G)/26(SMPTE Triple rates) @ 10-12 BER — — Bits Table 3-21. Reference Clock Symbol Description Test Conditions Min. Typ. Max. Units FVCLK Video output clock frequency 27 — 74.25 MHz DCV Duty cycle, video clock 45 50 55 % 3-45 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor HDMI (High-Definition Multimedia Interface) Electrical and Timing  Characteristics AC and DC Characteristics Table 3-22. Transmit and Receive1, 2 Spec. Compliance Symbol Description Min. Spec. Max. Spec. Units Intra-pair Skew — 75 ps Inter-pair Skew — 800 ps TMDS Differential Clock Jitter — 0.25 UI Termination Resistance 40 60 Ohms VICM Input AC Common Mode Voltage (50-ohm Setting) — 50 mV TMDS Clock Jitter Clock Jitter Tolerance — 0.25 UI SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Transmit Receive RT 1. Output buffers must drive a translation device. Max. speed is 2Gbps. If translation device does not modify rise/fall time, the maximum speed is 1.5Gbps. 2. Input buffers must be AC coupled in order to support the 3.3V common mode. Generally, HDMI inputs are terminated by an external cable equalizer before data/clock is forwarded to the LatticeECP3 device. 3-46 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-15. Test Loads Test Loads VDDSD 75Ω 1% VDDIO SDO SDO IOL CL Hi-Z test eqpt. ≥ 5Ωk (atteunation 0dB) 1.0µF SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N S1 75Ω test eqpt. (atteunation 0dB) CMOS outputs CL IOH VDDSD S2 CL including probe and jig capacitance, 3pF max. S1 - open, S2 - closed for VOH measurement. S1 - closed, S2 - open for VOL measurement. 5.5-30pF* 75Ω 1% 50 test eqpt. (atteunation 3.5dB) SDO SDO CL 1.0µF *Risetime compensation. Timing Jitter Bandpass Jitter Bandpass 0db Slopes: 20dB/Decade Passband Ripple < ±1dB Stopband Rejection 1/10 fSCLK 10Hz Jitter Frequency 3-47 24.9Ω 1% DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 sysCONFIG Port Timing Specifications Over Recommended Operating Conditions Parameter Description Min. Max. Units POR, Configuration Initialization, and Wakeup 23 ms — 6 ms tVMC Time from tICFG to the Valid Master MCLK — 5 µs tPRGM PROGRAMN Low Time to Start Configuration 25 — ns tPRGMRJ PROGRAMN Pin Pulse Rejection — 10 ns tDPPINIT Delay Time from PROGRAMN Low to INITN Low — 37 ns tDPPDONE Delay Time from PROGRAMN Low to DONE Low — 37 ns tDINIT PROGRAMN High to INITN High Delay — 1 ms tMWC Additional Wake Master Clock Signals After DONE Pin is High 100 500 cycles tCZ MCLK From Active To Low To High-Z — 300 ns 5 — ns SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Time from the Application of VCC, VCCAUX or VCCIO8* (Whichever Master mode is the Last to Cross the POR Trip Point) to the Rising Edge of Slave mode INITN — tICFG All Configuration Modes tSUCDI Data Setup Time to CCLK/MCLK tHCDI Data Hold Time to CCLK/MCLK 1 — ns tCODO CCLK/MCLK to DOUT in Flowthrough Mode — 12 ns 5 — ns Slave Serial tSSCH CCLK Minimum High Pulse tSSCL CCLK Minimum Low Pulse fCCLK CCLK Frequency 5 — ns Without encryption — 33 MHz With encryption — 20 MHz Master and Slave Parallel tSUCS CSN[1:0] Setup Time to CCLK/MCLK 7 — ns tHCS CSN[1:0] Hold Time to CCLK/MCLK 1 — ns tSUWD WRITEN Setup Time to CCLK/MCLK 7 — ns tHWD WRITEN Hold Time to CCLK/MCLK 1 — ns tDCB CCLK/MCLK to BUSY Delay Time — 12 ns tCORD CCLK to Out for Read Data — 12 ns tBSCH CCLK Minimum High Pulse 6 — ns tBSCL CCLK Minimum Low Pulse 6 — ns tBSCYC Byte Slave Cycle Time fCCLK CCLK/MCLK Frequency 30 — ns Without encryption — 33 MHz With encryption — 20 MHz Master and Slave SPI tCFGX INITN High to MCLK Low — 80 ns 0.2 2 µs 15 tCSSPI INITN High to CSSPIN Low tSOCDO MCLK Low to Output Valid — tCSPID CSSPIN[0:1] Low to First MCLK Edge Setup Time 0.3 fCCLK CCLK Frequency ns µs Without encryption — 33 MHz With encryption — 20 MHz tSSCH CCLK Minimum High Pulse 5 — ns tSSCL CCLK Minimum Low Pulse 5 — ns tHLCH HOLDN Low Setup Time (Relative to CCLK) 5 — ns 3-48 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 sysCONFIG Port Timing Specifications (Continued) Over Recommended Operating Conditions Parameter tCHHH Description HOLDN Low Hold Time (Relative to CCLK) Min. Max. Units 5 — ns 5 — ns Master and Slave SPI (Continued) HOLDN High Hold Time (Relative to CCLK) tHHCH HOLDN High Setup Time (Relative to CCLK) 5 — ns tHLQZ HOLDN to Output High-Z — 9 ns tHHQX HOLDN to Output Low-Z — 9 ns SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N tCHHL Parameter Master Clock Frequency Min. Max. Units Selected value - 15% Selected value + 15% MHz 40 60 % Duty Cycle Figure 3-16. sysCONFIG Parallel Port Read Cycle tBSCL tBSCYC tBSCH CCLK t SUCS tHCS tSUWD t HWD CS1N CSN WRITEN tDCB BUSY t CORD D[0:7] Byte 0 Byte 1 *n = last byte of read cycle. 3-49 Byte 2 Byte n* DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-17. sysCONFIG Parallel Port Write Cycle tBSCYC tBSCL tBSCH CCLK 1 t SUCS tHCS CS1N SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N CSN t SUWD t HWD WRITEN tDCB BUSY t HCBDI tSUCBDI D[0:7] Byte 0 Byte 1 Byte 2 Byte n 1. In Master Parallel Mode the FPGA provides CCLK (MCLK). In Slave Parallel Mode the external device provides CCLK. Figure 3-18. sysCONFIG Master Serial Port Timing CCLK (output) t HMCDI tSUMCDI DIN t CODO DOUT Figure 3-19. sysCONFIG Slave Serial Port Timing tSSCL tSSCH CCLK (input) tHSCDI t SUSCDI DIN t CODO DOUT 3-50 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-20. Power-On-Reset (POR) Timing VCC / VCCAUX / VCCIO81 tICFG INITN DONE SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N t VMC CCLK 2 CFG[2:0] 3 Valid 1. Time taken from VCC, VCCAUX or VCCIO8, whichever is the last to cross the POR trip point. 2. Device is in a Master Mode (SPI, SPIm). 3. The CFG pins are normally static (hard wired). Figure 3-21. sysCONFIG Port Timing 3-51 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-22. Configuration from PROGRAMN Timing tPRGMRJ PROGRAMN t DINIT tDPPINIT DONE t DINITD SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N INITN CCLK CFG[2:0] 1 Valid t IODISS USER I/O 1. The CFG pins are normally static (hard wired) Figure 3-23. Wake-Up Timing PROGRAMN INITN DONE Wake-Up tMWC CCLK tIOENSS USER I/O 3-52 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Figure 3-24. Master SPI Configuration Waveforms Capture CR0 Capture CFGx VCC PROGRAMN DONE SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N INITN CSSPIN 0 1 2 3 … 7 8 9 10 … 31 32 33 34 … 127 128 CCLK SISPI Opcode Address Ignore SOSPI 3-53 Valid Bitstream DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor JTAG Port Timing Specifications Over Recommended Operating Conditions Symbol Max Units TCK clock frequency Parameter — 25 MHz tBTCP TCK [BSCAN] clock pulse width 40 — ns tBTCPH TCK [BSCAN] clock pulse width high 20 — ns tBTCPL TCK [BSCAN] clock pulse width low 20 — ns tBTS TCK [BSCAN] setup time 10 — ns tBTH TCK [BSCAN] hold time 8 — ns tBTRF TCK [BSCAN] rise/fall time 50 — mV/ns — 10 ns SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Min fMAX tBTCO TAP controller falling edge of clock to valid output tBTCODIS TAP controller falling edge of clock to valid disable — 10 ns tBTCOEN TAP controller falling edge of clock to valid enable — 10 ns tBTCRS BSCAN test capture register setup time 8 — ns tBTCRH BSCAN test capture register hold time 25 — ns tBUTCO BSCAN test update register, falling edge of clock to valid output — 25 ns tBTUODIS BSCAN test update register, falling edge of clock to valid disable — 25 ns tBTUPOEN BSCAN test update register, falling edge of clock to valid enable — 25 ns Figure 3-25. JTAG Port Timing Waveforms TMS TDI tBTS tBTCPH tBTH tBTCP tBTCPL TCK tBTCO tBTCOEN TDO Valid Data tBTCRS Data to be captured from I/O tBTCODIS Valid Data tBTCRH Data Captured tBTUPOEN tBUTCO Data to be driven out to I/O Valid Data 3-54 tBTUODIS Valid Data DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Switching Test Conditions Figure 3-26 shows the output test load that is used for AC testing. The specific values for resistance, capacitance, voltage, and other test conditions are shown in Table 3-23. Figure 3-26. Output Test Load, LVTTL and LVCMOS Standards VT SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N R1 DUT Test Poi nt R2 CL* *CL Includes Test Fixture and Probe Capacitance Table 3-23. Test Fixture Required Components, Non-Terminated Interfaces Test Condition LVTTL and other LVCMOS settings (L -> H, H -> L) R1  LVCMOS 2.5 I/O (Z -> H)  R2  LVCMOS 2.5 I/O (Z -> L) 1M LVCMOS 2.5 I/O (H -> Z)  LVCMOS 2.5 I/O (L -> Z) 100 CL 0pF VT LVCMOS 3.3 = 1.5V — LVCMOS 2.5 = VCCIO/2 — LVCMOS 1.8 = VCCIO/2 — LVCMOS 1.5 = VCCIO/2 — LVCMOS 1.2 = VCCIO/2 — 1M 0pF VCCIO/2 — VCCIO  0pF VCCIO/2 100 0pF —  VOH - 0.10 0pF VOL + 0.10 VCCIO Note: Output test conditions for all other interfaces are determined by the respective standards. 3-55 Timing Ref. DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor sysI/O Differential Electrical Characteristics Transition Reduced LVDS (TRLVDS DC Specification) Over Recommended Operating Conditions Symbol Description Min. Nom. 3.3 VCCO Driver supply voltage (+/- 5%) 3.14 VID Input differential voltage 150 VICM Input common mode voltage VCCO Termination supply voltage Max. 3 3.3 3.47 V 1200 mV 3.265 V 3.47 V SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 3.14 Units RT Termination resistance (off-chip) 45 50 55 Ohms Note: LatticeECP3 only supports the TRLVDS receiver. VCCO = 3.3V RT Transmitter RT Z0 Receiver Current Source Mini LVDS Over Recommended Operating Conditions Parameter Symbol ZO RT Description Single-ended PCB trace impedance Min. Typ. Max. Units 30 50 75 ohms Differential termination resistance 50 100 150 ohms VOD Output voltage, differential, |VOP - VOM| 300 — 600 mV VOS Output voltage, common mode, |VOP + VOM|/2 1 1.2 1.4 V VOD Change in VOD, between H and L — — 50 mV VID Change in VOS, between H and L — — 50 mV VTHD Input voltage, differential, |VINP - VINM| 200 — 600 mV VCM Input voltage, common mode, |VINP + VINM|/2 0.3+(VTHD/2) — 2.1-(VTHD/2) TR, TF Output rise and fall times, 20% to 80% — — 550 ps TODUTY Output clock duty cycle 40 — 60 % Note: Data is for 6mA differential current drive. Other differential driver current options are available. 3-56 DC and Switching Characteristics LatticeECP3 Family Data Sheet Lattice Semiconductor Point-to-Point LVDS (PPLVDS) Over Recommended Operating Conditions Description Output driver supply (+/- 5%) Min. Typ. Max. Units 3.14 3.3 3.47 V 2.25 2.5 2.75 V Input differential voltage 100 400 mV Input common mode voltage 0.2 2.3 V Output differential voltage 130 400 mV Output common mode voltage 0.5 1.4 V SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N 0.8 RSDS Over Recommended Operating Conditions Parameter Symbol Description Min. Typ. Max. Units VOD Output voltage, differential, RT = 100 ohms 100 200 600 mV VOS Output voltage, common mode 0.5 1.2 1.5 V IRSDS Differential driver output current 1 2 6 mA VTHD Input voltage differential 100 — — mV VCM Input common mode voltage 0.3 — 1.5 V TR, TF Output rise and fall times, 20% to 80% — 500 — ps TODUTY Output clock duty cycle 35 50 65 % Note: Data is for 2mA drive. Other differential driver current options are available. 3-57 LatticeECP3 Family Data Sheet Pinout Information March 2010 Preliminary Data Sheet DS1021 Signal Descriptions Signal Name I/O Description General Purpose SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N [Edge] indicates the edge of the device on which the pad is located. Valid edge designations are L (Left), B (Bottom), R (Right), T (Top). [Row/Column Number] indicates the PFU row or the column of the device on which the PIC exists. When Edge is T (Top) or B (Bottom), only need to specify Column Number. When Edge is L (Left) or R (Right), only need to specify Row Number. P[Edge] [Row/Column Number]_[A/B] I/O [A/B] indicates the PIO within the PIC to which the pad is connected. Some of these user-programmable pins are shared with special function pins. These pins, when not used as special purpose pins, can be programmed as I/Os for user logic. During configuration the user-programmable I/Os are tri-stated with an internal pull-up resistor enabled. If any pin is not used (or not bonded to a package pin), it is also tri-stated with an internal pull-up resistor enabled after configuration. P[Edge][Row Number]E_[A/B/C/D] I These general purpose signals are input-only pins and are located near the PLLs. GSRN I Global RESET signal (active low). Any I/O pin can be GSRN. NC — No connect. RESERVED — This pin is reserved and should not be connected to anything on the board. GND — Ground. Dedicated pins. VCC — Power supply pins for core logic. Dedicated pins. VCCAUX — Auxiliary power supply pin. This dedicated pin powers all the differential and referenced input buffers. VCCIOx — Dedicated power supply pins for I/O bank x. VCCA — SERDES, transmit, receive, PLL and reference clock buffer power supply. VCCPLL_[LOC] — General purpose PLL supply pins where LOC=L (left) or R (right). VREF1_x, VREF2_x — Reference supply pins for I/O bank x. Pre-determined pins in each bank are assigned as VREF inputs. When not used, they may be used as I/O pins. VTTx — Power supply for on-chip termination of I/Os (Required for DDR3 and LVDS at 1.25Gbps). XRES1 — 10K ohm +/-1% resistor must be connected between this pad and ground. PLL, DLL and Clock Functions [LOC][num]_GPLL[T, C]_IN_[index] I General Purpose PLL (GPLL) input pads: LUM, LLM, RUM, RLM, num = row from center, T = true and C = complement, index A,B,C...at each side. [LOC][num]_GPLL[T, C]_FB_[index] I Optional feedback GPLL input pads: LUM, LLM, RUM, RLM, num = row from center, T = true and C = complement, index A,B,C...at each side. [LOC]0_GDLLT_IN_[index] I/O General Purpose DLL (GDLL) input pads where LOC=RUM or LUM, T is True Complement, index is A or B. [LOC]0_GDLLT_FB_[index] I/O Optional feedback GDLL input pads where LOC=RUM or LUM, T is True Complement, index is A or B. PCLK[T, C][n:0]_[3:0] I Primary Clock pads, T = true and C = complement, n per side, indexed by bank and 0, 1, 2, 3 within bank. © 2010 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com 4-1 DS1021 Pinout Information_01.2 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Signal Descriptions (Cont.) Signal Name I/O Description [LOC]DQS[num] I/O DQ input/output pads: T (top), R (right), B (bottom), L (left), DQS, num = ball function number. [LOC]DQ[num] I/O DQ input/output pads: T (top), R (right), B (bottom), L (left), DQ, associated DQS number. Test and Programming (Dedicated Pins) TMS I Test Mode Select input, used to control the 1149.1 state machine. Pull-up is enabled during configuration. Test Clock input pin, used to clock the 1149.1 state machine. No pull-up enabled. TDI I Test Data in pin. Used to load data into device using 1149.1 state machine. After power-up, this TAP port can be activated for configuration by sending appropriate command. (Note: once a configuration port is selected it is locked. Another configuration port cannot be selected until the power-up sequence). Pull-up is enabled during configuration. TDO O Output pin. Test Data Out pin used to shift data out of a device using 1149.1. VCCJ — Power supply pin for JTAG Test Access Port. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N I TCK Configuration Pads (Used During sysCONFIG) CFG[2:0] INITN I Mode pins used to specify configuration mode values latched on rising edge of INITN. During configuration, a pull-up is enabled. These are dedicated pins. I/O Open Drain pin. Indicates the FPGA is ready to be configured. During configuration, a pull-up is enabled. It is a dedicated pin. I Initiates configuration sequence when asserted low. This pin always has an active pull-up. It is a dedicated pin. DONE I/O Open Drain pin. Indicates that the configuration sequence is complete, and the startup sequence is in progress. It is a dedicated pin. CCLK I Input Configuration Clock for configuring an FPGA in Slave SPI, Serial, and CPU modes. It is a dedicated pin. MCLK I/O Output Configuration Clock for configuring an FPGA in SPI, SPIm, and Master configuration modes. BUSY/SISPI O Parallel configuration mode busy indicator. SPI/SPIm mode data output. CSN/SN/OEN I/O Parallel configuration mode active-low chip select. Slave SPI chip select.  Parallel burst Flash output enable. PROGRAMN CS1N/HOLDN/RDY I Parallel configuration mode active-low chip select. Slave SPI hold input. WRITEN I Write enable for parallel configuration modes. DOUT/CSON/CSSPI1N O Serial data output. Chip select output. SPI/SPIm mode chip select. sysCONFIG Port Data I/O for Parallel mode. Open drain during configuration. D[0]/SPIFASTN I/O sysCONFIG Port Data I/O for SPI or SPIm. When using the SPI or SPIm mode, this pin should either be tied high or low, must not be left floating. Open drain during configuration. D1 I/O Parallel configuration I/O. Open drain during configuration. D2 I/O Parallel configuration I/O. Open drain during configuration. D3/SI I/O Parallel configuration I/O. Slave SPI data input. Open drain during configuration. D4/SO I/O Parallel configuration I/O. Slave SPI data output. Open drain during configuration. D5 I/O Parallel configuration I/O. Open drain during configuration. I/O Parallel configuration I/O. SPI/SPIm data input. Open drain during configuration. D6/SPID1 4-2 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Signal Descriptions (Cont.) Signal Name D7/SPID0 DI/CSSPI0N/CEN I/O Description I/O Parallel configuration I/O. SPI/SPIm data input. Open drain during configuration. I/O Serial data input for slave serial mode. SPI/SPIm mode chip select. 2 Dedicated SERDES Signals PCS[Index]_HDINNm I High-speed input, negative channel m PCS[Index]_HDOUTNm O High-speed output, negative channel m I Negative Reference Clock Input SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N PCS[Index]_REFCLKN PCS[Index]_HDINPm I High-speed input, positive channel m PCS[Index]_HDOUTPm O High-speed output, positive channel m PCS[Index]_REFCLKP I Positive Reference Clock Input PCS[Index]_VCCOBm — Output buffer power supply, channel m (1.2V/1.5) PCS[Index]_VCCIBm — Input buffer power supply, channel m (1.2V/1.5V) 1. When placing switching I/Os around these critical pins that are designed to supply the device with the proper reference or supply voltage, care must be given. 2. m defines the associated channel in the quad. 4-3 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor PICs and DDR Data (DQ) Pins Associated with the DDR Strobe (DQS) Pin PICs Associated with DQS Strobe PIO Within PIC DDR Strobe (DQS) and Data (DQ) Pins For Left and Right Edges of the Device P[Edge] [n-3] DQ B DQ A DQ B DQ A DQ B DQ A [Edge]DQSn B DQ A DQ B DQ A DQ B DQ A DQ B DQ A DQ B DQ A DQ B DQ A [Edge]DQSn B DQ A DQ B DQ A DQ B DQ SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N P[Edge] [n-2] A P[Edge] [n-1] P[Edge] [n] P[Edge] [n+1] P[Edge] [n+2] For Top Edge of the Device P[Edge] [n-3] P[Edge] [n-2] P[Edge] [n-1] P[Edge] [n] P[Edge] [n+1] P[Edge] [n+2] Note: “n” is a row PIC number. 4-4 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Pin Information Summary Pin Information Summary Pin Type ECP3-17EA ECP3-35EA ECP3-70E/EA 256 484 256 484 672 484 672 1156 ftBGA fpBGA ftBGA fpBGA fpBGA fpBGA fpBGA fpBGA 36 26 14 24 14 36 36 36 48 78 6 12 6 24 24 24 34 36 Bank 3 18 44 16 54 59 54 59 86 Bank 6 20 44 18 63 61 63 67 86 Bank 7 19 32 19 36 42 36 48 54 Bank 8 24 24 24 24 24 24 24 24 Bank 0 0 0 0 0 0 0 0 0 Bank 1 0 0 0 0 0 0 0 0 Bank 2 2 2 2 4 4 4 8 8 Bank 3 0 0 2 4 4 4 12 12 Bank 6 0 0 2 4 4 4 12 12 Bank 7 4 4 4 4 4 4 8 8 Bank 8 0 0 0 0 0 0 0 0 Bank 0 0 0 0 0 0 0 0 0 Bank 1 0 0 0 0 0 0 0 0 Bank 2 0 0 0 0 0 0 0 0 General Purpose Outputs per Bank 3 Bank Bank 6 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Bank 7 0 0 0 0 0 0 0 0 Bank 8 0 0 0 0 0 0 0 0 26 Bank 1 Bank 2 42 48 42 60 86 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N General Purpose Inputs/Outputs per Bank Bank 0 General Purpose Inputs per Bank Total Single-Ended User I/O 133 222 133 295 310 295 380 490 VCC 6 16 6 16 32 16 32 32 VCCAUX 4 8 4 8 12 8 12 16 VTT 4 4 4 4 4 4 4 8 VCCA 4 4 4 4 8 4 8 16 VCCPLL 2 4 2 4 4 4 4 4 Bank 0 2 2 2 2 4 2 4 4 Bank 1 2 2 2 2 4 2 4 4 Bank 2 2 2 2 2 4 2 4 4 Bank 3 2 2 2 2 4 2 4 4 Bank 6 2 2 2 2 4 2 4 4 Bank 7 2 2 2 2 4 2 4 4 Bank 8 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 VCCIO VCCJ TAP 4 4 4 4 4 4 4 4 GND, GNDIO 50 98 50 98 139 98 139 233 NC 0 73 0 0 96 0 0 238 Reserved1 0 2 0 2 2 2 2 2 SERDES 26 26 26 26 26 26 52 78 Miscellaneous Pins 8 8 8 8 8 8 8 8 Total Bonded Pins 256 484 256 484 672 484 672 1156 4-5 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Pin Information Summary (Cont.) Pin Information Summary Pin Type Emulated Differential I/O per Bank ECP3-17EA 256 ftBGA ECP3-35EA 484 fpBGA 256 ftBGA 484 fpBGA 672 fpBGA Bank 0 13 18 13 21 24 Bank 1 7 12 7 18 18 Bank 2 2 4 1 8 8 Bank 3 4 13 5 20 19 5 13 6 22 20 6 10 6 11 13 Bank 8 12 12 12 12 12 Bank 0 0 0 0 0 0 Bank 1 0 0 0 0 0 Bank 2 2 3 3 6 6 Highspeed Differential I/O per Bank 3 Bank Bank 6 5 9 4 9 12 5 9 4 11 12 Bank 7 5 8 5 9 10 Bank 8 0 0 0 0 0 Bank 0 26/13 36/18 26/13 42/21 48/24 Bank 1 14/7 24/12 14/7 36/18 36/18 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Bank 6 Bank 7 Total Single Ended/ Total Differential I/O per Bank DDR Groups Bonded per Bank Bank 2 8/4 14/7 8/4 28/14 28/14 Bank 3 18/9 44/22 18/9 58/29 63/31 Bank 6 20/10 44/22 20/10 67/33 65/32 Bank 7 23/11 36/18 23/11 40/20 46/23 Bank 8 24/12 24/12 24/12 24/12 24/12 Bank 0 2 3 2 3 4 Bank 1 1 2 1 3 3 Bank 2 0 1 0 2 2 Bank 3 1 3 1 3 4 Bank 6 1 3 1 4 4 Bank 7 1 2 1 3 3 Configuration Bank 8 0 0 0 0 0 1 1 1 1 1 SERDES Quads 1. These pins must remain floating on the board. 4-6 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Pin Information Summary (Cont.) Pin Information Summary Pin Type ECP3-70E 484 fpBGA 672 fpBGA ECP3-70EA 1156 fpBGA 484 fpBGA 672 fpBGA Bank 0 21 30 43 21 Bank 1 18 24 39 18 24 39 Bank 2 10 15 16 8 12 13 Bank 3 23 27 39 20 23 33 Bank 6 26 30 39 22 25 33 Bank 7 14 20 22 11 16 18 Bank 8 12 12 12 12 12 12 Bank 0 0 0 0 0 0 0 Bank 1 0 0 0 0 0 0 Bank 2 High-Speed Differential Bank 3 I/O per Bank Bank 6 4 6 6 6 9 9 6 8 10 9 12 16 7 9 10 11 14 16 13 43 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Emulated Differential  I/O per Bank 30 1156 fpBGA Total Single-Ended/ Total Differential I/O per Bank DDR Groups Bonded per Bank SERDES Quads Bank 7 6 8 9 9 12 Bank 8 0 0 0 0 0 0 Bank 0 42/21 60/30 86/43 42/21 60/30 86/43 Bank 1 36/18 48/24 78/39 36/18 48/24 78/39 Bank 2 28/14 42/21 44/22 28/14 42/21 44/22 Bank 3 58/29 71/35 98/49 58/29 71/35 98/49 Bank 6 67/33 79/38 98/49 67/33 78/39 98/49 Bank 7 40/20 56/28 62/31 40/20 56/28 62/31 Bank 8 24/12 24/12 24/12 24/12 24/12 24/12 Bank 0 3 5 7 3 5 7 Bank 1 3 4 7 3 4 7 Bank 2 2 3 3 2 3 3 Bank 3 3 4 5 3 4 5 Bank 6 4 4 5 4 4 5 Bank 7 3 4 4 3 4 4 Configuration Bank 8 0 0 0 0 0 0 1 2 3 1 2 3 4-7 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Pin Information Summary (Cont.) Pin Information Summary ECP3-150EA 484 fpBGA 672 fpBGA 1156 fpBGA 672 fpBGA 1156 fpBGA Bank 0 42 60 86 60 94 Bank 1 36 48 78 48 86 Bank 2 24 34 36 34 58 Bank 3 54 59 86 59 104 Bank 6 63 67 86 67 104 Pin Type SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N General Purpose Inputs/Outputs per bank ECP3-95E/EA Bank 7 36 48 54 48 76 Bank 8 24 24 24 24 24 Bank 0 0 0 0 0 0 Bank 1 0 0 0 0 0 Bank 2 4 8 8 8 8 Bank 3 4 12 12 12 12 Bank 6 4 12 12 12 12 Bank 7 4 8 8 8 8 Bank 8 0 0 0 0 0 Bank 0 0 0 0 0 0 Bank 1 0 0 0 0 0 Bank 2 0 0 0 0 0 General Purpose Outputs per Bank 3 Bank Bank 6 0 0 0 0 0 0 0 0 0 0 Bank 7 0 0 0 0 0 Bank 8 0 0 0 0 0 Total Single-Ended User I/O 295 380 490 380 586 VCC 16 32 32 32 32 VCCAUX 8 12 16 12 16 VTT 4 4 8 4 8 VCCA 4 8 16 8 16 VCCPLL 4 4 4 4 4 Bank 0 2 4 4 4 4 Bank 1 2 4 4 4 4 Bank 2 2 4 4 4 4 Bank 3 2 4 4 4 4 Bank 6 2 4 4 4 4 Bank 7 2 4 4 4 4 Bank 8 2 2 2 2 2 1 1 1 1 1 General Purpose Inputs per Bank VCCIO VCCJ TAP 4 4 4 4 4 GND, GNDIO 98 139 233 139 233 NC 0 0 238 0 116 Reserved1 2 2 2 2 2 SERDES 26 52 78 52 104 Miscellaneous Pins 8 8 8 8 8 Total Bonded Pins 484 672 1156 672 1156 4-8 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Pin Information Summary (Cont.) Pin Information Summary ECP3-95EA ECP3-150EA 672 fpBGA 1156 fpBGA 484 fpBGA 672 fpBGA 1156 fpBGA 672 fpBGA 1156 fpBGA Bank 0 21 30 43 21 30 43 30 47 Bank 1 18 24 39 18 24 39 24 43 Bank 2 10 15 16 8 12 13 12 18 Bank 3 23 27 39 20 23 33 23 37 Bank 6 26 30 39 22 25 33 25 37 Bank 7 14 20 22 11 16 18 16 24 Bank 8 12 12 12 12 12 12 12 12 Bank 0 0 0 0 0 0 0 0 0 Bank 1 0 0 0 0 0 0 0 0 Bank 2 4 6 6 6 9 9 9 15 Bank 3 6 8 10 9 12 16 12 21 Bank 6 7 9 10 11 14 16 14 21 Bank 7 6 8 9 9 12 13 12 18 Pin Type SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Emulated Differential I/O  per Bank ECP3-95E 484 fpBGA Highspeed Differential I/O  per Bank Bank 8 0 0 0 0 0 0 0 0 Bank 0 42/21 60/30 86/43 42/21 60/30 86/43 60/30 94/47 Bank 1 36/18 48/24 78/39 36/18 48/24 78/39 48/24 86/43 Total Single Ended/ Bank 2 Bank 3 Total Differential I/O per Bank Bank 6 28/14 42/21 44/22 28/14 42/21 44/22 42/21 66/33 58/29 71/35 98/49 58/29 71/35 98/49 71/35 116/58 67/33 78/39 98/49 67/33 78/39 98/49 78/39 116/58 Bank 7 40/20 56/28 62/31 40/20 56/28 62/31 56/28 84/42 Bank 8 24/12 24/12 24/12 24/12 24/12 24/12 24/12 24/12 Bank 0 3 5 7 3 5 7 5 7 Bank 1 3 4 7 3 4 7 4 7 Bank 2 2 3 3 2 3 3 3 4 Bank 3 3 4 5 3 4 5 4 7 Bank 6 4 4 5 4 4 5 4 7 Bank 7 3 4 4 3 4 4 4 6 Configuration Bank8 0 0 0 0 0 0 0 0 1 2 3 1 2 3 2 4 DDR Groups Bonded  per Bank SERDES Quads 1.These pins must remain floating on the board. 4-9 Pinout Information LatticeECP3 Family Data Sheet Lattice Semiconductor Logic Signal Connections Package pinout information can be found under “Data Sheets” on the LatticeECP3 product pages on the Lattice website at www.latticesemi.com/products/fpga/ecp3 and in the Lattice ispLEVER Design Planner software. To create pinout information from within Design Planner, select View -> Package View. Then select Select File -> Export and choose a type of output file. See Design Planner help for more information. Thermal Management SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Thermal management is recommended as part of any sound FPGA design methodology. To assess the thermal characteristics of a system, Lattice specifies a maximum allowable junction temperature in all device data sheets. Designers must complete a thermal analysis of their specific design to ensure that the device and package do not exceed the junction temperature limits. Refer to the Thermal Management document to find the device/package specific thermal values. For Further Information For further information regarding Thermal Management, refer to the following: • Thermal Management document • TN1181, Power Consumption and Management for LatticeECP3 Devices • Power Calculator tool included with the Lattice ispLEVER design tool, or as a standalone download from  www.latticesemi.com/software 4-10 LatticeECP3 Family Data Sheet Ordering Information March 2010 Preliminary Data Sheet DS1021 LatticeECP3 Part Number Description LFE3 – XXX XX – X XXXXXX X Device Family ECP3 (LatticeECP3 FPGA + SERDES) SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Grade C = Commercial I = Industrial Package FTN256 = 256-ball Lead-Free ftBGA FN484 = 484-ball Lead-Free fpBGA FN672 = 672-ball Lead-Free fpBGA FN1156 = 1156-ball Lead-Free fpBGA Logic Capacity 17 = 17K LUTs 35 = 33K LUTs 70 = 67K LUTs 95 = 92K LUTs 150 = 149K LUTs Supply Voltage E or EA = 1.2V Speed 6 = Slowest 7 8 = Fastest Ordering Information LatticeECP3 devices have top-side markings, for commercial and industrial grades, as shown below: Commercial Industrial ECP3 ECP3 LFE3-95E 7FN672C LFE3-95E 7FN672I Datecode Datecode © 2010 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com 5-1 DS1021 Order Info_01.2 Ordering Information LatticeECP3 Family Data Sheet Lattice Semiconductor LatticeECP3 Devices, Lead-Free Packaging The following devices may have associated errata. Specific devices with associated errata will be notated with a footnote. Commercial Part Number Voltage Grade Package Pins Temp. LUTs (K) LFE3-17EA-6FTN256C 1.2V -6 Lead-Free ftBGA 256 COM 17 LFE3-17EA-7FTN256C 1.2V -7 Lead-Free ftBGA 256 COM 17 1.2V -8 Lead-Free ftBGA 256 COM 17 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LFE3-17EA-8FTN256C LFE3-17EA-6FN484C 1.2V -6 Lead-Free fpBGA 484 COM 17 LFE3-17EA-7FN484C 1.2V -7 Lead-Free fpBGA 484 COM 17 LFE3-17EA-8FN484C 1.2V -8 Lead-Free fpBGA 484 COM 17 Voltage Grade Package Pins Temp. LUTs (K) LFE3-35EA-6FTN256C Part Number 1.2V -6 Lead-Free ftBGA 256 COM 33 LFE3-35EA-7FTN256C 1.2V -7 Lead-Free ftBGA 256 COM 33 LFE3-35EA-8FTN256C 1.2V -8 Lead-Free ftBGA 256 COM 33 LFE3-35EA-6FN484C 1.2V -6 Lead-Free fpBGA 484 COM 33 LFE3-35EA-7FN484C 1.2V -7 Lead-Free fpBGA 484 COM 33 LFE3-35EA-8FN484C 1.2V -8 Lead-Free fpBGA 484 COM 33 LFE3-35EA-6FN672C 1.2V -6 Lead-Free fpBGA 672 COM 33 LFE3-35EA-7FN672C 1.2V -7 Lead-Free fpBGA 672 COM 33 LFE3-35EA-8FN672C 1.2V -8 Lead-Free fpBGA 672 COM 33 Voltage Grade Package Pins Temp. LUTs (K) LFE3-70EA-6FN484C Part Number 1.2V -6 Lead-Free fpBGA 484 COM 67 LFE3-70EA-7FN484C 1.2V -7 Lead-Free fpBGA 484 COM 67 LFE3-70EA-8FN484C 1.2V -8 Lead-Free fpBGA 484 COM 67 LFE3-70EA-6FN672C 1.2V -6 Lead-Free fpBGA 672 COM 67 LFE3-70EA-7FN672C 1.2V -7 Lead-Free fpBGA 672 COM 67 LFE3-70EA-8FN672C 1.2V -8 Lead-Free fpBGA 672 COM 67 LFE3-70EA-6FN1156C 1.2V -6 Lead-Free fpBGA 1156 COM 67 LFE3-70EA-7FN1156C 1.2V -7 Lead-Free fpBGA 1156 COM 67 LFE3-70EA-8FN1156C 1.2V -8 Lead-Free fpBGA 1156 COM 67 5-2 Ordering Information LatticeECP3 Family Data Sheet Lattice Semiconductor Part Number Grade Package Pins Temp. LUTs (K) 1.2V -6 Lead-Free fpBGA 484 COM 67 LFE3-70E-7FN484C 1 1.2V -7 Lead-Free fpBGA 484 COM 67 LFE3-70E-8FN484C 1 1.2V -8 Lead-Free fpBGA 484 COM 67 LFE3-70E-6FN672C 1 1.2V -6 Lead-Free fpBGA 672 COM 67 LFE3-70E-7FN672C 1 1.2V -7 Lead-Free fpBGA 672 COM 67 LFE3-70E-8FN672C1 1.2V -8 Lead-Free fpBGA 672 COM 67 LFE3-70E-6FN1156C1 1.2V -6 Lead-Free fpBGA 1156 COM 67 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Voltage LFE3-70E-6FN484C1 1 1.2V -7 Lead-Free fpBGA 1156 COM 67 LFE3-70E-8FN1156C1 1.2V -8 Lead-Free fpBGA 1156 COM 67 LFE3-70E-7FN1156C 1.This device has associated errata. View www.latticesemi.com/documents/ds1021.zip for a description of the errata. Voltage Grade Package Pins Temp. LUTs (K) LFE3-95EA-6FN484C Part Number 1.2V -6 Lead-Free fpBGA 484 COM 92 LFE3-95EA-7FN484C 1.2V -7 Lead-Free fpBGA 484 COM 92 LFE3-95EA-8FN484C 1.2V -8 Lead-Free fpBGA 484 COM 92 LFE3-95EA-6FN672C 1.2V -6 Lead-Free fpBGA 672 COM 92 LFE3-95EA-7FN672C 1.2V -7 Lead-Free fpBGA 672 COM 92 LFE3-95EA-8FN672C 1.2V -8 Lead-Free fpBGA 672 COM 92 LFE3-95EA-6FN1156C 1.2V -6 Lead-Free fpBGA 1156 COM 92 LFE3-95EA-7FN1156C 1.2V -7 Lead-Free fpBGA 1156 COM 92 LFE3-95EA-8FN1156C 1.2V -8 Lead-Free fpBGA 1156 COM 92 Part Number Voltage Grade Package Pins Temp. LUTs (K) 1 1.2V -6 Lead-Free fpBGA 484 COM 92 LFE3-95E-7FN484C1 1.2V -7 Lead-Free fpBGA 484 COM 92 1 1.2V -8 Lead-Free fpBGA 484 COM 92 LFE3-95E-6FN672C1 1.2V -6 Lead-Free fpBGA 672 COM 92 1 1.2V -7 Lead-Free fpBGA 672 COM 92 LFE3-95E-8FN672C1 1.2V -8 Lead-Free fpBGA 672 COM 92 1 1.2V -6 Lead-Free fpBGA 1156 COM 92 LFE3-95E-7FN1156C1 1.2V -7 Lead-Free fpBGA 1156 COM 92 1 1.2V -8 Lead-Free fpBGA 1156 COM 92 LFE3-95E-6FN484C LFE3-95E-8FN484C LFE3-95E-7FN672C LFE3-95E-6FN1156C LFE3-95E-8FN1156C 1.This device has associated errata. View www.latticesemi.com/documents/ds1021.zip for a description of the errata. Part Number Voltage Grade Package Pins Temp. LUTs (K) LFE3-150EA-6FN672C 1.2V -6 Lead-Free fpBGA 672 COM 149 LFE3-150EA-7FN672C 1.2V -7 Lead-Free fpBGA 672 COM 149 LFE3-150EA-8FN672C 1.2V -8 Lead-Free fpBGA 672 COM 149 LFE3-150EA-6FN1156C 1.2V -6 Lead-Free fpBGA 1156 COM 149 LFE3-150EA-7FN1156C 1.2V -7 Lead-Free fpBGA 1156 COM 149 LFE3-150EA-8FN1156C 1.2V -8 Lead-Free fpBGA 1156 COM 149 5-3 Ordering Information LatticeECP3 Family Data Sheet Lattice Semiconductor Part Number Grade Package Pins Temp. LUTs (K) 1.2V -6 Lead-Free fpBGA 672 COM 149 LFE3-150EA-7FN672CTW* 1.2V -7 Lead-Free fpBGA 672 COM 149 LFE3-150EA-8FN672CTW* 1.2V -8 Lead-Free fpBGA 672 COM 149 LFE3-150EA-6FN1156CTW* 1.2V -6 Lead-Free fpBGA 1156 COM 149 LFE3-150EA-7FN1156CTW* 1.2V -7 Lead-Free fpBGA 1156 COM 149 LFE3-150EA-8FN1156CTW* 1.2V -8 Lead-Free fpBGA 1156 COM 149 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Voltage LFE3-150EA-6FN672CTW* *Note: Specifications for the LFE3-150EA-spFNpkgCTW and LFE3-150EA-spFNpkgITW devices, (where sp is the speed and pkg is the package), are the same as the LFE3-150EA-spFNpkgC and LFE3-150EA-spFNpkgI devices respectively, except as specified below. • The CTC (Clock Tolerance Circuit) inside the SERDES hard PCS in the TW device is not functional but it can be bypassed and implemented in soft IP. • The SERDES XRES pin on the TW device passes CDM testing at 250V. 5-4 Ordering Information LatticeECP3 Family Data Sheet Lattice Semiconductor Industrial The following devices may have associated errata. Specific devices with associated errata will be notated with a footnote. Part Number LFE3-17EA-6FTN256I Voltage Grade Package Pins Temp. LUTs (K) 1.2V -6 Lead-Free ftBGA 256 IND 17 1.2V -7 Lead-Free ftBGA 256 IND 17 1.2V -8 Lead-Free ftBGA 256 IND 17 LFE3-17EA-6FN484I 1.2V -6 Lead-Free fpBGA 484 IND 17 LFE3-17EA-7FN484I 1.2V -7 Lead-Free fpBGA 484 IND 17 LFE3-17EA-8FN484I 1.2V -8 Lead-Free fpBGA 484 IND 17 LUTs (K) SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N LFE3-17EA-7FTN256I LFE3-17EA-8FTN256I Voltage Grade Package Pins Temp. LFE3-35EA-6FTN256I Part Number 1.2V -6 Lead-Free ftBGA 256 IND 33 LFE3-35EA-7FTN256I 1.2V -7 Lead-Free ftBGA 256 IND 33 LFE3-35EA-8FTN256I 1.2V -8 Lead-Free ftBGA 256 IND 33 LFE3-35EA-6FN484I 1.2V -6 Lead-Free fpBGA 484 IND 33 LFE3-35EA-7FN484I 1.2V -7 Lead-Free fpBGA 484 IND 33 LFE3-35EA-8FN484I 1.2V -8 Lead-Free fpBGA 484 IND 33 LFE3-35EA-6FN672I 1.2V -6 Lead-Free fpBGA 672 IND 33 LFE3-35EA-7FN672I 1.2V -7 Lead-Free fpBGA 672 IND 33 LFE3-35EA-8FN672I 1.2V -7 Lead-Free fpBGA 672 IND 33 Voltage Grade Package Pins Temp. LUTs (K) LFE3-70EA-6FN484I 1.2V -6 Lead-Free fpBGA 484 IND 67 LFE3-70EA-7FN484I 1.2V -7 Lead-Free fpBGA 484 IND 67 LFE3-70EA-8FN484I 1.2V -8 Lead-Free fpBGA 484 IND 67 LFE3-70EA-6FN672I 1.2V -6 Lead-Free fpBGA 672 IND 67 LFE3-70EA-7FN672I 1.2V -7 Lead-Free fpBGA 672 IND 67 LFE3-70EA-8FN672I 1.2V -8 Lead-Free fpBGA 672 IND 67 Part Number LFE3-70EA-6FN1156I 1.2V -6 Lead-Free fpBGA 1156 IND 67 LFE3-70EA-7FN1156I 1.2V -7 Lead-Free fpBGA 1156 IND 67 LFE3-70EA-8FN1156I 1.2V -8 Lead-Free fpBGA 1156 IND 67 5-5 Ordering Information LatticeECP3 Family Data Sheet Lattice Semiconductor Part Number Grade Package Pins Temp. LUTs (K) 1.2V -6 Lead-Free fpBGA 484 IND 67 LFE3-70E-7FN484I1 1.2V -7 Lead-Free fpBGA 484 IND 67 1 LFE3-70E-8FN484I 1.2V -8 Lead-Free fpBGA 484 IND 67 LFE3-70E-6FN672I1 1.2V -6 Lead-Free fpBGA 672 IND 67 1 LFE3-70E-7FN672I 1.2V -7 Lead-Free fpBGA 672 IND 67 LFE3-70E-8FN672I1 1.2V -8 Lead-Free fpBGA 672 IND 67 LFE3-70E-6FN1156I1 1.2V -6 Lead-Free fpBGA 1156 IND 67 1 1.2V -7 Lead-Free fpBGA 1156 IND 67 LFE3-70E-8FN1156I1 1.2V -8 Lead-Free fpBGA 1156 IND 67 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Voltage LFE3-70E-6FN484I1 LFE3-70E-7FN1156I 1.This device has associated errata. View www.latticesemi.com/documents/ds1021.zip for a description of the errata. Voltage Grade Package Pins Temp. LUTs (K) LFE3-95EA-6FN484I Part Number 1.2V -6 Lead-Free fpBGA 484 IND 92 LFE3-95EA-7FN484I 1.2V -7 Lead-Free fpBGA 484 IND 92 LFE3-95EA-8FN484I 1.2V -8 Lead-Free fpBGA 484 IND 92 LFE3-95EA-6FN672I 1.2V -6 Lead-Free fpBGA 672 IND 92 LFE3-95EA-7FN672I 1.2V -7 Lead-Free fpBGA 672 IND 92 LFE3-95EA-8FN672I 1.2V -8 Lead-Free fpBGA 672 IND 92 LFE3-95EA-6FN1156I 1.2V -6 Lead-Free fpBGA 1156 IND 92 LFE3-95EA-7FN1156I 1.2V -7 Lead-Free fpBGA 1156 IND 92 LFE3-95EA-8FN1156I 1.2V -8 Lead-Free fpBGA 1156 IND 92 Part Number Voltage Grade Package Pins Temp. LUTs (K) 1 1.2V -6 Lead-Free fpBGA 484 IND 92 LFE3-95E-7FN484I1 1.2V -7 Lead-Free fpBGA 484 IND 92 1 LFE3-95E-8FN484I 1.2V -8 Lead-Free fpBGA 484 IND 92 LFE3-95E-6FN672I1 1.2V -6 Lead-Free fpBGA 672 IND 92 1 LFE3-95E-7FN672I 1.2V -7 Lead-Free fpBGA 672 IND 92 LFE3-95E-8FN672I1 1.2V -8 Lead-Free fpBGA 672 IND 92 1 1.2V -6 Lead-Free fpBGA 1156 IND 92 LFE3-95E-7FN1156I1 1.2V -7 Lead-Free fpBGA 1156 IND 92 1 1.2V -8 Lead-Free fpBGA 1156 IND 92 LFE3-95E-6FN484I LFE3-95E-6FN1156I LFE3-95E-8FN1156I 1.This device has associated errata. View www.latticesemi.com/documents/ds1021.zip for a description of the errata. 5-6 Ordering Information LatticeECP3 Family Data Sheet Lattice Semiconductor Part Number Grade Package Pins Temp. LUTs (K) 1.2V -6 Lead-Free fpBGA 672 IND 149 LFE3-150EA-7FN672I 1.2V -7 Lead-Free fpBGA 672 IND 149 LFE3-150EA-8FN672I 1.2V -8 Lead-Free fpBGA 672 IND 149 LFE3-150EA-6FN1156I 1.2V -6 Lead-Free fpBGA 1156 IND 149 LFE3-150EA-7FN1156I 1.2V -7 Lead-Free fpBGA 1156 IND 149 LFE3-150EA-8FN1156I 1.2V -8 Lead-Free fpBGA 1156 IND 149 SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Voltage LFE3-150EA-6FN672I Part Number Voltage Grade Package Pins Temp. LUTs (K) LFE3-150EA-6FN672ITW* 1.2V -6 Lead-Free fpBGA 672 IND 149 LFE3-150EA-7FN672ITW* 1.2V -7 Lead-Free fpBGA 672 IND 149 LFE3-150EA-8FN672ITW* 1.2V -8 Lead-Free fpBGA 672 IND 149 LFE3-150EA-6FN1156ITW* 1.2V -6 Lead-Free fpBGA 1156 IND 149 LFE3-150EA-7FN1156ITW* 1.2V -7 Lead-Free fpBGA 1156 IND 149 LFE3-150EA-8FN1156ITW* 1.2V -8 Lead-Free fpBGA 1156 IND 149 *Note: Specifications for the LFE3-150EA-spFNpkgCTW and LFE3-150EA-spFNpkgITW devices, (where sp is the speed and pkg is the package), are the same as the LFE3-150EA-spFNpkgC and LFE3-150EA-spFNpkgI devices respectively, except as specified below. • The CTC (Clock Tolerance Circuit) inside the SERDES hard PCS in the TW device is not functional but it can be bypassed and implemented in soft IP. • The SERDES XRES pin on the TW device passes CDM testing at 250V. 5-7 LatticeECP3 Family Data Sheet Supplemental Information February 2009 Preliminary Data Sheet DS1021 For Further Information A variety of technical notes for the LatticeECP3 family are available on the Lattice website at www.latticesemi.com. • TN1169, LatticeECP3 sysCONFIG Usage Guide SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N • TN1176, LatticeECP3 SERDES/PCS Usage Guide • TN1177, LatticeECP3 sysIO Usage Guide • TN1178, LatticeECP3 sysCLOCK PLL/DLL Design and Usage Guide • TN1179, LatticeECP3 Memory Usage Guide • TN1180, LatticeECP3 High-Speed I/O Interface • TN1181, Power Consumption and Management for LatticeECP3 Devices • TN1182, LatticeECP3 sysDSP Usage Guide • TN1184, LatticeECP3 Soft Error Detection (SED) Usage Guide • TN1189, LatticeECP3 Hardware Checklist For further information on interface standards refer to the following websites: • JEDEC Standards (LVTTL, LVCMOS, SSTL, HSTL): www.jedec.org • PCI: www.pcisig.com © 2009 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com 6-1 DS1021 Further Info_01.0 LatticeECP3 Family Data Sheet Revision History March 2010 Preliminary Data Sheet DS1021 Date Version Section February 2009 01.0 — May 2009 01.1 All Removed references to Parallel burst mode Flash. Features - Changed 250 Mbps to 230 Mbps in Embedded SERDES bulleted section and added a footnote to indicate 230 Mbps applies to 8b10b and 10b12b applications. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Introduction Change Summary Initial release. Updated data for ECP3-17 in LatticeECP3 Family Selection Guide table. Changed embedded memory from 552 to 700 Kbits in LatticeECP3 Family Selection Guide table. Architecture Updated description for CLKFB in General Purpose PLL Diagram. Corrected Primary Clock Sources text section. Corrected Secondary Clock/Control Sources text section. Corrected Secondary Clock Regions table. Corrected note below Detailed sysDSP Slice Diagram. Corrected Clock, Clock Enable, and Reset Resources text section. Corrected ECP3-17 EBR number in Embedded SRAM in the LatticeECP3 Family table. Added On-Chip Termination Options for Input Modes table. Updated Available SERDES Quads per LatticeECP3 Devices table. Updated Simplified Channel Block Diagram for SERDES/PCS Block diagram. Updated Device Configuration text section. Corrected software default value of MCLK to be 2.5 MHz. DC and Switching Characteristics Updated VCCOB Min/Max data in Recommended Operating Conditions table. Corrected footnote 2 in sysIO Recommended Operating Conditions table. Added added footnote 7 for tSKEW_PRIB to External Switching Characteristics table. Added 2-to-1 Gearing text section and table. Updated External Reference Clock Specification (refclkp/refclkn) table. LatticeECP3 sysCONFIG Port Timing Specifications - updated tDINIT information. Added sysCONFIG Port Timing waveform. Serial Input Data Specifications table, delete Typ data for VRX-DIFF-S. Added footnote 4 to sysCLOCK PLL Timing table for tPFD. Added SERDES/PCS Block Latency Breakdown table. External Reference Clock Specifications table, added footnote 4, add symbol name vREF-IN-DIFF. Added SERDES External Reference Clock Waveforms. Updated Serial Output Timing and Levels table. Pin-to-pin performance table, changed "typically 3% slower" to "typically slower". © 2010 Lattice Semiconductor Corp. All Lattice trademarks, registered trademarks, patents, and disclaimers are as listed at www.latticesemi.com/legal. All other brand or product names are trademarks or registered trademarks of their respective holders. The specifications and information herein are subject to change without notice. www.latticesemi.com 7-1 DS1021 Revision History Revision History LatticeECP3 Family Data Sheet Lattice Semiconductor Date Version Section May 2009 (cont.) 01.1 (cont.) DC and Switching Characteristics (cont.) Change Summary Updated timing information Updated SERDES minimum frequency. Added data to the following tables: External Switching Characteristics, Internal Switching Characteristics, Family Timing Adders, Maximum I/O Buffer Speed, DLL Timing, High Speed Data Transmitter, Channel Output Jitter, Typical Building Block Function Performance, Register-toRegister Performance, and Power Supply Requirements. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Updated Serial Input Data Specifications table. Updated Transmit table, Serial Rapid I/O Type 2 Electrical and Timing Characteristics section. Pinout Information Updated Signal Description tables. Updated Pin Information Summary tables and added footnote 1. July 2009 01.2 Multiple Architecture Changed references of “multi-boot” to “dual-boot” throughout the data sheet. Updated On-Chip Programmable Termination bullets. Updated On-Chip Termination Options for Input Modes table. Updated On-Chip Termination figure. DC and Switching Characterisitcs Changed min/max data for FREF_PPM and added footnote 4 in SERDES External Reference Clock Specification table. Updated SERDES minimum frequency. Pinout Information Corrected MCLK to be I/O and CCLK to be I in Signal Descriptions table Corrected truncated numbers for VCCIB and VCCOB in Recommended Operating Conditions table. August 2009 01.3 DC and Switching Characterisitcs September 2009 01.4 Architecture Corrected link in sysMEM Memory Block section. Updated information for On-Chip Programmable Termination and modified corresponding figure. Added footnote 2 to On-Chip Programmable Termination Options for Input Modes table. Corrected Per Quadrant Primary Clock Selection figure. DC and Switching Characterisitcs Modified -8 Timing data for 1024x18 True-Dual Port RAM (Read-BeforeWrite, EBR Output Registers) Added ESD Performance table. LatticeECP3 External Switching Characteristics table - updated data for tDIBGDDR, tW_PRI, tW_EDGE and tSKEW_EDGE_DQS. LatticeECP3 Internal Switching Characteristics table - updated data for tCOO_PIO and added footnote #4. sysCLOCK PLL Timing table - updated data for fOUT. External Reference Clock Specification (refclkp/refclkn) table - updated data for VREF-IN-SE and VREF-IN-DIFF. LatticeECP3 sysCONFIG Port Timing Specifications table - updated data for tMWC. Added TRLVDS DC Specification table and diagram. Updated Mini LVDS table. November 2009 01.5 Introduction Updated Embedded SERDES features. Architecture Updated Figure 2-4, General Purpose PLL Diagram. Added SONET/SDH to Embedded SERDES protocols. Updated SONET/SDH to SERDES and PCS protocols. 7-2 Revision History LatticeECP3 Family Data Sheet Lattice Semiconductor Date Version Section November 2009 (cont.) 01.5 (cont.) Architecture (cont.) DC and Switching Characterisitcs Change Summary Updated Table 2-13, SERDES Standard Support to include SONET/ SDH and updated footnote 2. Added footnote to ESD Performance table. Updated SERDES Power Supply Requirements table and footnotes. Updated Maximum I/O Buffer Speed table. Updated Pin-to-Pin Peformance table. Updated sysCLOCK PLL Timing table. SE C E U DA L R a T R A tt EN S ic e T HE EC IN E P FO T 3 F R O EA M R A TI O N Updated DLL timing table. Updated High-Speed Data Transmitter tables. Updated High-Speed Data Receiver table. Updated footnote for Receiver Total Jitter Tolerance Specification table. Updated Periodic Receiver Jitter Tolerance Specification table. Updated SERDES External Reference Clock Specification table. Updated PCI Express Electrical and Timing AC and DC Characteristics. Deleted Reference Clock table for PCI Express Electrical and Timing AC and DC Characteristics. Updated SMPTE AC/DC Characteristics Transmit table. Updated Mini LVDS table. Updated RSDS table. Added Supply Current (Standby) table for EA devices. Updated Internal Switching Characteristics table. Updated Register-to-Register Performance table. Added HDMI Electrical and Timing Characteristics data. Updated Family Timing Adders table. Updated sysCONFIG Port Timing Specifications table. Updated Recommended Operating Conditions table. Updated Hot Socket Specifications table. Updated Single-Ended DC table. Updated TRLVDS table and figure. Updated Serial Data Input Specifications table. Updated HDMI Transmit and Receive table. Ordering Information March 2010 01.6 Architecture Added LFE3-150EA “TW” devices and footnotes to the Commercial and Industrial tables. Added Read-Before-Write information. DC and Switching Characteristics Added footnote #6 to Maximum I/O Buffer Speed table. Pinout Information Added pin information for the LatticeECP3-70EA and LatticeECP395EA devices. Ordering Information Corrected minimum operating conditions for input and output differential voltages in the Point-to-Point LVDS table. Added ordering part numbers for the LatticeECP3-70EA and LatticeECP3-95EA devices. Removed dual mark information. 7-3
LFE3-95E-7FN484I
1. 物料型号:文档中没有明确列出具体的物料型号,但提到了LatticeECP3系列的FPGA。

2. 器件简介:LatticeECP3系列FPGA是高性能的可编程逻辑设备,适用于需要高速串行通信和复杂逻辑处理的应用。

3. 引脚分配:文档提供了详细的引脚分配信息,包括电源引脚、地引脚、配置引脚、JTAG测试访问端口引脚等。

4. 参数特性:文档列出了FPGA的多种参数特性,例如电源电压、工作温度范围、逻辑单元的数量(LUTs)等。

5. 功能详解:文档详细解释了FPGA的多种功能,包括时钟管理、I/O接口、内嵌存储器、DSP模块等。

6. 应用信息:虽然文档没有直接提供应用案例,但从FPGA的功能特性可以推断,它适用于通信、工业控制、视频处理等领域。

7. 封装信息:文档列出了FPGA的不同封装类型,如ftBGA和fpBGA,以及相应的引脚数量。

8. 性能参数:文档提供了FPGA的性能参数,包括时钟频率、I/O缓冲速度、串行数据速率等。

9. 电源管理:文档强调了热管理的重要性,并提供了有关FPGA功耗和电源管理的技术文档和工具的参考信息。

10. 订购信息:文档最后提供了FPGA的订购信息,包括部件编号、电压、等级、封装类型、引脚数量、温度范围和逻辑单元数量。
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