0
登录后你可以
  • 下载海量资料
  • 学习在线课程
  • 观看技术视频
  • 写文章/发帖/加入社区
会员中心
创作中心
发布
  • 发文章

  • 发资料

  • 发帖

  • 提问

  • 发视频

创作活动
LCMXO2-4000HC-C-EVN

LCMXO2-4000HC-C-EVN

  • 厂商:

    LATTICE(莱迪思半导体)

  • 封装:

    -

  • 描述:

    LCMXO2-1200HC-MG132CR1 MachXO2 PLD Evaluation Board

  • 详情介绍
  • 数据手册
  • 价格&库存
LCMXO2-4000HC-C-EVN 数据手册
MachXO2™ Family Data Sheet DS1035 Version 3.3, March 2017 MachXO2 Family Data Sheet Introduction May 2016 Data Sheet DS1035  Flexible On-Chip Clocking Features • Eight primary clocks • Up to two edge clocks for high-speed I/O  interfaces (top and bottom sides only) • Up to two analog PLLs per device with  fractional-n frequency synthesis – Wide input frequency range (7 MHz to  400 MHz)  Flexible Logic Architecture • Six devices with 256 to 6864 LUT4s and  18 to 334 I/Os  Ultra Low Power Devices • • • • Advanced 65 nm low power process As low as 22 µW standby power Programmable low swing differential I/Os Stand-by mode and other power saving options  Non-volatile, Infinitely Reconfigurable • • • • Instant-on – powers up in microseconds Single-chip, secure solution Programmable through JTAG, SPI or I2C Supports background programming of non-volatile memory • Optional dual boot with external SPI memory  Embedded and Distributed Memory • Up to 240 kbits sysMEM™ Embedded Block RAM • Up to 54 kbits Distributed RAM • Dedicated FIFO control logic  On-Chip User Flash Memory  TransFR™ Reconfiguration • Up to 256 kbits of User Flash Memory • 100,000 write cycles • Accessible through WISHBONE, SPI, I2C and JTAG interfaces • Can be used as soft processor PROM or as Flash memory • In-field logic update while system operates  Enhanced System Level Support • On-chip hardened functions: SPI, I2C, timer/ counter • On-chip oscillator with 5.5% accuracy • Unique TraceID for system tracking • One Time Programmable (OTP) mode • Single power supply with extended operating range • IEEE Standard 1149.1 boundary scan • IEEE 1532 compliant in-system programming  Pre-Engineered Source Synchronous I/O • • • • • DDR registers in I/O cells Dedicated gearing logic 7:1 Gearing for Display I/Os Generic DDR, DDRX2, DDRX4 Dedicated DDR/DDR2/LPDDR memory with DQS support  Broad Range of Package Options  High Performance, Flexible I/O Buffer • Programmable sysIO™ buffer supports wide range of interfaces: – LVCMOS 3.3/2.5/1.8/1.5/1.2 – LVTTL – PCI – LVDS, Bus-LVDS, MLVDS, RSDS, LVPECL – SSTL 25/18 – HSTL 18 – Schmitt trigger inputs, up to 0.5 V hysteresis • I/Os support hot socketing • On-chip differential termination • Programmable pull-up or pull-down mode • TQFP, WLCSP, ucBGA, csBGA, caBGA, ftBGA, fpBGA, QFN package options • Small footprint package options – As small as 2.5 mm x 2.5 mm • Density migration supported • Advanced halogen-free packaging © 2016 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 DS1035 Introduction_02.2 Introduction MachXO2 Family Data Sheet Table 1-1. MachXO2™ Family Selection Guide LUTs XO2-256 XO2-640 XO2-640U1 XO2-1200 XO2-1200U1 XO2-2000 XO2-2000U1 XO2-4000 XO2-7000 256 640 640 1280 1280 2112 2112 4320 Distributed RAM (kbits) 2 5 5 10 10 16 16 34 54 EBR SRAM (kbits) 0 18 64 64 74 74 92 92 240 Number of EBR SRAM Blocks (9 kbits/block) 0 2 7 7 8 8 10 10 26 256 UFM (kbits) Device Options: HC2 0 24 64 64 80 80 96 96 Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes HE3 ZE4 Yes Yes 0 0 1 1 1 1 2 2 2 I2C 2 2 2 2 2 2 2 2 2 SPI 1 1 1 1 1 1 1 1 1 Timer/Counter 1 1 1 1 1 1 1 1 1 Number of PLLs Hardened  Functions: 6864 Yes Packages Yes IO 25-ball WLCSP5 (2.5 mm x 2.5 mm, 0.4 mm) 18 32 QFN6 (5 mm x 5 mm, 0.5 mm) 21 48 QFN8, 9 (7 mm x 7 mm, 0.5 mm) 40 21 40 5 49-ball WLCSP (3.2 mm x 3.2 mm, 0.4 mm) 64-ball ucBGA (4 mm x 4 mm, 0.4 mm) 38 44 84 QFN7 (7 mm x 7 mm, 0.5 mm) 68 100-pin TQFP (14 mm x 14 mm) 55 78 79 79 132-ball csBGA (8 mm x 8 mm, 0.5 mm) 55 79 104 104 104 107 111 114 144-pin TQFP (20 mm x 20 mm) 107 184-ball csBGA7 (8 mm x 8 mm, 0.5 mm) 150 256-ball caBGA (14 mm x 14 mm, 0.8 mm) 256-ball ftBGA (17 mm x 17 mm, 1.0 mm) 206 206 206 206 206 206 206 274 278 278 334 332-ball caBGA (17 mm x 17 mm, 0.8 mm) 484-ball ftBGA (23 mm x 23 mm, 1.0 mm) 1. 2. 3. 4. 5. 6. 7. 8. 9. 114 278 Ultra high I/O device. High performance with regulator – VCC = 2.5 V, 3.3 V High performance without regulator – VCC = 1.2 V Low power without regulator – VCC = 1.2 V WLCSP package only available for ZE devices. 32 QFN package only available for HC and ZE devices. 184 csBGA package only available for HE devices. 48-pin QFN information is ‘Advanced’. 48 QFN package only available for HC devices. 1-2 Introduction MachXO2 Family Data Sheet Introduction The MachXO2 family of ultra low power, instant-on, non-volatile PLDs has six devices with densities ranging from 256 to 6864 Look-Up Tables (LUTs). In addition to LUT-based, low-cost programmable logic these devices feature Embedded Block RAM (EBR), Distributed RAM, User Flash Memory (UFM), Phase Locked Loops (PLLs), preengineered source synchronous I/O support, advanced configuration support including dual-boot capability and hardened versions of commonly used functions such as SPI controller, I2C controller and timer/counter. These features allow these devices to be used in low cost, high volume consumer and system applications. The MachXO2 devices are designed on a 65 nm non-volatile low power process. The device architecture has several features such as programmable low swing differential I/Os and the ability to turn off I/O banks, on-chip PLLs and oscillators dynamically. These features help manage static and dynamic power consumption resulting in low static power for all members of the family. The MachXO2 devices are available in two versions – ultra low power (ZE) and high performance (HC and HE) devices. The ultra low power devices are offered in three speed grades –1, –2 and –3, with –3 being the fastest. Similarly, the high-performance devices are offered in three speed grades: –4, –5 and –6, with –6 being the fastest. HC devices have an internal linear voltage regulator which supports external VCC supply voltages of 3.3 V or 2.5 V. ZE and HE devices only accept 1.2 V as the external VCC supply voltage. With the exception of power supply voltage all three types of devices (ZE, HC and HE) are functionally compatible and pin compatible with each other. The MachXO2 PLDs are available in a broad range of advanced halogen-free packages ranging from the space saving 2.5 mm x 2.5 mm WLCSP to the 23 mm x 23 mm fpBGA. MachXO2 devices support density migration within the same package. Table 1-1 shows the LUT densities, package and I/O options, along with other key parameters. The pre-engineered source synchronous logic implemented in the MachXO2 device family supports a broad range of interface standards, including LPDDR, DDR, DDR2 and 7:1 gearing for display I/Os. The MachXO2 devices offer enhanced I/O features such as drive strength control, slew rate control, PCI compatibility, bus-keeper latches, pull-up resistors, pull-down resistors, open drain outputs and hot socketing. Pull-up, pulldown and bus-keeper features are controllable on a “per-pin” basis. A user-programmable internal oscillator is included in MachXO2 devices. The clock output from this oscillator may be divided by the timer/counter for use as clock input in functions such as LED control, key-board scanner and similar state machines. The MachXO2 devices also provide flexible, reliable and secure configuration from on-chip Flash memory. These devices can also configure themselves from external SPI Flash or be configured by an external master through the JTAG test access port or through the I2C port. Additionally, MachXO2 devices support dual-boot capability (using external Flash memory) and remote field upgrade (TransFR) capability. Lattice provides a variety of design tools that allow complex designs to be efficiently implemented using the MachXO2 family of devices. Popular logic synthesis tools provide synthesis library support for MachXO2. Lattice design tools use the synthesis tool output along with the user-specified preferences and constraints to place and route the design in the MachXO2 device. These tools extract the timing from the routing and back-annotate it into the design for timing verification. Lattice provides many pre-engineered IP (Intellectual Property) LatticeCORE™ modules, including a number of reference designs licensed free of charge, optimized for the MachXO2 PLD family. By using these configurable soft core IP cores as standardized blocks, users are free to concentrate on the unique aspects of their design, increasing their productivity. 1-3 MachXO2 Family Data Sheet Architecture March 2016 Data Sheet DS1035 Architecture Overview The MachXO2 family architecture contains an array of logic blocks surrounded by Programmable I/O (PIO). The larger logic density devices in this family have sysCLOCK™ PLLs and blocks of sysMEM Embedded Block RAM (EBRs). Figure 2-1 and Figure 2-2 show the block diagrams of the various family members. Figure 2-1. Top View of the MachXO2-1200 Device Embedded Function Block (EFB) User Flash Memory (UFM) sysCLOCK PLL sysMEM Embedded Block RAM (EBR) On-chip Configuration Flash Memory Programmable Function Units with Distributed RAM (PFUs) PIOs Arranged into sysIO Banks Note: MachXO2-256, and MachXO2-640/U are similar to MachXO2-1200. MachXO2-256 has a lower LUT count and no PLL or EBR blocks. MachXO2-640 has no PLL, a lower LUT count and two EBR blocks. MachXO2-640U has a lower LUT count, one PLL and seven EBR blocks. Figure 2-2. Top View of the MachXO2-4000 Device Embedded Function Block(EFB) User Flash Memory (UFM) sysCLOCK PLL On-chip Configuration Flash Memory sysMEM Embedded Block RAM (EBR) PIOs Arranged into sysIO Banks Programmable Function Units with Distributed RAM (PFUs) Note: MachXO2-1200U, MachXO2-2000/U and MachXO2-7000 are similar to MachXO2-4000. MachXO2-1200U and MachXO2-2000 have a lower LUT count, one PLL, and eight EBR blocks. MachXO2-2000U has a lower LUT count, two PLLs, and 10 EBR blocks. MachXO2-7000 has a higher LUT count, two PLLs, and 26 EBR blocks. © 2016 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 DS1035 Architecture_02.3 Architecture MachXO2 Family Data Sheet The logic blocks, Programmable Functional Unit (PFU) and sysMEM EBR blocks, are arranged in a two-dimensional grid with rows and columns. Each row has either the logic blocks or the EBR blocks. The PIO cells are located at the periphery of the device, arranged in banks. The PFU contains the building blocks for logic, arithmetic, RAM, ROM, and register functions. The PIOs utilize a flexible I/O buffer referred to as a sysIO buffer that supports operation with a variety of interface standards. The blocks are connected with many vertical and horizontal routing channel resources. The place and route software tool automatically allocates these routing resources. In the MachXO2 family, the number of sysIO banks varies by device. There are different types of I/O buffers on the different banks. Refer to the details in later sections of this document. The sysMEM EBRs are large, dedicated fast memory blocks; these blocks are found in MachXO2-640/U and larger devices. These blocks can be configured as RAM, ROM or FIFO. FIFO support includes dedicated FIFO pointer and flag “hard” control logic to minimize LUT usage. The MachXO2 registers in PFU and sysI/O can be configured to be SET or RESET. After power up and device is configured, the device enters into user mode with these registers SET/RESET according to the configuration setting, allowing device entering to a known state for predictable system function. The MachXO2 architecture also provides up to two sysCLOCK Phase Locked Loop (PLL) blocks on MachXO2640U, MachXO2-1200/U and larger devices. These blocks are located at the ends of the on-chip Flash block. The PLLs have multiply, divide, and phase shifting capabilities that are used to manage the frequency and phase relationships of the clocks. MachXO2 devices provide commonly used hardened functions such as SPI controller, I2C controller and timer/ counter. MachXO2-640/U and higher density devices also provide User Flash Memory (UFM). These hardened functions and the UFM interface to the core logic and routing through a WISHBONE interface. The UFM can also be accessed through the SPI, I2C and JTAG ports. Every device in the family has a JTAG port that supports programming and configuration of the device as well as access to the user logic. The MachXO2 devices are available for operation from 3.3 V, 2.5 V and 1.2 V power supplies, providing easy integration into the overall system. PFU Blocks The core of the MachXO2 device consists of PFU blocks, which can be programmed to perform logic, arithmetic, distributed RAM and distributed ROM functions. Each PFU block consists of four interconnected slices numbered 0 to 3 as shown in Figure 2-3. Each slice contains two LUTs and two registers. There are 53 inputs and 25 outputs associated with each PFU block. 2-2 Architecture MachXO2 Family Data Sheet Figure 2-3. PFU Block Diagram From Routing FCIN LUT4 & CARRY LUT4 & CARRY LUT4 & CARRY Slice 0 D FF/ Latch D FF/ Latch LUT4 & CARRY LUT4 & CARRY Slice 1 D FF/ Latch LUT4 & CARRY LUT4 & CARRY D FF/ Latch FCO Slice 3 Slice 2 D FF/ Latch LUT4 & CARRY D FF/ Latch D FF/ Latch D FF/ Latch To Routing Slices Slices 0-3 contain two LUT4s feeding two registers. Slices 0-2 can be configured as distributed memory. Table 2-1 shows the capability of the slices in 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. The control logic performs set/reset functions (programmable as synchronous/ asynchronous), clock select, chipselect and wider RAM/ROM functions. Table 2-1. Resources and Modes Available per Slice PFU Block Slice Resources Modes Slice 0 2 LUT4s and 2 Registers Logic, Ripple, RAM, ROM Slice 1 2 LUT4s and 2 Registers Logic, Ripple, RAM, ROM Slice 2 2 LUT4s and 2 Registers Logic, Ripple, RAM, ROM Slice 3 2 LUT4s and 2 Registers Logic, Ripple, ROM Figure 2-4 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. All slices have 15 inputs from routing and one from the carry-chain (from the adjacent slice or PFU). There are seven outputs: six for routing and one to carry-chain (to the adjacent PFU). Table 2-2 lists the signals associated with Slices 0-3. 2-3 Architecture MachXO2 Family Data Sheet Figure 2-4. Slice Diagram FCO To Different Slice/PFU Slice FXB FXA OFX1 A1 B1 C1 D1 CO F1 F/SUM D LUT4 & Carry Q1 Flip-flop/ Latch To Routing CI M1 M0 LUT5 Mux From Routing OFX0 A0 B0 C0 D0 CO LUT4 & Carry F0 F/SUM CI D Q0 Flip-flop/ Latch CE CLK LSR Memory & Control Signals 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 Description Input Data signal A0, B0, C0, D0 Inputs to LUT4 Input Data signal A1, B1, C1, D1 Inputs to LUT4 Input Multi-purpose M0/M1 Input Control signal CE Multi-purpose input Clock enable Input Control signal LSR Local set/reset Input Control signal CLK System clock Input Inter-PFU signal FCIN Fast carry in1 Output Data signals F0, F1 LUT4 output register bypass signals Output Data signals Q0, Q1 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 Fast carry out1 Register outputs 1. See Figure 2-3 for connection details. 2. Requires two PFUs. 2-4 Architecture MachXO2 Family Data Sheet 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. 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 by 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. MachXO2 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 MachXO2 devices, please see TN1201, Memory Usage Guide for MachXO2 Devices. Table 2-3. Number of Slices Required For Implementing Distributed RAM SPR 16x4 PDPR 16x4 3 3 Number of slices Note: SPR = Single Port RAM, PDPR = Pseudo Dual Port RAM 2-5 Architecture MachXO2 Family Data Sheet ROM Mode ROM mode uses the LUT logic; hence, slices 0-3 can be used in ROM mode. Preloading is accomplished through the programming interface during PFU configuration. For more information on the RAM and ROM modes, please refer to TN1201, Memory Usage Guide for MachXO2 Devices. Routing There are many resources provided in the MachXO2 devices to route signals individually or as buses with related control signals. The routing resources consist of switching circuitry, buffers and metal interconnect (routing) segments. The inter-PFU connections are made with three different types of routing resources: x1 (spans two PFUs), x2 (spans three PFUs) and x6 (spans seven PFUs). The x1, x2, and x6 connections provide fast and efficient connections in the horizontal and vertical directions. The design tools take the output of the synthesis tool and places and routes the design. Generally, the place and route tool is completely automatic, although an interactive routing editor is available to optimize the design. Clock/Control Distribution Network Each MachXO2 device has eight clock inputs (PCLK [T, C] [Banknum]_[2..0]) – three pins on the left side, two pins each on the bottom and top sides and one pin on the right side. These clock inputs drive the clock nets. These eight inputs can be differential or single-ended and may be used as general purpose I/O if they are not used to drive the clock nets. When using a single ended clock input, only the PCLKT input can drive the clock tree directly. The MachXO2 architecture has three types of clocking resources: edge clocks, primary clocks and secondary high fanout nets. MachXO2-640U, MachXO2-1200/U and higher density devices have two edge clocks each on the top and bottom edges. Lower density devices have no edge clocks. Edge clocks are used to clock I/O registers and have low injection time and skew. Edge clock inputs are from PLL outputs, primary clock pads, edge clock bridge outputs and CIB sources. The eight primary clock lines in the primary clock network drive throughout the entire device and can provide clocks for all resources within the device including PFUs, EBRs and PICs. In addition to the primary clock signals, MachXO2 devices also have eight secondary high fanout signals which can be used for global control signals, such as clock enables, synchronous or asynchronous clears, presets, output enables, etc. Internal logic can drive the global clock network for internally-generated global clocks and control signals. The maximum frequency for the primary clock network is shown in the MachXO2 External Switching Characteristics table. The primary clock signals for the MachXO2-256 and MachXO2-640 are generated from eight 17:1 muxes The available clock sources include eight I/O sources and 9 routing inputs. Primary clock signals for the MachXO2640U, MachXO2-1200/U and larger devices are generated from eight 27:1 muxes The available clock sources include eight I/O sources, 11 routing inputs, eight clock divider inputs and up to eight sysCLOCK PLL outputs. 2-6 Architecture MachXO2 Family Data Sheet Figure 2-5. Primary Clocks for MachXO2 Devices Up to 8 8 11 8 27:1 Dynamic Clock Enable Primary Clock 0 27:1 Dynamic Clock Enable Primary Clock 1 27:1 Dynamic Clock Enable Primary Clock 2 27:1 Dynamic Clock Enable Primary Clock 3 Dynamic Clock Enable Primary Clock 4 Dynamic Clock Enable Primary Clock 5 27:1 27:1 27:1 27:1 Dynamic Clock Enable Primary Clock 6 Dynamic Clock Enable Primary Clock 7 Clock Switch 27:1 Edge Clock Divider Routing Clock Pads PLL Outputs 27:1 Clock Switch Primary clocks for MachXO2-640U, MachXO2-1200/U and larger devices. Note: MachXO2-640 and smaller devices do not have inputs from the Edge Clock Divider or PLL and fewer routing inputs. These devices have 17:1 muxes instead of 27:1 muxes. Eight secondary high fanout nets are generated from eight 8:1 muxes as shown in Figure 2-6. One of the eight inputs to the secondary high fanout net input mux comes from dual function clock pins and the remaining seven come from internal routing. The maximum frequency for the secondary clock network is shown in MachXO2 External Switching Characteristics table. 2-7 Architecture MachXO2 Family Data Sheet Figure 2-6. Secondary High Fanout Nets for MachXO2 Devices 1 Clock Pads 7 8:1 Secondary High Fanout Net 0 8:1 Secondary High Fanout Net 1 8:1 Secondary High Fanout Net 2 8:1 Secondary High Fanout Net 3 8:1 Secondary High Fanout Net 4 8:1 Secondary High Fanout Net 5 8:1 Secondary High Fanout Net 6 8:1 Secondary High Fanout Net 7 Routing sysCLOCK Phase Locked Loops (PLLs) The sysCLOCK PLLs provide the ability to synthesize clock frequencies. The MachXO2-640U, MachXO2-1200/U and larger devices have one or more sysCLOCK PLL. CLKI is the reference frequency input to the PLL and its source can come from an external I/O pin or from internal routing. CLKFB is the feedback signal to the PLL which can come from internal routing or an external I/O pin. The feedback divider is used to multiply the reference frequency and thus synthesize a higher frequency clock output. The MachXO2 sysCLOCK PLLs support high resolution (16-bit) fractional-N synthesis. Fractional-N frequency synthesis allows the user to generate an output clock which is a non-integer multiple of the input frequency. For more information about using the PLL with Fractional-N synthesis, please see TN1199, MachXO2 sysCLOCK PLL Design and Usage Guide. Each output has its own output divider, thus allowing the PLL to generate different frequencies for each output. The output dividers can have a value from 1 to 128. The output dividers may also be cascaded together to generate low frequency clocks. The CLKOP, CLKOS, CLKOS2, and CLKOS3 outputs can all be used to drive the MachXO2 clock distribution network directly or general purpose routing resources can be used. The LOCK signal is asserted when the PLL determines it has achieved lock and de-asserted if a loss of lock is detected. A block diagram of the PLL is shown in Figure 2-7. The setup and hold times of the device can be improved by programming a phase shift into the CLKOS, CLKOS2, and CLKOS3 output clocks which will advance or delay the output clock with reference to the CLKOP output clock. 2-8 Architecture MachXO2 Family Data Sheet This phase shift can be either programmed during configuration or can be adjusted dynamically. In dynamic mode, the PLL may lose lock after a phase adjustment on the output used as the feedback source and not relock until the tLOCK parameter has been satisfied. The MachXO2 also has a feature that allows the user to select between two different reference clock sources dynamically. This feature is implemented using the PLLREFCS primitive. The timing parameters for the PLL are shown in the sysCLOCK PLL Timing table. The MachXO2 PLL contains a WISHBONE port feature that allows the PLL settings, including divider values, to be dynamically changed from the user logic. When using this feature the EFB block must also be instantiated in the design to allow access to the WISHBONE ports. Similar to the dynamic phase adjustment, when PLL settings are updated through the WISHBONE port the PLL may lose lock and not relock until the tLOCK parameter has been satisfied. The timing parameters for the PLL are shown in the sysCLOCK PLL Timing table. For more details on the PLL and the WISHBONE interface, see TN1199, MachXO2 sysCLOCK PLL Design and Usage Guide. Figure 2-7. PLL Diagram DPHSRC PHASESEL[1:0] Dynamic Phase Adjust PHASEDIR PHASESTEP A0 STDBY CLKOP CLKOP Divider (1 - 128) Phase Adjust/ Edge Trim A2 Mux ClkEn Synch REFCLK CLKI CLKFB REFCLK Divider M (1 - 40) Phase detector, VCO, and loop filter. B1 Mux CLKOS Divider (1 - 128) Phase Adjust/ Edge Trim B2 Mux ClkEn Synch C0 C1 Mux CLKOS2 Divider (1 - 128) Phase Adjust C2 Mux ClkEn Synch D2 Mux ClkEn Synch FBKSEL Fractional-N Synthesizer FBKCLK Divider N (1 - 40) CLKOS B0 D0 Internal Feedback D1 Mux CLKOS2 CLKOS3 Divider (1 - 128) CLKOS3 Phase Adjust CLKOP, CLKOS, CLKOS2, CLKOS3 LOCK Lock Detect 4 RST, RESETM, RESETC, RESETD ENCLKOP, ENCLKOS, ENCLKOS2, ENCLKOS3 PLLDATO[7:0] , PLLACK PLLCLK, PLLRST, PLLSTB, PLLWE, PLLDATI[7:0], PLLADDR[4:0] Table 2-4 provides signal descriptions of the PLL block. Table 2-4. PLL Signal Descriptions Port Name I/O Description CLKI I Input clock to PLL CLKFB I Feedback clock PHASESEL[1:0] I Select which output is affected by Dynamic Phase adjustment ports PHASEDIR I Dynamic Phase adjustment direction PHASESTEP I Dynamic Phase step – toggle shifts VCO phase adjust by one step. 2-9 Architecture MachXO2 Family Data Sheet Table 2-4. PLL Signal Descriptions (Continued) Port Name CLKOP I/O O Description Primary PLL output clock (with phase shift adjustment) CLKOS O Secondary PLL output clock (with phase shift adjust) CLKOS2 O Secondary PLL output clock2 (with phase shift adjust) CLKOS3 O Secondary PLL output clock3 (with phase shift adjust) LOCK O PLL LOCK, asynchronous signal. Active high indicates PLL is locked to input and feedback signals. DPHSRC O Dynamic Phase source – ports or WISHBONE is active STDBY I Standby signal to power down the PLL RST I PLL reset without resetting the M-divider. Active high reset. RESETM I PLL reset - includes resetting the M-divider. Active high reset. RESETC I Reset for CLKOS2 output divider only. Active high reset. RESETD I Reset for CLKOS3 output divider only. Active high reset. ENCLKOP I Enable PLL output CLKOP ENCLKOS I Enable PLL output CLKOS when port is active ENCLKOS2 I Enable PLL output CLKOS2 when port is active ENCLKOS3 I Enable PLL output CLKOS3 when port is active PLLCLK I PLL data bus clock input signal PLLRST I PLL data bus reset. This resets only the data bus not any register values. PLLSTB I PLL data bus strobe signal PLLWE I PLL data bus write enable signal PLLADDR [4:0] I PLL data bus address PLLDATI [7:0] I PLL data bus data input PLLDATO [7:0] O PLL data bus data output PLLACK O PLL data bus acknowledge signal sysMEM Embedded Block RAM Memory The MachXO2-640/U and larger devices contain sysMEM Embedded Block RAMs (EBRs). The EBR consists of a 9-kbit RAM, with dedicated input and output registers. This memory can be used for a wide variety of purposes including data buffering, PROM for the soft processor and FIFO. sysMEM Memory Block The sysMEM block can implement single port, dual port, pseudo dual port, or FIFO memories. Each block can be used in a variety of depths and widths as shown in Table 2-5. 2-10 Architecture MachXO2 Family Data Sheet Table 2-5. sysMEM Block Configurations Memory Mode Configurations Single Port 8,192 x 1 4,096 x 2 2,048 x 4 1,024 x 9 True Dual Port 8,192 x 1 4,096 x 2 2,048 x 4 1,024 x 9 Pseudo Dual Port 8,192 x 1 4,096 x 2 2,048 x 4 1,024 x 9 512 x 18 FIFO 8,192 x 1 4,096 x 2 2,048 x 4 1,024 x 9 512 x 18 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. EBR initialization data can be loaded from the UFM. To maximize the number of UFM bits, initialize the EBRs used in your design to an all-zero pattern. Initializing to an all-zero pattern does not use up UFM bits. MachXO2 devices have been designed such that multiple EBRs share the same initialization memory space if they are initialized to the same pattern. 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. Single, Dual, Pseudo-Dual Port and FIFO Modes Figure 2-8 shows the five basic memory configurations and their input/output names. In all the sysMEM RAM modes, the input data and addresses for the ports are registered at the input of the memory array. The output data of the memory is optionally registered at the memory array output. 2-11 Architecture MachXO2 Family Data Sheet Figure 2-8. sysMEM Memory Primitives DI[8:0] DIA[8:0] AD[12:0] DI[8:0] ADB[12:0] CLKB CEB ADA[12:0] CLKA CEA CLK CE OCE EBR DO[8:0] EBR RSTA WEA CSA[2:0] OCEA DOA[8:0] RST WE CS[2:0] Single-Port RAM RSTB WEB CSB[2:0] OCEB DOB[8:0] ADW[8:0] DI[17:0] BE[1:0] CLKW CEW RST CLKW WE EBR RST FULLI CSW[1:0] CLKR EBR CER DO[17:0] OCER CSR[2:0] CSW[2:0] True Dual Port RAM DI[17:0] ADR[12:0] Pseudo Dual Port RAM AD[12:0] AFF FF AEF EF DO[17:0] ORE CLKR RE EMPTYI CSR[1:0] RPRST CLK CE OCE EBR DO[17:0] RST CS[2:0] FIFO RAM ROM Table 2-6. EBR Signal Descriptions Port Name Description Active State CLK Clock Rising Clock Edge CE Clock Enable Active High OCE1 Output Clock Enable Active High RST Reset Active High BE1 Byte Enable Active High WE Write Enable Active High AD Address Bus — DI Data In — DO Data Out — CS Chip Select AFF FIFO RAM Almost Full Flag Active High — FF FIFO RAM Full Flag — AEF FIFO RAM Almost Empty Flag — EF FIFO RAM Empty Flag — RPRST FIFO RAM Read Pointer Reset — 1. Optional signals. 2. For dual port EBR primitives a trailing ‘A’ or ‘B’ in the signal name specifies the EBR port A or port B respectively. 3. For FIFO RAM mode primitive, a trailing ‘R’ or ‘W’ in the signal name specifies the FIFO read port or write port respectively. 4. For FIFO RAM mode primitive FULLI has the same function as CSW(2) and EMPTYI has the same function as CSR(2). 5. In FIFO mode, CLKW is the write port clock, CSW is the write port chip select, CLKR is the read port clock, CSR is the read port chip select, ORE is the output read enable. 2-12 Architecture MachXO2 Family Data Sheet The EBR memory supports three forms of write behavior for single or dual port operation: 1. Normal – Data on the output appears only during the 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. 2. Write Through – A copy of the input data appears at the output of the same port. This mode is supported for all data widths. 3. Read-Before-Write – When new data is being written, the old contents of the address appears at the output. FIFO Configuration The FIFO has a write port with data-in, CEW, WE and CLKW signals. There is a separate read port with data-out, RCE, RE and CLKR signals. The FIFO internally generates Almost Full, Full, Almost Empty and Empty Flags. The Full and Almost Full flags are registered with CLKW. The Empty and Almost Empty flags are registered with CLKR. Table 2-7 shows the range of programming values for these flags. Table 2-7. Programmable FIFO Flag Ranges Flag Name Programming Range 1 to max (up to 2N-1) Full (FF) Almost Full (AF) 1 to Full-1 Almost Empty (AE) 1 to Full-1 Empty (EF) 0 N = Address bit width. The FIFO state machine supports two types of reset signals: RST and RPRST. The RST signal is a global reset that clears the contents of the FIFO by resetting the read/write pointer and puts the FIFO flags in their initial reset state. The RPRST signal is used to reset the read pointer. The purpose of this reset is to retransmit the data that is in the FIFO. In these applications it is important to keep careful track of when a packet is written into or read from the FIFO. Memory Core Reset The memory core contains data output latches for ports A and B. These are simple latches that can be reset synchronously or asynchronously. RSTA and RSTB are local signals, which reset the output latches associated with port A and port B respectively. The Global Reset (GSRN) signal resets both ports. The output data latches and associated resets for both ports are as shown in Figure 2-9. 2-13 Architecture MachXO2 Family Data Sheet Figure 2-9. Memory Core Reset Memory Core D SET Q Port A[18:0] Output Data Latches D SET Q Port B[18:0] RSTA RSTB GSRN Programmable Disable For further information on the sysMEM EBR block, please refer to TN1201, Memory Usage Guide for MachXO2 Devices. EBR Asynchronous Reset EBR asynchronous reset or GSR (if used) can only be applied if all clock enables are low for a clock cycle before the reset is applied and released a clock cycle after the reset is released, as shown in Figure 2-10. The GSR input to the EBR is always asynchronous. Figure 2-10. EBR Asynchronous Reset (Including GSR) Timing Diagram Reset Clock Clock Enable If all clock enables remain enabled, the EBR asynchronous reset or GSR may only be applied and released after the EBR read and write clock inputs are in a steady state condition for a minimum of 1/fMAX (EBR clock). The reset release must adhere to the EBR synchronous reset setup time before the next active read or write clock edge. If an EBR is pre-loaded during configuration, the GSR input must be disabled or the release of the GSR during device wake up must occur before the release of the device I/Os becoming active. These instructions apply to all EBR RAM, ROM and FIFO implementations. For the EBR FIFO mode, the GSR signal is always enabled and the WE and RE signals act like the clock enable signals in Figure 2-10. The reset timing rules apply to the RPReset input versus the RE input and the RST input versus the WE and RE inputs. Both RST and RPReset are always asynchronous EBR inputs. For more details refer to TN1201, Memory Usage Guide for MachXO2 Devices. Note that there are no reset restrictions if the EBR synchronous reset is used and the EBR GSR input is disabled. 2-14 Architecture MachXO2 Family Data Sheet Programmable I/O Cells (PIC) The programmable logic associated with an I/O is called a PIO. The individual PIO are connected to their respective sysIO buffers and pads. On the MachXO2 devices, the PIO cells are assembled into groups of four PIO cells called a Programmable I/O Cell or PIC. The PICs are placed on all four sides of the device. On all the MachXO2 devices, two adjacent PIOs can be combined to provide a complementary output driver pair. The MachXO2-640U, MachXO2-1200/U and higher density devices contain enhanced I/O capability. All PIO pairs on these larger devices can implement differential receivers. Half of the PIO pairs on the top edge of these devices can be configured as true LVDS transmit pairs. The PIO pairs on the bottom edge of these higher density devices have on-chip differential termination and also provide PCI support. 2-15 Architecture MachXO2 Family Data Sheet Figure 2-11. Group of Four Programmable I/O Cells 1 PIC PIO A Input Register Block Output Register Block & Tristate Register Block Pin A PIO B Input Register Block Core Logic/ Routing Input Gearbox Output Gearbox Output Register Block & Tristate Register Block Pin B PIO C Input Register Block Output Register Block & Tristate Register Block Pin C PIO D Input Register Block Output Register Block & Tristate Register Block Pin D Notes: 1. Input gearbox is available only in PIC on the bottom edge of MachXO2-640U, MachXO2-1200/U and larger devices. 2. Output gearbox is available only in PIC on the top edge of MachXO2-640U, MachXO2-1200/U and larger devices. 2-16 Architecture MachXO2 Family Data Sheet PIO The PIO contains three blocks: an input register block, output register block and tri-state register block. These blocks contain registers for operating in a variety of modes along with the necessary clock and selection logic. Table 2-8. PIO Signal List Pin Name CE D I/O Type Description Input Clock Enable Input Pin input from sysIO buffer. INDD Output Register bypassed input. INCK Output Clock input Q0 Output DDR positive edge input Q1 Output D0 Input Registered input/DDR negative edge input Output signal from the core (SDR and DDR) D1 Input Output signal from the core (DDR) TD Input Tri-state signal from the core Q Output Data output signals to sysIO Buffer TQ Output Tri-state output signals to sysIO Buffer 1 DQSR90 Input DQS shift 90-degree read clock DQSW901 Input DQS shift 90-degree write clock DDRCLKPOL 1 Input DDR input register polarity control signal from DQS SCLK Input System clock for input and output/tri-state blocks. RST Input Local set reset signal 1. Available in PIO on right edge only. Input Register Block The input register blocks for the PIOs on all edges contain delay elements and registers that can be used to condition high-speed interface signals before they are passed to the device core. In addition to this functionality, the input register blocks for the PIOs on the right edge include built-in logic to interface to DDR memory. Figure 2-12 shows the input register block for the PIOs located on the left, top and bottom edges. Figure 2-13 shows the input register block for the PIOs on the right edge. Left, Top, Bottom Edges Input signals are fed from the sysIO buffer to the input register block (as signal D). If desired, the input signal can bypass the register and delay elements and be used directly as a combinatorial signal (INDD), and a clock (INCK). If an input delay is desired, users can select a fixed delay. I/Os on the bottom edge also have a dynamic delay, DEL[4:0]. The delay, if selected, reduces input register hold time requirements when using a global clock. The input block allows two modes of operation. In single data rate (SDR) the data is registered with the system clock (SCLK) by one of the registers in the single data rate sync register block. In Generic DDR mode, two registers are used to sample the data on the positive and negative edges of the system clock (SCLK) signal, creating two data streams. 2-17 Architecture MachXO2 Family Data Sheet Figure 2-12. MachXO2 Input Register Block Diagram (PIO on Left, Top and Bottom Edges) INCK INDD D Programmable Delay Cell Q1 D D Q Q1 D/L Q Q Q0 D Q Q0 SCLK Right Edge The input register block on the right edge is a superset of the same block on the top, bottom, and left edges. In addition to the modes described above, the input register block on the right edge also supports DDR memory mode. In DDR memory mode, two registers are used to sample the data on the positive and negative edges of the modified DQS (DQSR90) in the DDR Memory mode creating two data streams. Before entering the core, these two data streams are synchronized to the system clock to generate two data streams. 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 DQS domain. The DQSR90 and DDRCLKPOL signals are generated in the DQS read-write block. Figure 2-13. MachXO2 Input Register Block Diagram (PIO on Right Edge) INCK INDD D Programmable Delay Cell D Q Q1 D Q S1 D Q D Q Q0 D Q S0 D Q DQSR90 DDRCLKPOL SCLK 2-18 D/L Q D Q Q1 Q0 Architecture MachXO2 Family Data Sheet Output Register Block The output register block registers signals from the core of the device before they are passed to the sysIO buffers. Left, Top, Bottom Edges In SDR mode, D0 feeds one of the flip-flops that then feeds the output. The flip-flop can be configured as a D-type register or latch. In DDR generic mode, D0 and D1 inputs are fed into registers on the positive edge of the clock. At the next falling edge the registered D1 input is registered into the register Q1. A multiplexer running off the same clock is used to switch the mux between the outputs of registers Q0 and Q1 that will then feed the output. Figure 2-14 shows the output register block on the left, top and bottom edges. Figure 2-14. MachXO2 Output Register Block Diagram (PIO on the Left, Top and Bottom Edges) Q Q0 D/L Q D0 D1 D Q D Q Q1 SCLK TD Output path D/L Q TQ Tri-state path Right Edge The output register block on the right edge is a superset of the output register on left, top and bottom edges of the device. In addition to supporting SDR and Generic DDR modes, the output register blocks for PIOs on the right edge include additional logic to support DDR-memory interfaces. Operation of this block is similar to that of the output register block on other edges. In DDR memory mode, D0 and D1 inputs are fed into registers on the positive edge of the clock. At the next falling edge the registered D1 input is registered into the register Q1. A multiplexer running off the DQSW90 signal is used to switch the mux between the outputs of registers Q0 and Q1 that will then feed the output. Figure 2-15 shows the output register block on the right edge. 2-19 Architecture MachXO2 Family Data Sheet Figure 2-15. MachXO2 Output Register Block Diagram (PIO on the Right Edges) D/L Q D0 D1 D Q D Q Q Q0 Q1 SCLK DQSW90 Output Register Block T0 TD TQ D Q D/L Q Tristate Register Block Tri-state Register Block The tri-state register block registers tri-state control signals from the core of the device before they are passed to the sysIO buffers. The block contains a register for SDR operation. In SDR, TD input feeds one of the flip-flops that then feeds the output. The tri-state register blocks on the right edge contain an additional register for DDR memory operation. In DDR memory mode, the register TS input is fed into another register that is clocked using the DQSW90 signal. The output of this register is used as a tri-state control. Input Gearbox Each PIC on the bottom edge has a built-in 1:8 input gearbox. Each of these input gearboxes may be programmed as a 1:7 de-serializer or as one IDDRX4 (1:8) gearbox or as two IDDRX2 (1:4) gearboxes. Table 2-9 shows the gearbox signals. Table 2-9. Input Gearbox Signal List Name I/O Type Description D Input High-speed data input after programmable delay in PIO A input register block ALIGNWD Input Data alignment signal from device core SCLK Input Slow-speed system clock ECLK[1:0] Input High-speed edge clock RST Input Reset Q[7:0] Output Low-speed data to device core: Video RX(1:7): Q[6:0] GDDRX4(1:8): Q[7:0] GDDRX2(1:4)(IOL-A): Q4, Q5, Q6, Q7 GDDRX2(1:4)(IOL-C): Q0, Q1, Q2, Q3 2-20 Architecture MachXO2 Family Data Sheet These gearboxes have three stage pipeline registers. The first stage registers sample the high-speed input data by the high-speed edge clock on its rising and falling edges. The second stage registers perform data alignment based on the control signals UPDATE and SEL0 from the control block. The third stage pipeline registers pass the data to the device core synchronized to the low-speed system clock. Figure 2-16 shows a block diagram of the input gearbox. Figure 2-16. Input Gearbox Q21 Q43 D Q D Q Q65 Q0_ Q10 D Q CE Q32 D Q CE Q54 D Q CE Q_6 D Q CE D Q S2 Q21 Q43 D Q S0 Q65 D Q S4 S6 D Q D Q D Q T0 T2 T4 T6 Q0 Q2 Q4 Q6 D Q_6 D Q D Q CE Q54 Q_6 D Q Q54 D Q Q32 S5 Q65 D Q CE Q43 D Q S3 CE Q32 Q10 D Q S7 D Q CE Q21 ECLK0/1 S1 T7 Q7 T5 Q5 T3 Q3 T1 Q1 D Q D D D SCLK SEL0 UPDATE 2-21 Architecture MachXO2 Family Data Sheet More information on the input gearbox is available in TN1203, Implementing High-Speed Interfaces with MachXO2 Devices. Output Gearbox Each PIC on the top edge has a built-in 8:1 output gearbox. Each of these output gearboxes may be programmed as a 7:1 serializer or as one ODDRX4 (8:1) gearbox or as two ODDRX2 (4:1) gearboxes. Table 2-10 shows the gearbox signals. Table 2-10. Output Gearbox Signal List Name Q D[7:0] I/O Type Output Description High-speed data output Input Low-speed data from device core SCLK Input Slow-speed system clock ECLK [1:0] Input High-speed edge clock RST Input Reset Video TX(7:1): D[6:0] GDDRX4(8:1): D[7:0] GDDRX2(4:1)(IOL-A): D[3:0] GDDRX2(4:1)(IOL-C): D[7:4] The gearboxes have three stage pipeline registers. The first stage registers sample the low-speed input data on the low-speed system clock. The second stage registers transfer data from the low-speed clock registers to the highspeed clock registers. The third stage pipeline registers controlled by high-speed edge clock shift and mux the high-speed data out to the sysIO buffer. Figure 2-17 shows the output gearbox block diagram. 2-22 Architecture MachXO2 Family Data Sheet Figure 2-17. Output Gearbox D6 D Q D4 D Q T6 T4 D Q CE D Q CE S6 S7 0 1 GND 0 1 Q67 S4 S5 0 1 S3 0 1 D Q 0 1 D Q 0 1 D Q Q67 Q45 ODDRx2_C D Q D2 T2 D Q CE Q45 S2 Q23 QC D Q T0 D0 D Q CE S0 S1 0 1 Q23 0 1 Q01 D Q Q/QA D1 D Q T1 T3 D Q D3 D Q CE S1 D Q S3 CE Q12 0 1 D Q 0 1 D Q 0 1 D Q S4 0 1 GND 0 1 D Q S6 0 1 S0 S2 0 1 0 1 Q34 Q10 Q32 ODDRx2_A D5 Q D Q D D7 T5 T7 D Q CE D Q CE Q56 S5 S7 Q54 Q76 ODDRx2_C SCLK SEL /0 UPDATE ECLK0/1 More information on the output gearbox is available in TN1203, Implementing High-Speed Interfaces with MachXO2 Devices. 2-23 Architecture MachXO2 Family Data Sheet DDR Memory Support Certain PICs on the right edge of MachXO2-640U, MachXO2-1200/U and larger devices, have additional circuitry to allow the implementation of DDR memory interfaces. There are two groups of 14 or 12 PIOs each on the right edge with additional circuitry to implement DDR memory interfaces. This capability allows the implementation of up to 16-bit wide memory interfaces. One PIO from each group contains a control element, the DQS Read/Write Block, to facilitate the generation of clock and control signals (DQSR90, DQSW90, DDRCLKPOL and DATAVALID). These clock and control signals are distributed to the other PIO in the group through dedicated low skew routing. DQS Read Write 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 (referred to as DQS) is not free-running so this approach cannot be used. The DQS Read Write block provides the required clock alignment for DDR memory interfaces. DQSR90 and DQSW90 signals are generated by the DQS Read Write block from the DQS input. 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 MachXO2 family contains dedicated circuits to transfer data between these domains. To prevent set-up and hold violations, at the domain transfer between DQS (delayed) and the system clock, a clock polarity selector is used. This circuit 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 tri-state (pulled by termination). The DDR memory device drives DQS low at the start of the preamble state. A dedicated circuit in the DQS Read Write block detects the first DQS rising edge after the preamble state and generates the DDRCLKPOL signal. This signal is used to control the polarity of the clock to the synchronizing registers. The temperature, voltage and process variations of the DQS delay block are compensated by a set of calibration signals (6-bit bus) from a DLL on the right edge of the device. The DLL loop is compensated for temperature, voltage and process variations by the system clock and feedback loop. sysIO Buffer Each I/O is associated with a flexible buffer referred to as a sysIO buffer. These buffers are arranged around the periphery of the device in groups referred to as banks. The sysIO buffers allow users to implement a wide variety of standards that are found in today’s systems including LVCMOS, TTL, PCI, SSTL, HSTL, LVDS, BLVDS, MLVDS and LVPECL. Each bank is capable of supporting multiple I/O standards. In the MachXO2 devices, single-ended output buffers, ratioed input buffers (LVTTL, LVCMOS and PCI), differential (LVDS) and referenced input buffers (SSTL and HSTL) are powered using I/O supply voltage (VCCIO). Each sysIO bank has its own VCCIO. In addition, each bank has a voltage reference, VREF, which allows the use of referenced input buffers independent of the bank VCCIO. MachXO2-256 and MachXO2-640 devices contain single-ended ratioed input buffers and single-ended output buffers with complementary outputs on all the I/O banks. Note that the single-ended input buffers on these devices do not contain PCI clamps. In addition to the single-ended I/O buffers these two devices also have differential and referenced input buffers on all I/Os. The I/Os are arranged in pairs, the two pads in the pair are described as “T” and “C”, 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. 2-24 Architecture MachXO2 Family Data Sheet MachXO2-640U, MachXO2-1200/U, MachXO2-2000/U, MachXO2-4000 and MachXO2-7000 devices contain three types of sysIO buffer pairs. 1. Left and Right sysIO Buffer Pairs The sysIO buffer pairs in the left and right banks of the device consist of two single-ended output drivers and two single-ended input buffers (for ratioed inputs such as LVCMOS and LVTTL). The I/O pairs on the left and right of the devices also have differential and referenced input buffers. 2. Bottom sysIO Buffer Pairs The sysIO buffer pairs in the bottom bank of the device consist of two single-ended output drivers and two single-ended input buffers (for ratioed inputs such as LVCMOS and LVTTL). The I/O pairs on the bottom also have differential and referenced input buffers. Only the I/Os on the bottom banks have programmable PCI clamps and differential input termination. The PCI clamp is enabled after VCC and VCCIO are at valid operating levels and the device has been configured. 3. Top sysIO Buffer Pairs The sysIO buffer pairs in the top bank of the device consist of two single-ended output drivers and two singleended input buffers (for ratioed inputs such as LVCMOS and LVTTL). The I/O pairs on the top also have differential and referenced I/O buffers. Half of the sysIO buffer pairs on the top edge have true differential outputs. The sysIO buffer pair comprising of the A and B PIOs in every PIC on the top edge have a differential output driver. The referenced input buffer can also be configured as a differential input buffer. Typical I/O Behavior During Power-up The internal power-on-reset (POR) signal is deactivated when VCC and VCCIO0 have reached VPORUP level defined in the Power-On-Reset Voltage table in the DC and Switching Characteristics section of this data sheet. After the POR signal is deactivated, the FPGA core logic becomes active. It is the user’s responsibility to ensure that all 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. The default configuration of the I/O pins in a blank device is tri-state with a weak pulldown to GND (some pins such as PROGRAMN and the JTAG pins have weak pull-up to VCCIO as the default functionality). The I/O pins will maintain the blank configuration until VCC and VCCIO (for I/O banks containing configuration I/Os) have reached VPORUP levels at which time the I/Os will take on the user-configured settings only after a proper download/configuration. Supported Standards The MachXO2 sysIO buffer supports both single-ended and differential standards. Single-ended standards can be further subdivided into LVCMOS, LVTTL, and PCI. The buffer supports the LVTTL, PCI, LVCMOS 1.2, 1.5, 1.8, 2.5, and 3.3 V standards. In the LVCMOS and LVTTL modes, the buffer has individually configurable options for drive strength, bus maintenance (weak pull-up, weak pull-down, bus-keeper latch or none) and open drain. BLVDS, MLVDS and LVPECL output emulation is supported on all devices. The MachXO2-640U, MachXO2-1200/U and higher devices support on-chip LVDS output buffers on approximately 50% of the I/Os on the top bank. Differential receivers for LVDS, BLVDS, MLVDS and LVPECL are supported on all banks of MachXO2 devices. PCI support is provided in the bottom bank of theMachXO2-640U, MachXO2-1200/U and higher density devices. Table 2-11 summarizes the I/O characteristics of the MachXO2 PLDs. Tables 2-11 and 2-12 show the I/O standards (together with their supply and reference voltages) supported by the MachXO2 devices. For further information on utilizing the sysIO buffer to support a variety of standards please see TN1202, MachXO2 sysIO Usage Guide. 2-25 Architecture MachXO2 Family Data Sheet Table 2-11. I/O Support Device by Device MachXO2-256, MachXO2-640 Number of I/O Banks 4 Single-ended (all I/O banks) Type of Input Buffers Differential Receivers (all I/O banks) MachXO2-1200U MachXO2-2000/U, MachXO2-4000, MachXO2-7000 MachXO2-640U, MachXO2-1200 4 6 Single-ended (all I/O banks) Single-ended (all I/O banks) Differential Receivers (all I/O banks) Differential Receivers (all I/O banks) Differential input termination (bottom side) Differential input termination (bottom side) Single-ended buffers with Single-ended buffers with complementary outputs (all I/O complementary outputs (all I/O banks) banks) Single-ended buffers with complementary outputs (all I/O Differential buffers with true banks) LVDS outputs (50% on top side) Differential buffers with true LVDS outputs (50% on top side) Differential Output Emulation Capability All I/O banks All I/O banks All I/O banks PCI Clamp Support No Clamp on bottom side only Clamp on bottom side only Types of Output Buffers Table 2-12. Supported Input Standards VCCIO (Typ.) Input Standard 3.3 V 2.5 V 1.8 V 1.5 1.2 V LVTTL  2 2 2 LVCMOS33    2 2 LVCMOS25 2  2 2 LVCMOS18   2  2 LVCMOS15 2 2 2  2 LVCMOS12   2     Single-Ended Interfaces 2 2 2 PCI  SSTL18 (Class I, Class II)   SSTL25 (Class I, Class II)   HSTL18 (Class I, Class II)   LVDS   BLVDS, MVDS, LVPECL, RSDS   MIPI3   Differential SSTL18 Class I, II   Differential SSTL25 Class I, II   Differential HSTL18 Class I, II   1 2 2  Differential Interfaces   1. Bottom banks of MachXO2-640U, MachXO2-1200/U and higher density devices only. 2. Reduced functionality. Refer to TN1202, MachXO2 sysIO Usage Guide for more detail. 3. These interfaces can be emulated with external resistors in all devices. 2-26 Architecture MachXO2 Family Data Sheet Table 2-13. Supported Output Standards Output Standard VCCIO (Typ.) Single-Ended Interfaces LVTTL 3.3 LVCMOS33 3.3 LVCMOS25 2.5 LVCMOS18 1.8 LVCMOS15 1.5 LVCMOS12 1.2 LVCMOS33, Open Drain — LVCMOS25, Open Drain — LVCMOS18, Open Drain — LVCMOS15, Open Drain — LVCMOS12, Open Drain — PCI33 3.3 SSTL25 (Class I) 2.5 SSTL18 (Class I) 1.8 HSTL18(Class I) 1.8 Differential Interfaces LVDS1, 2 BLVDS, MLVDS, RSDS 2.5, 3.3 2 2.5 LVPECL2 MIPI 3.3 2 2.5 Differential SSTL18 1.8 Differential SSTL25 2.5 Differential HSTL18 1.8 1. MachXO2-640U, MachXO2-1200/U and larger devices have dedicated LVDS buffers. 2. These interfaces can be emulated with external resistors in all devices. sysIO Buffer Banks The numbers of banks vary between the devices of this family. MachXO2-1200U, MachXO2-2000/U and higher density devices have six I/O banks (one bank on the top, right and bottom side and three banks on the left side). The MachXO2-1200 and lower density devices have four banks (one bank per side). Figures 2-18 and 2-19 show the sysIO banks and their associated supplies for all devices. 2-27 Architecture MachXO2 Family Data Sheet Figure 2-18. MachXO2-1200U, MachXO2-2000/U, MachXO2-4000 and MachXO2-7000 Banks GND GND VCCIO3 GND Bank 5 VCCIO1 Bank 1 VCCIO4 Bank 0 Bank 4 GND GND Bank 3 VCCIO5 VCCIO0 Bank 2 GND VCCIO2 Figure 2-19. MachXO2-256, MachXO2-640/U and MachXO2-1200 Banks GND VCCIO0 Bank 0 VCCIO3 VCCIO1 Bank 3 Bank 1 GND GND Bank 2 GND VCCIO2 2-28 Architecture MachXO2 Family Data Sheet Hot Socketing The MachXO2 devices have been carefully designed to ensure predictable behavior during power-up and powerdown. Leakage into I/O pins is controlled to within specified limits. This allows for easy integration with the rest of the system. These capabilities make the MachXO2 ideal for many multiple power supply and hot-swap applications. On-chip Oscillator Every MachXO2 device has an internal CMOS oscillator. The oscillator output can be routed as a clock to the clock tree or as a reference clock to the sysCLOCK PLL using general routing resources. The oscillator frequency can be divided by internal logic. There is a dedicated programming bit and a user input to enable/disable the oscillator. The oscillator frequency ranges from 2.08 MHz to 133 MHz. The software default value of the Master Clock (MCLK) is nominally 2.08 MHz. When a different MCLK is selected during the design process, the following sequence takes place: 1. Device powers up with a nominal MCLK frequency of 2.08 MHz. 2. During configuration, users select a different master clock frequency. 3. The MCLK 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 2.08 MHz. Table 2-14 lists all the available MCLK frequencies. Table 2-14. Available MCLK Frequencies MCLK (MHz, Nominal) MCLK (MHz, Nominal) MCLK (MHz, Nominal) 2.08 (default) 9.17 33.25 2.46 10.23 38 3.17 13.3 44.33 4.29 14.78 53.2 5.54 20.46 66.5 7 26.6 88.67 8.31 29.56 133 Embedded Hardened IP Functions and User Flash Memory All MachXO2 devices provide embedded hardened functions such as SPI, I2C and Timer/Counter. MachXO2-640/U and higher density devices also provide User Flash Memory (UFM). These embedded blocks interface through the WISHBONE interface with routing as shown in Figure 2-20. 2-29 Architecture MachXO2 Family Data Sheet Figure 2-20. Embedded Function Block Interface Configuration Logic Power Control Embedded Function Block (EFB) I2C (Primary) Core Logic/ Routing EFB WISHBONE Interface I2C (Secondary) SPI I/Os for I2C (Primary) I/Os for I2C (Secondary) I/Os for SPI Timer/Counter PLL0 PLL1 UFM Indicates connection through core logic/routing. Hardened I2C IP Core Every MachXO2 device contains two I2C IP cores. These are the primary and secondary I2C IP cores. Either of the two cores can be configured either as an I2C master or as an I2C slave. The only difference between the two IP cores is that the primary core has pre-assigned I/O pins whereas users can assign I/O pins for the secondary core. When the IP core is configured as a master it will be able to control other devices on the I2C bus through the interface. When the core is configured as the slave, the device will be able to provide I/O expansion to an I2C Master. The I2C cores support the following functionality: • Master and Slave operation • 7-bit and 10-bit addressing • Multi-master arbitration support • Up to 400 kHz data transfer speed • General call support • Interface to custom logic through 8-bit WISHBONE interface 2-30 Architecture MachXO2 Family Data Sheet Figure 2-21. I2C Core Block Diagram Configuration Logic Power Control EFB I2C Function Core Logic/ Routing SCL EFB WISHBONE Interface I2C Registers Control Logic SDA Table 2-15 describes the signals interfacing with the I2C cores. Table 2-15. I2C Core Signal Description Signal Name I/O Description Bi-directional Bi-directional clock line of the I2C core. The signal is an output if the I2C core is in master mode. The signal is an input if the I2C core is in slave mode. MUST be routed directly to the pre-assigned I/O of the chip. Refer to the Pinout Information section of this document for detailed pad and pin locations of I2C ports in each MachXO2 device. Bi-directional Bi-directional data line of the I2C core. The signal is an output when data is transmitted from the I2C core. The signal is an input when data is received into the I2C core. MUST be routed directly to the pre-assigned I/O of the chip. Refer to the Pinout Information section of this document for detailed pad and pin locations of I2C ports in each MachXO2 device. i2c_irqo Output Interrupt request output signal of the I2C core. The intended usage of this signal is for it to be connected to the WISHBONE master controller (i.e. a microcontroller or state machine) and request an interrupt when a specific condition is met. These conditions are described with the I2C register definitions. cfg_wake Output Wake-up signal – To be connected only to the power module of the MachXO2 device. The signal is enabled only if the “Wakeup Enable” feature has been set within the EFB GUI, I2C Tab. cfg_stdby Output Stand-by signal – To be connected only to the power module of the MachXO2 device. The signal is enabled only if the “Wakeup Enable” feature has been set within the EFB GUI, I2C Tab. i2c_scl i2c_sda Hardened SPI IP Core Every MachXO2 device has a hard SPI IP core that can be configured as a SPI master or slave. When the IP core is configured as a master it will be able to control other SPI enabled chips connected to the SPI bus. When the core is configured as the slave, the device will be able to interface to an external SPI master. The SPI IP core on MachXO2 devices supports the following functions: • Configurable Master and Slave modes • Full-Duplex data transfer • Mode fault error flag with CPU interrupt capability • Double-buffered data register • Serial clock with programmable polarity and phase • LSB First or MSB First Data Transfer • Interface to custom logic through 8-bit WISHBONE interface 2-31 Architecture MachXO2 Family Data Sheet There are some limitations on the use of the hardened user SPI. These are defined in the following technical notes: • TN1087, Minimizing System Interruption During Configuration Using TransFR Technology (Appendix B) • TN1205, Using User Flash Memory and Hardened Control Functions in MachXO2 Devices Figure 2-22. SPI Core Block Diagram Configuration Logic EFB SPI Function MISO Core Logic/ Routing MOSI EFB WISHBONE Interface SPI Registers Control Logic SCK MCSN SCSN Table 2-16 describes the signals interfacing with the SPI cores. Table 2-16. SPI Core Signal Description I/O Master/Slave spi_csn[0] Signal Name O Master SPI master chip-select output Description spi_csn[1..7] O Master Additional SPI chip-select outputs (total up to eight slaves) spi_scsn I Slave SPI slave chip-select input spi_irq O Master/Slave Interrupt request spi_clk I/O Master/Slave SPI clock. Output in master mode. Input in slave mode. spi_miso I/O Master/Slave SPI data. Input in master mode. Output in slave mode. spi_mosi I/O Master/Slave SPI data. Output in master mode. Input in slave mode. ufm_sn I Slave cfg_stdby O Master/Slave Stand-by signal – To be connected only to the power module of the MachXO2 device. The signal is enabled only if the “Wakeup Enable” feature has been set within the EFB GUI, SPI Tab. cfg_wake O Master/Slave Wake-up signal – To be connected only to the power module of the MachXO2 device. The signal is enabled only if the “Wakeup Enable” feature has been set within the EFB GUI, SPI Tab. Configuration Slave Chip Select (active low), dedicated for selecting the User Flash Memory (UFM). 2-32 Architecture MachXO2 Family Data Sheet Hardened Timer/Counter MachXO2 devices provide a hard Timer/Counter IP core. This Timer/Counter is a general purpose, bi-directional, 16-bit timer/counter module with independent output compare units and PWM support. The Timer/Counter supports the following functions: • Supports the following modes of operation: — Watchdog timer — Clear timer on compare match — Fast PWM — Phase and Frequency Correct PWM • Programmable clock input source • Programmable input clock prescaler • One static interrupt output to routing • One wake-up interrupt to on-chip standby mode controller. • Three independent interrupt sources: overflow, output compare match, and input capture • Auto reload • Time-stamping support on the input capture unit • Waveform generation on the output • Glitch-free PWM waveform generation with variable PWM period • Internal WISHBONE bus access to the control and status registers • Stand-alone mode with preloaded control registers and direct reset input Figure 2-23. Timer/Counter Block Diagram EFB Core Logic Routing EFB WISHBONE Interface Timer/Counter Timer/ Counter Registers Control Logic PWM Table 2-17. Timer/Counter Signal Description Port I/O Description tc_clki I Timer/Counter input clock signal tc_rstn I Register tc_rstn_ena is preloaded by configuration to always keep this pin enabled tc_ic I Input capture trigger event, applicable for non-pwm modes with WISHBONE interface. If enabled, a rising edge of this signal will be detected and synchronized to capture tc_cnt value into tc_icr for time-stamping. tc_int O Without WISHBONE – Can be used as overflow flag With WISHBONE – Controlled by three IRQ registers tc_oc O Timer counter output signal 2-33 Architecture MachXO2 Family Data Sheet For more details on these embedded functions, please refer to TN1205, Using User Flash Memory and Hardened Control Functions in MachXO2 Devices. User Flash Memory (UFM) MachXO2-640/U and higher density devices provide a User Flash Memory block, which can be used for a variety of applications including storing a portion of the configuration image, initializing EBRs, to store PROM data or, as a general purpose user Flash memory. The UFM block connects to the device core through the embedded function block WISHBONE interface. Users can also access the UFM block through the JTAG, I2C and SPI interfaces of the device. The UFM block offers the following features: • Non-volatile storage up to 256 kbits • 100K write cycles • Write access is performed page-wise; each page has 128 bits (16 bytes) • Auto-increment addressing • WISHBONE interface For more information on the UFM, please refer to TN1205, Using User Flash Memory and Hardened Control Functions in MachXO2 Devices. Standby Mode and Power Saving Options MachXO2 devices are available in three options for maximum flexibility: ZE, HC and HE devices. The ZE devices have ultra low static and dynamic power consumption. These devices use a 1.2 V core voltage that further reduces power consumption. The HC and HE devices are designed to provide high performance. The HC devices have a built-in voltage regulator to allow for 2.5 V VCC and 3.3 V VCC while the HE devices operate at 1.2 V VCC. MachXO2 devices have been designed with features that allow users to meet the static and dynamic power requirements of their applications by controlling various device subsystems such as the bandgap, power-on-reset circuitry, I/O bank controllers, power guard, on-chip oscillator, PLLs, etc. In order to maximize power savings, MachXO2 devices support an ultra low power Stand-by mode. While most of these features are available in all three device types, these features are mainly intended for use with MachXO2 ZE devices to manage power consumption. In the stand-by mode the MachXO2 devices are powered on and configured. Internal logic, I/Os and memories are switched on and remain operational, as the user logic waits for an external input. The device enters this mode when the standby input of the standby controller is toggled or when an appropriate I2C or JTAG instruction is issued by an external master. Various subsystems in the device such as the band gap, power-on-reset circuitry etc can be configured such that they are automatically turned “off” or go into a low power consumption state to save power when the device enters this state. Note that the MachXO2 devices are powered on when in standby mode and all power supplies should remain in the Recommended Operating Conditions. 2-34 Architecture MachXO2 Family Data Sheet Table 2-18. MachXO2 Power Saving Features Description Device Subsystem Feature Description Bandgap The bandgap can be turned off in standby mode. When the Bandgap is turned off, analog circuitry such as the POR, PLLs, on-chip oscillator, and referenced and differential  I/O buffers are also turned off. Bandgap can only be turned off for 1.2 V devices. Power-On-Reset (POR) The POR can be turned off in standby mode. This monitors VCC levels. In the event of unsafe VCC drops, this circuit reconfigures the device. When the POR circuitry is turned off, limited power detector circuitry is still active. This option is only recommended for applications in which the power supply rails are reliable. On-Chip Oscillator The on-chip oscillator has two power saving features. It may be switched off if it is not needed in your design. It can also be turned off in Standby mode. PLL Similar to the on-chip oscillator, the PLL also has two power saving features. It can be statically switched off if it is not needed in a design. It can also be turned off in Standby mode. The PLL will wait until all output clocks from the PLL are driven low before powering off. I/O Bank Controller Referenced and differential I/O buffers (used to implement standards such as HSTL, SSTL and LVDS) consume more than ratioed single-ended I/Os such as LVCMOS and LVTTL. The I/O bank controller allows the user to turn these I/Os off dynamically on a per bank selection. Dynamic Clock Enable for Primary Clock Nets Each primary clock net can be dynamically disabled to save power. Power Guard Power Guard is a feature implemented in input buffers. This feature allows users to switch off the input buffer when it is not needed. This feature can be used in both clock and data paths. Its biggest impact is that in the standby mode it can be used to switch off clock inputs that are distributed using general routing resources. For more details on the standby mode refer to TN1198, Power Estimation and Management for MachXO2 Devices. Power On Reset MachXO2 devices have power-on reset circuitry to monitor VCCINT and VCCIO voltage levels during power-up and operation. At power-up, the POR circuitry monitors VCCINT and VCCIO0 (controls configuration) voltage levels. It then triggers download from the on-chip configuration Flash memory after reaching the VPORUP level specified in the Power-On-Reset Voltage table in the DC and Switching Characteristics section of this data sheet. For devices without voltage regulators (ZE and HE devices), VCCINT is the same as the VCC supply voltage. For devices with voltage regulators (HC devices), VCCINT is regulated from the VCC supply voltage. From this voltage reference, the time taken for configuration and entry into user mode is specified as Flash Download Time (tREFRESH) in the DC and Switching Characteristics section of this data sheet. Before and during configuration, the I/Os are held in tristate. I/Os are released to user functionality once the device has finished configuration. Note that for HC devices, a separate POR circuit monitors external VCC voltage in addition to the POR circuit that monitors the internal postregulated power supply voltage level. Once the device enters into user mode, the POR circuitry can optionally continue to monitor VCCINT levels. If VCCINT drops below VPORDNBG level (with the bandgap circuitry switched on) or below VPORDNSRAM level (with the bandgap circuitry switched off to conserve power) device functionality cannot be guaranteed. In such a situation the POR issues a reset and begins monitoring the VCCINT and VCCIO voltage levels. VPORDNBG and VPORDNSRAM are both specified in the Power-On-Reset Voltage table in the DC and Switching Characteristics section of this data sheet. Note that once a ZE or HE device enters user mode, users can switch off the bandgap to conserve power. When the bandgap circuitry is switched off, the POR circuitry also shuts down. The device is designed such that a minimal, low power POR circuit is still operational (this corresponds to the VPORDNSRAM reset point described in the paragraph above). However this circuit is not as accurate as the one that operates when the bandgap is switched on. The low power POR circuit emulates an SRAM cell and is biased to trip before the vast majority of SRAM cells flip. If users are concerned about the VCC supply dropping below VCC (min) they should not shut down the bandgap or POR circuit. 2-35 Architecture MachXO2 Family Data Sheet Configuration and Testing This section describes the configuration and testing features of the MachXO2 family. IEEE 1149.1-Compliant Boundary Scan Testability All MachXO2 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 access port consists of dedicated I/Os: TDI, TDO, TCK and TMS. The test access port shares its power supply with VCCIO Bank 0 and can operate with LVCMOS3.3, 2.5, 1.8, 1.5, and 1.2 standards. For more details on boundary scan test, see AN8066, Boundary Scan Testability with Lattice sysIO Capability and TN1087, Minimizing System Interruption During Configuration Using TransFR Technology. Device Configuration All MachXO2 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 which supports serial configuration through I2C or SPI. The TAP supports both the IEEE Standard 1149.1 Boundary Scan specification and the IEEE Standard 1532 In-System Configuration specification. There are various ways to configure a MachXO2 device: 1. Internal Flash Download 2. JTAG 3. Standard Serial Peripheral Interface (Master SPI mode) – interface to boot PROM memory 4. System microprocessor to drive a serial slave SPI port (SSPI mode) 5. Standard I2C Interface to system microprocessor Upon power-up, the configuration 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. Optionally the device can run a CRC check upon entering the user mode. This will ensure that the device was configured correctly. The sysCONFIG port has 10 dual-function pins which can be used as general purpose I/Os if they are not required for configuration. See TN1204, MachXO2 Programming and Configuration Usage Guide for more information about using the dual-use pins as general purpose I/Os. Lattice design software uses proprietary compression technology to compress bit-streams for use in MachXO2 devices. Use of this technology allows Lattice to provide a lower cost solution. In the unlikely event that this technology is unable to compress bitstreams to fit into the amount of on-chip Flash memory, there are a variety of techniques that can be utilized to allow the bitstream to fit in the on-chip Flash memory. For more details, refer to TN1204, MachXO2 Programming and Configuration Usage Guide. The Test Access Port (TAP) has five dual purpose pins (TDI, TDO, TMS, TCK and JTAGENB). These pins are dual function pins - TDI, TDO, TMS and TCK can be used as general purpose I/O if desired. For more details, refer to TN1204, MachXO2 Programming and Configuration Usage Guide. TransFR (Transparent Field Reconfiguration) TransFR is a unique Lattice technology that allows users to update their logic in the field without interrupting system operation using a simple push-button solution. For more details refer to TN1087, Minimizing System Interruption During Configuration Using TransFR Technology for details. 2-36 Architecture MachXO2 Family Data Sheet When implementing background programming of the on-chip Flash, care must be taken for the operation of the PLL. For devices that have two PLLs (XO2-2000U, -4000 and -7000), the system must put the RPLL (Right-side PLL) in reset state during the background Flash programming. More detailed description can be found in TN1204, MachXO2 Programming and Configuration Usage Guide. Security and One-Time Programmable Mode (OTP) For applications where security is important, the lack of an external bitstream provides a solution that is inherently more secure than SRAM-based FPGAs. This is further enhanced by device locking. MachXO2 devices contain security bits that, when set, prevent the readback of the SRAM configuration and non-volatile Flash memory spaces. The device can be in one of two modes: 1. Unlocked – Readback of the SRAM configuration and non-volatile Flash memory spaces is allowed. 2. Permanently Locked – The device is permanently locked. Once set, the only way to clear the security bits is to erase the device. To further complement the security of the device, a One Time Programmable (OTP) mode is available. Once the device is set in this mode it is not possible to erase or re-program the Flash and SRAM OTP portions of the device. For more details, refer to TN1204, MachXO2 Programming and Configuration Usage Guide. Dual Boot MachXO2 devices can optionally boot from two patterns, a primary bitstream and a golden bitstream. If the primary bitstream is found to be corrupt while being downloaded into the SRAM, the device shall then automatically re-boot from the golden bitstream. Note that the primary bitstream must reside in the on-chip Flash. The golden image MUST reside in an external SPI Flash. For more details, refer to TN1204, MachXO2 Programming and Configuration Usage Guide. Soft Error Detection The SED feature is a CRC check of the SRAM cells after the device is configured. This check ensures that the SRAM cells were configured successfully. This feature is enabled by a configuration bit option. The Soft Error Detection can also be initiated in user mode via an input to the fabric. The clock for the Soft Error Detection circuit is generated using a dedicated divider. The undivided clock from the on-chip oscillator is the input to this divider. For low power applications users can switch off the Soft Error Detection circuit. For more details, refer to TN1206, MachXO2 Soft Error Detection Usage Guide. TraceID Each MachXO2 device contains a unique (per device), TraceID that can be used for tracking purposes or for IP security applications. The TraceID is 64 bits long. Eight out of 64 bits are user-programmable, the remaining 56 bits are factory-programmed. The TraceID is accessible through the EFB WISHBONE interface and can also be accessed through the SPI, I2C, or JTAG interfaces. Density Shifting The MachXO2 family has been designed to enable density migration within the same package. 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 likely success in each case. When migrating from lower to higher density or higher to lower density, ensure to review all the power supplies and NC pins of the chosen devices. For more details refer to the MachXO2 migration files. 2-37 MachXO2 Family Data Sheet DC and Switching Characteristics March 2017 Data Sheet DS1035 Absolute Maximum Ratings1, 2, 3 MachXO2 ZE/HE (1.2 V) MachXO2 HC (2.5 V / 3.3 V) Supply Voltage VCC . . . . . . . . . . . . . . . . . . . . . . .–0.5 V to 1.32 V . . . . . . . . . . . . .–0.5 V to 3.75 V Output Supply Voltage VCCIO . . . . . . . . . . . . . . .–0.5 V to 3.75 V . . . . . . . . . . . . .–0.5 V to 3.75 V I/O Tri-state Voltage Applied4, 5 . . . . . . . . . . . . . . .–0.5 V to 3.75 V . . . . . . . . . . . . .–0.5 V to 3.75 V Dedicated Input Voltage Applied4 . . . . . . . . . . . . .–0.5 V to 3.75 V . . . . . . . . . . . . .–0.5 V to 3.75 V Storage Temperature (Ambient). . . . . . . . . . . . . –55 °C to 125 °C. . . . . . . . . . . . –55 °C to 125 °C Junction Temperature (TJ) . . . . . . . . . . . . . . . . . –40 °C to 125 °C. . . . . . . . . . . . –40 °C to 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 –2 V to (VIHMAX + 2) volts is permitted for a duration of 100 MHz — 160 ps p-p fPFD < 100 MHz — 0.011 UIPP ps p-p fOUT > 100 MHz — 230 fOUT < 100 MHz — 0.12 UIPP Output Clock Cycle-to-cycle Jitter  (Fractional-N) fOUT > 100 MHz — 230 ps p-p tSPO Static Phase Offset Divider ratio = integer tW Output Clock Pulse Width At 90% or 10%3 Output Clock Period Jitter (Fractional-N) 2, 5 tLOCK PLL Lock-in Time tUNLOCK PLL Unlock Time fOUT < 100 MHz fPFD  20 MHz — 0.12 UIPP –120 120 ps 0.9 — ns — 15 ms — 50 ns — 1,000 ps p-p tIPJIT6 Input Clock Period Jitter fPFD < 20 MHz — 0.02 UIPP tHI Input Clock High Time 90% to 90% 0.5 — ns tLO Input Clock Low Time 10% to 10% 0.5 — ns 5 tSTABLE STANDBY High to PLL Stable — 15 ms tRST RST/RESETM Pulse Width 1 — ns tRSTREC RST Recovery Time 1 — ns tRST_DIV RESETC/D Pulse Width 10 — ns tRSTREC_DIV RESETC/D Recovery Time 1 — ns 10 — ns tROTATE-SETUP PHASESTEP Setup Time 3-31 DC and Switching Characteristics MachXO2 Family Data Sheet sysCLOCK PLL Timing (Continued) Over Recommended Operating Conditions Parameter tROTATE_WD Descriptions Conditions PHASESTEP Pulse Width Min. Max. Units 4 — VCO Cycles 1. Period jitter sample is taken over 10,000 samples of the primary PLL output with a clean reference clock. Cycle-to-cycle jitter is taken over 1000 cycles. Phase jitter is taken over 2000 cycles. All values per JESD65B. 2. Output clock is valid after tLOCK for PLL reset and dynamic delay adjustment. 3. Using LVDS output buffers. 4. CLKOS as compared to CLKOP output for one phase step at the maximum VCO frequency. See TN1199, MachXO2 sysCLOCK PLL Design and Usage Guide for more details. 5. At minimum fPFD. As the fPFD increases the time will decrease to approximately 60% the value listed. 6. Maximum allowed jitter on an input clock. PLL unlock may occur if the input jitter exceeds this specification. Jitter on the input clock may be transferred to the output clocks, resulting in jitter measurements outside the output specifications listed in this table. 7. Edge Duty Trim Accuracy is a percentage of the setting value. Settings available are 70 ps, 140 ps, and 280 ps in addition to the default value of none. 8. Jitter values measured with the internal oscillator operating. The jitter values will increase with loading of the PLD fabric and in the presence of SSO noise. 3-32 DC and Switching Characteristics MachXO2 Family Data Sheet MachXO2 Oscillator Output Frequency Symbol fMAX tDT Min. Typ. Max Units Oscillator Output Frequency (Commercial Grade Devices,  0 to 85°C) Parameter 125.685 133 140.315 MHz Oscillator Output Frequency (Industrial Grade Devices,  –40 °C to 100 °C) 124.355 133 141.645 MHz 43 50 57 % Output Clock Period Jitter 0.01 0.012 0.02 UIPP STDBY Low to Oscillator Stable 0.01 0.05 0.1 µs Output Clock Duty Cycle tOPJIT 1 tSTABLEOSC 1. Output Clock Period Jitter specified at 133 MHz. The values for lower frequencies will be smaller UIPP. The typical value for 133 MHz is 95 ps and for 2.08 MHz the typical value is 1.54 ns. MachXO2 Standby Mode Timing – HC/HE Devices Symbol tPWRDN Parameter Device Min. Typ. Max All — — 9 USERSTDBY High to Stop tWSTDBY USERSTDBY Low to Power Up ns LCMXO2-256 — µs LCMXO2-640 — µs LCMXO2-640U — µs LCMXO2-1200 tPWRUP Units 20 — 50 µs LCMXO2-1200U — µs LCMXO2-2000 — µs LCMXO2-2000U — µs LCMXO2-4000 — µs LCMXO2-7000 — µs USERSTDBY Pulse Width All 18 — — ns Typ. Max Units — 13 USERSTDBY Mode BG, POR tPWRUP tPWRDN USERSTDBY tWSTDBY MachXO2 Standby Mode Timing – ZE Devices Symbol tPWRDN Parameter USERSTDBY High to Stop Device Min. All — LCMXO2-256 — LCMXO2-640 tPWRUP USERSTDBY Low to Power Up LCMXO2-1200 — 20 — ns µs µs 50 µs LCMXO2-2000 — µs LCMXO2-4000 — µs LCMXO2-7000 — µs tWSTDBY USERSTDBY Pulse Width All 19 — — ns tBNDGAPSTBL USERSTDBY High to Bandgap Stable All — — 15 ns 3-33 DC and Switching Characteristics MachXO2 Family Data Sheet Flash Download Time1, 2 Symbol Parameter Device Typ. Units 0.6 ms LCMXO2-640 1.0 ms LCMXO2-640U 1.9 ms LCMXO2-256 tREFRESH POR to Device I/O Active LCMXO2-1200 1.9 ms LCMXO2-1200U 1.4 ms LCMXO2-2000 1.4 ms LCMXO2-2000U 2.4 ms LCMXO2-4000 2.4 ms LCMXO2-7000 3.8 ms 1. Assumes sysMEM EBR initialized to an all zero pattern if they are used. 2. The Flash download time is measured starting from the maximum voltage of POR trip point. JTAG Port Timing Specifications Symbol fMAX Parameter TCK clock frequency Min. Max. Units — 25 MHz 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 tBTCO TAP controller falling edge of clock to valid output — 10 ns 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 20 — 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 3-34 DC and Switching Characteristics MachXO2 Family Data Sheet Figure 3-12. 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 3-35 tBTUODIS Valid Data DC and Switching Characteristics MachXO2 Family Data Sheet sysCONFIG Port Timing Specifications Symbol Parameter Min. Max. Units All Configuration Modes tPRGM PROGRAMN low pulse accept 55 — ns tPRGMJ PROGRAMN low pulse rejection — 25 ns tINITL INITN low time LCMXO2-256 — 30 µs LCMXO2-640 — 35 µs LCMXO2-640U/ LCMXO2-1200 — 55 LCMXO2-1200U/ LCMXO2-2000 — 70 LCMXO2-2000U/ LCMXO2-4000 — 105 LCMXO2-7000 µs µs µs — 130 µs tDPPINIT PROGRAMN low to INITN low — 150 ns tDPPDONE PROGRAMN low to DONE low — 150 ns tIODISS PROGRAMN low to I/O disable — 120 ns fMAX CCLK clock frequency — 66 MHz tCCLKH CCLK clock pulse width high 7.5 — ns tCCLKL CCLK clock pulse width low 7.5 — ns tSTSU CCLK setup time 2 — ns tSTH CCLK hold time 0 — ns tSTCO CCLK falling edge to valid output — 10 ns tSTOZ CCLK falling edge to valid disable — 10 ns tSTOV CCLK falling edge to valid enable — 10 ns tSCS Chip select high time 25 — ns tSCSS Chip select setup time 3 — ns tSCSH Chip select hold time 3 — ns fMAX MCLK clock frequency — 133 MHz Slave SPI Master SPI tMCLKH MCLK clock pulse width high 3.75 — ns tMCLKL MCLK clock pulse width low 3.75 — ns tSTSU MCLK setup time 5 — ns tSTH MCLK hold time 1 — ns tCSSPI INITN high to chip select low 100 200 ns tMCLK INITN high to first MCLK edge 0.75 1 µs 3-36 DC and Switching Characteristics MachXO2 Family Data Sheet I2C Port Timing Specifications1, 2 Symbol fMAX Parameter Min. Max. Units — 400 kHz Min. Max. Units — 45 MHz Maximum SCL clock frequency 1. MachXO2 supports the following modes: • Standard-mode (Sm), with a bit rate up to 100 kbit/s (user and configuration mode) • Fast-mode (Fm), with a bit rate up to 400 kbit/s (user and configuration mode) 2. Refer to the I2C specification for timing requirements. SPI Port Timing Specifications1 Symbol fMAX Parameter Maximum SCK clock frequency 1. Applies to user mode only. For configuration mode timing specifications, refer to sysCONFIG Port Timing Specifications table in this data sheet. Switching Test Conditions Figure 3-13 shows the output test load used for AC testing. The specific values for resistance, capacitance, voltage, and other test conditions are shown in Table 3-5. Figure 3-13. Output Test Load, LVTTL and LVCMOS Standards VT R1 DUT Test Poi nt CL Table 3-5. Test Fixture Required Components, Non-Terminated Interfaces Test Condition LVTTL and LVCMOS settings (L -> H, H -> L) R1 CL  0pF Timing Ref. VT LVTTL, LVCMOS 3.3 = 1.5 V — LVCMOS 2.5 = VCCIO/2 — LVCMOS 1.8 = VCCIO/2 — LVCMOS 1.5 = VCCIO/2 — LVCMOS 1.2 = VCCIO/2 — LVTTL and LVCMOS 3.3 (Z -> H) 1.5 V VOL LVTTL and LVCMOS 3.3 (Z -> L) 1.5 V VOH Other LVCMOS (Z -> H) VCCIO/2 VOL Other LVCMOS (Z -> L) 188 0pF VCCIO/2 VOH LVTTL + LVCMOS (H -> Z) VOH – 0.15 V VOL LVTTL + LVCMOS (L -> Z) VOL – 0.15 V VOH Note: Output test conditions for all other interfaces are determined by the respective standards. 3-37 MachXO2 Family Data Sheet Pinout Information March 2017 Data Sheet DS1035 Signal Descriptions Signal Name I/O Descriptions General Purpose [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 PIO Group exists. When Edge is T (Top) or (Bottom), only need to specify Row Number. When Edge is L (Left) or R (Right), only need to specify Column Number. [A/B/C/D] indicates the PIO within the group to which the pad is connected. P[Edge] [Row/Column Number]_[A/B/C/D] I/O Some of these user-programmable pins are shared with special function pins. When not used as special function pins, these pins can be programmed as I/Os for user logic. During configuration of the user-programmable I/Os, the user has an option to tri-state the  I/Os and enable an internal pull-up, pull-down or buskeeper resistor. This option also applies to unused pins (or those not bonded to a package pin). The default during configuration is for user-programmable I/Os to be tri-stated with an internal pull-down resistor enabled. When the device is erased, I/Os will be tri-stated with an internal pull-down resistor enabled. Some pins, such as PROGRAMN and JTAG pins, default to tri-stated I/Os with pull-up resistors enabled when the device is erased. NC — No connect. GND — GND – Ground. Dedicated pins. It is recommended that all GNDs are tied together. For QFN 48 package, the exposed die pad is the device ground. VCC — VCC – The power supply pins for core logic. Dedicated pins. It is recommended that all VCCs are tied to the same supply. VCCIOx — VCCIO – The power supply pins for I/O Bank x. Dedicated pins. It is recommended that all VCCIOs located in the same bank are tied to the same supply. PLL and Clock Functions (Used as user-programmable I/O pins when not used for PLL or clock pins) [LOC]_GPLL[T, C]_IN — Reference Clock (PLL) input pads: [LOC] indicates location. Valid designations are L (Left PLL) and R (Right PLL). T = true and C = complement. [LOC]_GPLL[T, C]_FB — Optional Feedback (PLL) input pads: [LOC] indicates location. Valid designations are L (Left PLL) and R (Right PLL). T = true and C = complement. PCLK [n]_[2:0] — Primary Clock pads. One to three clock pads per side. Test and Programming (Dual function pins used for test access port and during sysCONFIG™) TMS I Test Mode Select input pin, used to control the 1149.1 state machine. TCK I Test Clock input pin, used to clock the 1149.1 state machine. TDI I Test Data input pin, used to load data into the device using an 1149.1 state machine. TDO O Output pin – Test Data output pin used to shift data out of the device using 1149.1. Optionally controls behavior of TDI, TDO, TMS, TCK. If the device is configured to use the JTAG pins (TDI, TDO, TMS, TCK) as general purpose I/O, then: JTAGENB I If JTAGENB is low: TDI, TDO, TMS and TCK can function a general purpose I/O. If JTAGENB is high: TDI, TDO, TMS and TCK function as JTAG pins. For more details, refer to TN1204, MachXO2 Programming and Configuration Usage Guide. Configuration (Dual function pins used during sysCONFIG) PROGRAMN I Initiates configuration sequence when asserted low. During configuration, or when reserved as PROGRAMN in user mode, this pin always has an active pull-up. © 2016 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 DS1035 Pinout Information_02.4 Pinout Information MachXO2 Family Data Sheet Signal Descriptions (Cont.) Signal Name I/O Descriptions INITN I/O Open Drain pin. Indicates the FPGA is ready to be configured. During configuration, or when reserved as INITn in user mode, this pin has an active pull-up. DONE I/O Open Drain pin. Indicates that the configuration sequence is complete, and the start-up sequence is in progress. During configuration, or when reserved as DONE in user mode, this pin has an active pull-up. MCLK/CCLK I/O Input Configuration Clock for configuring an FPGA in Slave SPI mode. Output Configuration Clock for configuring an FPGA in SPI and SPIm configuration modes. SN CSSPIN I I/O Slave SPI active low chip select input. Master SPI active low chip select output. SI/SPISI I/O Slave SPI serial data input and master SPI serial data output. SO/SPISO I/O Slave SPI serial data output and master SPI serial data input. SCL I/O Slave I2C clock input and master I2C clock output. SDA I/O Slave I2C data input and master I2C data output. 4-2 Pinout Information MachXO2 Family Data Sheet Pinout Information Summary MachXO2-256 MachXO2-640 MachXO2-640U 32 QFN1 48 QFN3 Bank 0 8 10 9 13 13 10 18 19 27 Bank 1 2 10 12 14 14 10 20 20 26 Bank 2 9 10 11 14 14 10 20 20 28 Bank 3 2 10 12 14 14 10 20 20 26 Bank 4 0 0 0 0 0 0 0 0 0 Bank 5 0 0 0 0 0 0 0 0 0 Total General Purpose Single Ended I/O 21 40 44 55 55 40 78 79 107 Bank 0 4 5 5 7 7 5 9 10 14 Bank 1 1 5 6 7 7 5 10 10 13 Bank 2 4 5 5 7 7 5 10 10 14 Bank 3 1 5 6 7 7 5 10 10 13 Bank 4 0 0 0 0 0 0 0 0 0 Bank 5 0 0 0 0 0 0 0 0 0 Total General Purpose Differential I/O 10 20 22 28 28 20 39 40 54 Dual Function I/O 22 25 27 29 29 25 29 29 33 0 0 0 0 0 0 0 0 7 Number of 7:1 or 8:1 Output Gearbox Available (Bank 0) 0 0 0 0 0 0 0 0 7 Number of 7:1 or 8:1 Input Gearbox Available (Bank 2) 0 0 0 0 0 0 0 0 7 0 0 0 0 0 0 0 0 2 Bank 0 2 2 2 2 2 2 2 2 3 Bank 1 1 1 2 2 2 1 2 2 3 Bank 2 2 2 2 2 2 2 2 2 3 Bank 3 1 1 2 2 2 1 2 2 3 Bank 4 0 0 0 0 0 0 0 0 0 Bank 5 0 0 0 0 0 0 0 0 0 VCC 2 2 2 2 2 2 2 2 4 GND2 2 1 8 8 8 1 8 10 12 NC 0 0 1 26 58 0 3 32 8 64 100 132 ucBGA TQFP csBGA 48 QFN3 100 132 TQFP csBGA 144 TQFP General Purpose I/O per Bank Differential I/O per Bank High-speed Differential I/O Bank 0 Gearboxes DQS Groups Bank 1 VCCIO Pins Reserved for Configuration 1 1 1 1 1 1 1 1 1 Total Count of Bonded Pins 32 49 64 100 132 49 100 132 144 1. Lattice recommends soldering the central thermal pad onto the top PCB ground for improved thermal resistance. 2. For 48 QFN package, exposed die pad is the device ground. 3. 48-pin QFN information is 'Advanced'. 4-3 Pinout Information MachXO2 Family Data Sheet MachXO2-1200 MachXO2-1200U 100 TQFP 132 csBGA 144 TQFP 25 WLCSP 32 QFN1 256 ftBGA General Purpose I/O per Bank Bank 0 18 25 27 11 9 50 Bank 1 21 26 26 0 2 52 Bank 2 20 28 28 7 9 52 Bank 3 20 25 26 0 2 16 Bank 4 0 0 0 0 0 16 Bank 5 0 0 0 0 0 20 Total General Purpose Single Ended I/O 79 104 107 18 22 206 Bank 0 9 13 14 5 4 25 Bank 1 10 13 13 0 1 26 Bank 2 10 14 14 2 4 26 Bank 3 10 12 13 0 1 8 Differential I/O per Bank Bank 4 0 0 0 0 0 8 Bank 5 0 0 0 0 0 10 Total General Purpose Differential I/O 39 52 54 7 10 103 Dual Function I/O 31 33 33 18 22 33 4 7 7 0 0 14 Number of 7:1 or 8:1 Output Gearbox Available (Bank 0) 4 7 7 0 0 14 Number of 7:1 or 8:1 Input Gearbox Available (Bank 2) 5 7 7 0 2 14 1 2 2 0 0 2 High-speed Differential I/O Bank 0 Gearboxes DQS Groups Bank 1 VCCIO Pins Bank 0 2 3 3 1 2 4 Bank 1 2 3 3 0 1 4 Bank 2 2 3 3 1 2 4 Bank 3 3 3 3 0 1 1 Bank 4 0 0 0 0 0 2 Bank 5 0 0 0 0 0 1 VCC 2 4 4 2 2 8 GND 8 10 12 2 2 24 NC 1 1 8 0 0 1 Reserved for Configuration 1 1 1 1 1 1 Total Count of Bonded Pins 100 132 144 25 32 256 1. Lattice recommends soldering the central thermal pad onto the top PCB ground for improved thermal resistance. 4-4 Pinout Information MachXO2 Family Data Sheet MachXO2-2000 49 WLCSP 100 TQFP 132 csBGA 144 TQFP MachXO2-2000U 256 caBGA 256 ftBGA 484 ftBGA General Purpose I/O per Bank Bank 0 19 18 25 27 50 50 70 Bank 1 0 21 26 28 52 52 68 Bank 2 13 20 28 28 52 52 72 Bank 3 0 6 7 8 16 16 24 Bank 4 0 6 8 10 16 16 16 Bank 5 6 8 10 10 20 20 28 Total General Purpose Single-Ended I/O 38 79 104 111 206 206 278 Differential I/O per Bank Bank 0 7 9 13 14 25 25 35 Bank 1 0 10 13 14 26 26 34 Bank 2 6 10 14 14 26 26 36 Bank 3 0 3 3 4 8 8 12 Bank 4 0 3 4 5 8 8 8 Bank 5 3 4 5 5 10 10 14 Total General Purpose Differential I/O 16 39 52 56 103 103 139 Dual Function I/O 24 31 33 33 33 33 37 5 4 8 9 14 14 18 Number of 7:1 or 8:1 Output Gearbox Available (Bank 0) 5 4 8 9 14 14 18 Number of 7:1 or 8:1 Input Gearbox Available (Bank 2) 6 10 14 14 14 14 18 0 1 2 2 2 2 2 Bank 0 2 2 3 3 4 4 10 Bank 1 0 2 3 3 4 4 10 Bank 2 1 2 3 3 4 4 10 Bank 3 0 1 1 1 1 1 3 Bank 4 0 1 1 1 2 2 4 Bank 5 1 1 1 1 1 1 3 VCC 2 2 4 4 8 8 12 GND 4 8 10 12 24 24 48 High-speed Differential I/O Bank 0 Gearboxes DQS Groups Bank 1 VCCIO Pins NC 0 1 1 4 1 1 105 Reserved for Configuration 1 1 1 1 v 1 1 Total Count of Bonded Pins 39 100 132 144 256 256 484 4-5 Pinout Information MachXO2 Family Data Sheet MachXO2-4000 84 QFN 132 csBGA 144 TQFP 184 csBGA 256 caBGA 256 ftBGA 332 caBGA 484 fpBGA Bank 0 27 25 27 37 50 50 68 70 Bank 1 10 26 29 37 52 52 68 68 Bank 2 22 28 29 39 52 52 70 72 Bank 3 0 7 9 10 16 16 24 24 Bank 4 9 8 10 12 16 16 16 16 Bank 5 0 10 10 15 20 20 28 28 Total General Purpose Single Ended I/O 68 104 114 150 206 206 274 278 General Purpose I/O per Bank Differential I/O per Bank Bank 0 13 13 14 18 25 25 34 35 Bank 1 4 13 14 18 26 26 34 34 Bank 2 11 14 14 19 26 26 35 36 Bank 3 0 3 4 4 8 8 12 12 Bank 4 4 4 5 6 8 8 8 8 Bank 5 0 5 5 7 10 10 14 14 Total General Purpose Differential I/O 32 52 56 72 103 103 137 139 Dual Function I/O 28 37 37 37 37 37 37 37 8 8 9 8 18 18 18 18 Number of 7:1 or 8:1 Output Gearbox Available (Bank 0) 8 8 9 9 18 18 18 18 Number of 7:1 or 8:1 Input Gearbox Available (Bank 2) 11 14 14 12 18 18 18 18 1 2 2 2 2 2 2 2 Bank 0 3 3 3 3 4 4 4 10 Bank 1 1 3 3 3 4 4 4 10 Bank 2 2 3 3 3 4 4 4 10 Bank 3 1 1 1 1 1 1 2 3 Bank 4 1 1 1 1 2 2 1 4 Bank 5 1 1 1 1 1 1 2 3 VCC 4 4 4 4 8 8 8 12 GND 4 10 12 16 24 24 27 48 NC 1 1 1 1 1 1 5 105 Reserved for configuration 1 1 1 1 1 1 1 1 Total Count of Bonded Pins 84 132 144 184 256 256 332 484 High-speed Differential I/O Bank 0 Gearboxes DQS Groups Bank 1 VCCIO Pins 4-6 Pinout Information MachXO2 Family Data Sheet MachXO2-7000 144 TQFP 256 caBGA 256 ftBGA 332 caBGA 400 caBGA 484 fpBGA General Purpose I/O per Bank Bank 0 27 50 50 68 83 82 Bank 1 29 52 52 70 84 84 Bank 2 29 52 52 70 84 84 Bank 3 9 16 16 24 28 28 Bank 4 10 16 16 16 24 24 Bank 5 10 20 20 30 32 32 Total General Purpose Single Ended I/O 114 206 206 278 335 334 Bank 0 14 25 25 34 42 41 Bank 1 14 26 26 35 42 42 Bank 2 14 26 26 35 42 42 Bank 3 4 8 8 12 14 14 Differential I/O per Bank Bank 4 5 8 8 8 12 12 Bank 5 5 10 10 15 16 16 Total General Purpose Differential I/O 56 103 103 139 168 167 Dual Function I/O 37 37 37 37 37 37 9 20 20 21 21 21 Number of 7:1 or 8:1 Output Gearbox Available (Bank 0) 9 20 20 21 21 21 Number of 7:1 or 8:1 Input Gearbox Available (Bank 2) 14 20 20 21 21 21 2 2 2 2 2 2 High-speed Differential I/O Bank 0 Gearboxes DQS Groups Bank 1 VCCIO Pins Bank 0 3 4 4 4 5 10 Bank 1 3 4 4 4 5 10 Bank 2 3 4 4 4 5 10 Bank 3 1 1 1 2 2 3 Bank 4 1 2 2 1 2 4 Bank 5 1 1 1 2 2 3 VCC 4 8 8 8 10 12 GND 12 24 24 27 33 48 NC 1 1 1 1 0 49 Reserved for Configuration 1 1 1 1 1 1 Total Count of Bonded Pins 144 256 256 332 400 484 4-7 Pinout Information MachXO2 Family Data Sheet For Further Information For further information regarding logic signal connections for various packages please refer to the MachXO2 Device Pinout Files. Thermal Management 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. Users 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 • TN1198, Power Estimation and Management for MachXO2 Devices • The Power Calculator tool is included with the Lattice design tools, or as a standalone download from www.latticesemi.com/software 4-8 MachXO2 Family Data Sheet Ordering Information March 2017 Data Sheet DS1035 MachXO2 Part Number Description LCMXO2 – XXXX X X X – X XXXXXX X XX XX Device Family MachXO2 PLD Device Status Blank = Production Device ES = Engineering Sample R1 = Production Release 1 Device 1K = WLCSP Package, 1,000 parts per reel Logic Capacity 256 = 256 LUTs 640 = 640 LUTs 1200 = 1280 LUTs 2000 = 2112 LUTs 4000 = 4320 LUTs 7000 = 6864 LUTs Shipping Method Blank = Trays TR = Tape and Reel Grade C = Commercial I = Industrial I/O Count Blank = Standard Device U = Ultra High I/O Device Package Power/Performance Z = Low Power H = High Performance UWG25 = 25-Ball Halogen-Free WLCSP (0.4 mm Pitch) SG32 = 32-Pin Halogen-Free QFN (0.5 mm Pitch) SG48 = 48-Pin Halogen-Free QFN (0.5 mm Pitch) UWG49 = 49-ball Halogen-Free WLCSP (0.4 mm Pitch) UMG64 = 64-Ball Halogen-Free ucBGA (0.4 mm Pitch) QN84 = 84-Pin Halogen-Free QFN (0.5 mm Pitch) TG100 = 100-Pin Halogen-Free TQFP TG144 = 144-Pin Halogen-Free TQFP MG132 = 132-Ball Halogen-Free csBGA (0.5 mm Pitch) MG184 = 184-Ball Halogen-Free csBGA (0.5 mm Pitch) BG256 = 256-Ball Halogen-Free caBGA (0.8 mm Pitch) FTG256 = 256-Ball Halogen-Free ftBGA (1.0 mm Pitch) BG332 = 332-Ball Halogen-Free caBGA (0.8 mm Pitch) FG484 = 484-Ball Halogen-Free fpBGA (1.0 mm Pitch) Supply Voltage C = 2.5 V / 3.3 V E = 1.2 V Speed 1 = Slowest 2 3 = Fastest 4 = Slowest 5 6 = Fastest Low Power High Performance * 48-pin QFN information is 'Advanced'. © 2016 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 DS1035 Order Info_02.7 Ordering Information MachXO2 Family Data Sheet Ordering Information MachXO2 devices have top-side markings, for commercial and industrial grades, as shown below: LCMXO2 256ZE 1UG64C Datecode LCMXO2-1200ZE 1TG100C Datecode Notes: 1. Markings are abbreviated for small packages. 2. See PCN 05A-12 for information regarding a change to the top-side mark logo. 5-2 Ordering Information MachXO2 Family Data Sheet Ultra Low Power Commercial Grade Devices, Halogen Free (RoHS) Packaging Part Number LUTs Supply Voltage Grade Package Leads Temp. LCMXO2-256ZE-1SG32C 256 1.2 V –1 Halogen-Free QFN 32 COM LCMXO2-256ZE-2SG32C 256 1.2 V –2 Halogen-Free QFN 32 COM LCMXO2-256ZE-3SG32C 256 1.2 V –3 Halogen-Free QFN 32 COM LCMXO2-256ZE-1UMG64C 256 1.2 V –1 Halogen-Free ucBGA 64 COM LCMXO2-256ZE-2UMG64C 256 1.2 V –2 Halogen-Free ucBGA 64 COM LCMXO2-256ZE-3UMG64C 256 1.2 V –3 Halogen-Free ucBGA 64 COM LCMXO2-256ZE-1TG100C 256 1.2 V –1 Halogen-Free TQFP 100 COM LCMXO2-256ZE-2TG100C 256 1.2 V –2 Halogen-Free TQFP 100 COM LCMXO2-256ZE-3TG100C 256 1.2 V –3 Halogen-Free TQFP 100 COM LCMXO2-256ZE-1MG132C 256 1.2 V –1 Halogen-Free csBGA 132 COM LCMXO2-256ZE-2MG132C 256 1.2 V –2 Halogen-Free csBGA 132 COM LCMXO2-256ZE-3MG132C 256 1.2 V –3 Halogen-Free csBGA 132 COM LUTs Supply Voltage Grade Leads Temp. LCMXO2-640ZE-1TG100C Part Number 640 1.2 V –1 Halogen-Free TQFP 100 COM LCMXO2-640ZE-2TG100C 640 1.2 V –2 Halogen-Free TQFP 100 COM LCMXO2-640ZE-3TG100C 640 1.2 V –3 Halogen-Free TQFP 100 COM LCMXO2-640ZE-1MG132C 640 1.2 V –1 Halogen-Free csBGA 132 COM LCMXO2-640ZE-2MG132C 640 1.2 V –2 Halogen-Free csBGA 132 COM LCMXO2-640ZE-3MG132C 640 1.2 V –3 Halogen-Free csBGA 132 COM LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200ZE-1SG32C 1280 1.2 V –1 Halogen-Free QFN 32 COM LCMXO2-1200ZE-2SG32C 1280 1.2 V –2 Halogen-Free QFN 32 COM Part Number Package Package LCMXO2-1200ZE-3SG32C 1280 1.2 V –3 Halogen-Free QFN 32 COM LCMXO2-1200ZE-1TG100C 1280 1.2 V –1 Halogen-Free TQFP 100 COM LCMXO2-1200ZE-2TG100C 1280 1.2 V –2 Halogen-Free TQFP 100 COM LCMXO2-1200ZE-3TG100C 1280 1.2 V –3 Halogen-Free TQFP 100 COM LCMXO2-1200ZE-1MG132C 1280 1.2 V –1 Halogen-Free csBGA 132 COM LCMXO2-1200ZE-2MG132C 1280 1.2 V –2 Halogen-Free csBGA 132 COM LCMXO2-1200ZE-3MG132C 1280 1.2 V –3 Halogen-Free csBGA 132 COM LCMXO2-1200ZE-1TG144C 1280 1.2 V –1 Halogen-Free TQFP 144 COM LCMXO2-1200ZE-2TG144C 1280 1.2 V –2 Halogen-Free TQFP 144 COM LCMXO2-1200ZE-3TG144C 1280 1.2 V –3 Halogen-Free TQFP 144 COM 5-3 Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000ZE-1TG100C Part Number 2112 1.2 V –1 Halogen-Free TQFP Package 100 COM LCMXO2-2000ZE-2TG100C 2112 1.2 V –2 Halogen-Free TQFP 100 COM LCMXO2-2000ZE-3TG100C 2112 1.2 V –3 Halogen-Free TQFP 100 COM LCMXO2-2000ZE-1MG132C 2112 1.2 V –1 Halogen-Free csBGA 132 COM LCMXO2-2000ZE-2MG132C 2112 1.2 V –2 Halogen-Free csBGA 132 COM LCMXO2-2000ZE-3MG132C 2112 1.2 V –3 Halogen-Free csBGA 132 COM LCMXO2-2000ZE-1TG144C 2112 1.2 V –1 Halogen-Free TQFP 144 COM LCMXO2-2000ZE-2TG144C 2112 1.2 V –2 Halogen-Free TQFP 144 COM LCMXO2-2000ZE-3TG144C 2112 1.2 V –3 Halogen-Free TQFP 144 COM LCMXO2-2000ZE-1BG256C 2112 1.2 V –1 Halogen-Free caBGA 256 COM LCMXO2-2000ZE-2BG256C 2112 1.2 V –2 Halogen-Free caBGA 256 COM LCMXO2-2000ZE-3BG256C 2112 1.2 V –3 Halogen-Free caBGA 256 COM LCMXO2-2000ZE-1FTG256C 2112 1.2 V –1 Halogen-Free ftBGA 256 COM LCMXO2-2000ZE-2FTG256C 2112 1.2 V –2 Halogen-Free ftBGA 256 COM LCMXO2-2000ZE-3FTG256C 2112 1.2 V –3 Halogen-Free ftBGA 256 COM LUTs Supply Voltage Grade Leads Temp. Part Number Package LCMXO2-4000ZE-1QN84C 4320 1.2 V –1 Halogen-Free QFN 84 COM LCMXO2-4000ZE-2QN84C 4320 1.2 V –2 Halogen-Free QFN 84 COM LCMXO2-4000ZE-3QN84C 4320 1.2 V –3 Halogen-Free QFN 84 COM LCMXO2-4000ZE-1MG132C 4320 1.2 V –1 Halogen-Free csBGA 132 COM LCMXO2-4000ZE-2MG132C 4320 1.2 V –2 Halogen-Free csBGA 132 COM LCMXO2-4000ZE-3MG132C 4320 1.2 V –3 Halogen-Free csBGA 132 COM LCMXO2-4000ZE-1TG144C 4320 1.2 V –1 Halogen-Free TQFP 144 COM LCMXO2-4000ZE-2TG144C 4320 1.2 V –2 Halogen-Free TQFP 144 COM LCMXO2-4000ZE-3TG144C 4320 1.2 V –3 Halogen-Free TQFP 144 COM LCMXO2-4000ZE-1BG256C 4320 1.2 V –1 Halogen-Free caBGA 256 COM LCMXO2-4000ZE-2BG256C 4320 1.2 V –2 Halogen-Free caBGA 256 COM LCMXO2-4000ZE-3BG256C 4320 1.2 V –3 Halogen-Free caBGA 256 COM LCMXO2-4000ZE-1FTG256C 4320 1.2 V –1 Halogen-Free ftBGA 256 COM LCMXO2-4000ZE-2FTG256C 4320 1.2 V –2 Halogen-Free ftBGA 256 COM LCMXO2-4000ZE-3FTG256C 4320 1.2 V –3 Halogen-Free ftBGA 256 COM LCMXO2-4000ZE-1BG332C 4320 1.2 V –1 Halogen-Free caBGA 332 COM LCMXO2-4000ZE-2BG332C 4320 1.2 V –2 Halogen-Free caBGA 332 COM LCMXO2-4000ZE-3BG332C 4320 1.2 V –3 Halogen-Free caBGA 332 COM LCMXO2-4000ZE-1FG484C 4320 1.2 V –1 Halogen-Free fpBGA 484 COM LCMXO2-4000ZE-2FG484C 4320 1.2 V –2 Halogen-Free fpBGA 484 COM LCMXO2-4000ZE-3FG484C 4320 1.2 V –3 Halogen-Free fpBGA 484 COM 5-4 Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-7000ZE-1TG144C Part Number 6864 1.2 V –1 Halogen-Free TQFP Package 144 COM LCMXO2-7000ZE-2TG144C 6864 1.2 V –2 Halogen-Free TQFP 144 COM LCMXO2-7000ZE-3TG144C 6864 1.2 V –3 Halogen-Free TQFP 144 COM LCMXO2-7000ZE-1BG256C 6864 1.2 V –1 Halogen-Free caBGA 256 COM LCMXO2-7000ZE-2BG256C 6864 1.2 V –2 Halogen-Free caBGA 256 COM LCMXO2-7000ZE-3BG256C 6864 1.2 V –3 Halogen-Free caBGA 256 COM LCMXO2-7000ZE-1FTG256C 6864 1.2 V –1 Halogen-Free ftBGA 256 COM LCMXO2-7000ZE-2FTG256C 6864 1.2 V –2 Halogen-Free ftBGA 256 COM LCMXO2-7000ZE-3FTG256C 6864 1.2 V –3 Halogen-Free ftBGA 256 COM LCMXO2-7000ZE-1BG332C 6864 1.2 V –1 Halogen-Free caBGA 332 COM LCMXO2-7000ZE-2BG332C 6864 1.2 V –2 Halogen-Free caBGA 332 COM LCMXO2-7000ZE-3BG332C 6864 1.2 V –3 Halogen-Free caBGA 332 COM LCMXO2-7000ZE-1FG484C 6864 1.2 V –1 Halogen-Free fpBGA 484 COM LCMXO2-7000ZE-2FG484C 6864 1.2 V –2 Halogen-Free fpBGA 484 COM LCMXO2-7000ZE-3FG484C 6864 1.2 V –3 Halogen-Free fpBGA 484 COM Part Number LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200ZE-1TG100CR11 1280 1.2 V –1 Halogen-Free TQFP 100 COM 1 LCMXO2-1200ZE-2TG100CR1 1280 1.2 V –2 Halogen-Free TQFP 100 COM LCMXO2-1200ZE-3TG100CR11 1280 1.2 V –3 Halogen-Free TQFP 100 COM 1 1280 1.2 V –1 Halogen-Free csBGA 132 COM LCMXO2-1200ZE-2MG132CR11 1280 1.2 V –2 Halogen-Free csBGA 132 COM 1 LCMXO2-1200ZE-1MG132CR1 LCMXO2-1200ZE-3MG132CR1 Package 1280 1.2 V –3 Halogen-Free csBGA 132 COM LCMXO2-1200ZE-1TG144CR11 1280 1.2 V –1 Halogen-Free TQFP 144 COM LCMXO2-1200ZE-2TG144CR11 1280 1.2 V –2 Halogen-Free TQFP 144 COM LCMXO2-1200ZE-3TG144CR11 1280 1.2 V –3 Halogen-Free TQFP 144 COM 1. Specifications for the “LCMXO2-1200ZE-speed package CR1” are the same as the “LCMXO2-1200ZE-speed package C” devices respectively, except as specified in the R1 Device Specifications section of this data sheet. 5-5 Ordering Information MachXO2 Family Data Sheet High-Performance Commercial Grade Devices with Voltage Regulator, Halogen Free (RoHS) Packaging LUTs Supply Voltage Grade Leads Temp. LCMXO2-256HC-4SG32C Part Number 256 2.5 V / 3.3 V –4 Halogen-Free QFN Package 32 COM LCMXO2-256HC-5SG32C 256 2.5 V / 3.3 V –5 Halogen-Free QFN 32 COM LCMXO2-256HC-6SG32C 256 2.5 V / 3.3 V –6 Halogen-Free QFN 32 COM LCMXO2-256HC-4SG48C 256 2.5 V / 3.3 V –4 Halogen-Free QFN 48 COM LCMXO2-256HC-5SG48C 256 2.5 V / 3.3 V –5 Halogen-Free QFN 48 COM LCMXO2-256HC-6SG48C 256 2.5 V / 3.3 V –6 Halogen-Free QFN 48 COM LCMXO2-256HC-4UMG64C 256 2.5 V / 3.3 V –4 Halogen-Free ucBGA 64 COM LCMXO2-256HC-5UMG64C 256 2.5 V / 3.3 V –5 Halogen-Free ucBGA 64 COM LCMXO2-256HC-6UMG64C 256 2.5 V / 3.3 V –6 Halogen-Free ucBGA 64 COM LCMXO2-256HC-4TG100C 256 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 COM LCMXO2-256HC-5TG100C 256 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 COM LCMXO2-256HC-6TG100C 256 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 COM LCMXO2-256HC-4MG132C 256 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 COM LCMXO2-256HC-5MG132C 256 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 COM LCMXO2-256HC-6MG132C 256 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 COM LUTs Supply Voltage Grade Leads Temp. LCMXO2-640HC-4SG48C Part Number 640 2.5 V / 3.3 V –4 Halogen-Free QFN 48 COM LCMXO2-640HC-5SG48C 640 2.5 V / 3.3 V –5 Halogen-Free QFN 48 COM LCMXO2-640HC-6SG48C 640 2.5 V / 3.3 V –6 Halogen-Free QFN 48 COM LCMXO2-640HC-4TG100C 640 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 COM LCMXO2-640HC-5TG100C 640 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 COM LCMXO2-640HC-6TG100C 640 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 COM LCMXO2-640HC-4MG132C 640 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 COM LCMXO2-640HC-5MG132C 640 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 COM LCMXO2-640HC-6MG132C 640 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 COM Part Number Package LUTs Supply Voltage Grade Leads Temp. LCMXO2-640UHC-4TG144C 640 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 COM LCMXO2-640UHC-5TG144C 640 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 COM LCMXO2-640UHC-6TG144C 640 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 COM 5-6 Package Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200HC-4SG32C Part Number 1280 2.5 V / 3.3 V –4 Halogen-Free QFN Package 32 COM LCMXO2-1200HC-5SG32C 1280 2.5 V / 3.3 V –5 Halogen-Free QFN 32 COM LCMXO2-1200HC-6SG32C 1280 2.5 V / 3.3 V –6 Halogen-Free QFN 32 COM LCMXO2-1200HC-4TG100C 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 COM LCMXO2-1200HC-5TG100C 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 COM LCMXO2-1200HC-6TG100C 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 COM LCMXO2-1200HC-4MG132C 1280 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 COM LCMXO2-1200HC-5MG132C 1280 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 COM LCMXO2-1200HC-6MG132C 1280 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 COM LCMXO2-1200HC-4TG144C 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 COM LCMXO2-1200HC-5TG144C 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 COM LCMXO2-1200HC-6TG144C 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 COM LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200UHC-4FTG256C Part Number 1280 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 COM LCMXO2-1200UHC-5FTG256C 1280 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 COM LCMXO2-1200UHC-6FTG256C 1280 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 COM Part Number Package LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000HC-4TG100C 2112 2.5 V / 3.3 V –4 Halogen-Free TQFP Package 100 COM LCMXO2-2000HC-5TG100C 2112 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 COM LCMXO2-2000HC-6TG100C 2112 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 COM LCMXO2-2000HC-4MG132C 2112 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 COM LCMXO2-2000HC-5MG132C 2112 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 COM LCMXO2-2000HC-6MG132C 2112 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 COM LCMXO2-2000HC-4TG144C 2112 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 COM LCMXO2-2000HC-5TG144C 2112 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 COM LCMXO2-2000HC-6TG144C 2112 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 COM LCMXO2-2000HC-4BG256C 2112 2.5 V / 3.3 V –4 Halogen-Free caBGA 256 COM LCMXO2-2000HC-5BG256C 2112 2.5 V / 3.3 V –5 Halogen-Free caBGA 256 COM LCMXO2-2000HC-6BG256C 2112 2.5 V / 3.3 V –6 Halogen-Free caBGA 256 COM LCMXO2-2000HC-4FTG256C 2112 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 COM LCMXO2-2000HC-5FTG256C 2112 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 COM LCMXO2-2000HC-6FTG256C 2112 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 COM 5-7 Ordering Information MachXO2 Family Data Sheet Part Number LUTs Supply Voltage Grade LCMXO2-2000UHC-4FG484C 2112 2.5 V / 3.3 V –4 LCMXO2-2000UHC-5FG484C 2112 2.5 V / 3.3 V –5 LCMXO2-2000UHC-6FG484C 2112 2.5 V / 3.3 V –6 Leads Temp. Halogen-Free fpBGA 484 COM Halogen-Free fpBGA 484 COM Halogen-Free fpBGA 484 COM LUTs Supply Voltage Grade Leads Temp. LCMXO2-4000HC-4QN84C 4320 2.5 V / 3.3 V –4 LCMXO2-4000HC-5QN84C 4320 2.5 V / 3.3 V –5 Halogen-Free QFN 84 COM Halogen-Free QFN 84 LCMXO2-4000HC-6QN84C 4320 2.5 V / 3.3 V COM –6 Halogen-Free QFN 84 COM LCMXO2-4000HC-4MG132C 4320 LCMXO2-4000HC-5MG132C 4320 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 COM 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 COM LCMXO2-4000HC-6MG132C 4320 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 COM LCMXO2-4000HC-4TG144C 4320 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 COM LCMXO2-4000HC-5TG144C 4320 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 COM LCMXO2-4000HC-6TG144C 4320 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 COM LCMXO2-4000HC-4BG256C 4320 2.5 V / 3.3 V –4 Halogen-Free caBGA 256 COM LCMXO2-4000HC-5BG256C 4320 2.5 V / 3.3 V –5 Halogen-Free caBGA 256 COM Part Number Package Package LCMXO2-4000HC-6BG256C 4320 2.5 V / 3.3 V –6 Halogen-Free caBGA 256 COM LCMXO2-4000HC-4FTG256C 4320 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 COM LCMXO2-4000HC-5FTG256C 4320 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 COM LCMXO2-4000HC-6FTG256C 4320 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 COM LCMXO2-4000HC-4BG332C 4320 2.5 V / 3.3 V –4 Halogen-Free caBGA 332 COM LCMXO2-4000HC-5BG332C 4320 2.5 V / 3.3 V –5 Halogen-Free caBGA 332 COM LCMXO2-4000HC-6BG332C 4320 2.5 V / 3.3 V –6 Halogen-Free caBGA 332 COM LCMXO2-4000HC-4FG484C 4320 2.5 V / 3.3 V –4 Halogen-Free fpBGA 484 COM LCMXO2-4000HC-5FG484C 4320 2.5 V / 3.3 V –5 Halogen-Free fpBGA 484 COM LCMXO2-4000HC-6FG484C 4320 2.5 V / 3.3 V –6 Halogen-Free fpBGA 484 COM 5-8 Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-7000HC-4TG144C Part Number 6864 2.5 V / 3.3 V –4 Halogen-Free TQFP Package 144 COM LCMXO2-7000HC-5TG144C 6864 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 COM LCMXO2-7000HC-6TG144C 6864 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 COM LCMXO2-7000HC-4BG256C 6864 2.5 V / 3.3 V –4 Halogen-Free caBGA 256 COM LCMXO2-7000HC-5BG256C 6864 2.5 V / 3.3 V –5 Halogen-Free caBGA 256 COM LCMXO2-7000HC-6BG256C 6864 2.5 V / 3.3 V –6 Halogen-Free caBGA 256 COM LCMXO2-7000HC-4FTG256C 6864 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 COM LCMXO2-7000HC-5FTG256C 6864 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 COM LCMXO2-7000HC-6FTG256C 6864 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 COM LCMXO2-7000HC-4BG332C 6864 2.5 V / 3.3 V –4 Halogen-Free caBGA 332 COM LCMXO2-7000HC-5BG332C 6864 2.5 V / 3.3 V –5 Halogen-Free caBGA 332 COM LCMXO2-7000HC-6BG332C 6864 2.5 V / 3.3 V –6 Halogen-Free caBGA 332 COM LCMXO2-7000HC-4FG400C 6864 2.5 V / 3.3 V –4 Halogen-Free fpBGA 400 COM LCMXO2-7000HC-5FG400C 6864 2.5 V / 3.3 V –5 Halogen-Free fpBGA 400 COM LCMXO2-7000HC-6FG400C 6864 2.5 V / 3.3 V –6 Halogen-Free fpBGA 400 COM LCMXO2-7000HC-4FG484C 6864 2.5 V / 3.3 V –4 Halogen-Free fpBGA 484 COM LCMXO2-7000HC-5FG484C 6864 2.5 V / 3.3 V –5 Halogen-Free fpBGA 484 COM LCMXO2-7000HC-6FG484C 6864 2.5 V / 3.3 V –6 Halogen-Free fpBGA 484 COM Leads Temp. Part Number LUTs Supply Voltage Grade LCMXO2-1200HC-4TG100CR11 Package 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 COM LCMXO2-1200HC-5TG100CR11 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 COM LCMXO2-1200HC-6TG100CR11 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 COM 1 LCMXO2-1200HC-4MG132CR1 1280 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 COM LCMXO2-1200HC-5MG132CR11 1280 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 COM LCMXO2-1200HC-6MG132CR11 1280 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 COM 1 LCMXO2-1200HC-4TG144CR1 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 COM LCMXO2-1200HC-5TG144CR11 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 COM LCMXO2-1200HC-6TG144CR11 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 COM 1. Specifications for the “LCMXO2-1200HC-speed package CR1” are the same as the “LCMXO2-1200HC-speed package C” devices respectively, except as specified in the R1 Device Specifications section of this data sheet. 5-9 Ordering Information MachXO2 Family Data Sheet High-Performance Commercial Grade Devices without Voltage Regulator, Halogen Free (RoHS) Packaging LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000HE-4TG100C Part Number 2112 1.2 V –4 Halogen-Free TQFP 100 COM LCMXO2-2000HE-5TG100C 2112 1.2 V –5 Halogen-Free TQFP 100 COM LCMXO2-2000HE-6TG100C 2112 1.2 V –6 Halogen-Free TQFP 100 COM LCMXO2-2000HE-4TG144C 2112 1.2 V –4 Halogen-Free TQFP 144 COM LCMXO2-2000HE-5TG144C 2112 1.2 V –5 Halogen-Free TQFP 144 COM LCMXO2-2000HE-6TG144C 2112 1.2 V –6 Halogen-Free TQFP 144 COM LCMXO2-2000HE-4MG132C 2112 1.2 V –4 Halogen-Free csBGA 132 COM LCMXO2-2000HE-5MG132C 2112 1.2 V –5 Halogen-Free csBGA 132 COM LCMXO2-2000HE-6MG132C 2112 1.2 V –6 Halogen-Free csBGA 132 COM LCMXO2-2000HE-4BG256C 2112 1.2 V –4 Halogen-Free caBGA 256 COM LCMXO2-2000HE-5BG256C 2112 1.2 V –5 Halogen-Free caBGA 256 COM LCMXO2-2000HE-6BG256C 2112 1.2 V –6 Halogen-Free caBGA 256 COM LCMXO2-2000HE-4FTG256C 2112 1.2 V –4 Halogen-Free ftBGA 256 COM LCMXO2-2000HE-5FTG256C 2112 1.2 V –5 Halogen-Free ftBGA 256 COM LCMXO2-2000HE-6FTG256C 2112 1.2 V –6 Halogen-Free ftBGA 256 COM Part Number Package LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000UHE-4FG484C 2112 1.2 V –4 Halogen-Free fpBGA 484 COM LCMXO2-2000UHE-5FG484C 2112 1.2 V –5 Halogen-Free fpBGA 484 COM LCMXO2-2000UHE-6FG484C 2112 1.2 V –6 Halogen-Free fpBGA 484 COM Part Number Package LUTs Supply Voltage Grade Leads Temp. LCMXO2-4000HE-4TG144C 4320 1.2 V –4 Halogen-Free TQFP 144 COM LCMXO2-4000HE-5TG144C 4320 1.2 V –5 Halogen-Free TQFP 144 COM LCMXO2-4000HE-6TG144C 4320 1.2 V –6 Halogen-Free TQFP 144 COM LCMXO2-4000HE-4MG132C 4320 1.2 V –4 Halogen-Free csBGA 132 COM LCMXO2-4000HE-5MG132C 4320 1.2 V –5 Halogen-Free csBGA 132 COM LCMXO2-4000HE-6MG132C 4320 1.2 V –6 Halogen-Free csBGA 132 COM LCMXO2-4000HE-4BG256C 4320 1.2 V –4 Halogen-Free caBGA 256 COM LCMXO2-4000HE-4MG184C 4320 1.2 V –4 Halogen-Free csBGA 184 COM LCMXO2-4000HE-5MG184C 4320 1.2 V –5 Halogen-Free csBGA 184 COM LCMXO2-4000HE-6MG184C 4320 1.2 V –6 Halogen-Free csBGA 184 COM LCMXO2-4000HE-5BG256C 4320 1.2 V –5 Halogen-Free caBGA 256 COM LCMXO2-4000HE-6BG256C 4320 1.2 V –6 Halogen-Free caBGA 256 COM LCMXO2-4000HE-4FTG256C 4320 1.2 V –4 Halogen-Free ftBGA 256 COM LCMXO2-4000HE-5FTG256C 4320 1.2 V –5 Halogen-Free ftBGA 256 COM LCMXO2-4000HE-6FTG256C 4320 1.2 V –6 Halogen-Free ftBGA 256 COM LCMXO2-4000HE-4BG332C 4320 1.2 V –4 Halogen-Free caBGA 332 COM LCMXO2-4000HE-5BG332C 4320 1.2 V –5 Halogen-Free caBGA 332 COM 5-10 Package Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-4000HE-6BG332C Part Number 4320 1.2 V –6 Halogen-Free caBGA 332 COM LCMXO2-4000HE-4FG484C 4320 1.2 V –4 Halogen-Free fpBGA 484 COM LCMXO2-4000HE-5FG484C 4320 1.2 V –5 Halogen-Free fpBGA 484 COM LCMXO2-4000HE-6FG484C 4320 1.2 V –6 Halogen-Free fpBGA 484 COM LUTs Supply Voltage Grade Leads Temp. Part Number Package Package LCMXO2-7000HE-4TG144C 6864 1.2 V –4 Halogen-Free TQFP 144 COM LCMXO2-7000HE-5TG144C 6864 1.2 V –5 Halogen-Free TQFP 144 COM LCMXO2-7000HE-6TG144C 6864 1.2 V –6 Halogen-Free TQFP 144 COM LCMXO2-7000HE-4BG256C 6864 1.2 V –4 Halogen-Free caBGA 256 COM LCMXO2-7000HE-5BG256C 6864 1.2 V –5 Halogen-Free caBGA 256 COM LCMXO2-7000HE-6BG256C 6864 1.2 V –6 Halogen-Free caBGA 256 COM LCMXO2-7000HE-4FTG256C 6864 1.2 V –4 Halogen-Free ftBGA 256 COM LCMXO2-7000HE-5FTG256C 6864 1.2 V –5 Halogen-Free ftBGA 256 COM LCMXO2-7000HE-6FTG256C 6864 1.2 V –6 Halogen-Free ftBGA 256 COM LCMXO2-7000HE-4BG332C 6864 1.2 V –4 Halogen-Free caBGA 332 COM LCMXO2-7000HE-5BG332C 6864 1.2 V –5 Halogen-Free caBGA 332 COM LCMXO2-7000HE-6BG332C 6864 1.2 V –6 Halogen-Free caBGA 332 COM LCMXO2-7000HE-4FG484C 6864 1.2 V –4 Halogen-Free fpBGA 484 COM LCMXO2-7000HE-5FG484C 6864 1.2 V –5 Halogen-Free fpBGA 484 COM LCMXO2-7000HE-6FG484C 6864 1.2 V –6 Halogen-Free fpBGA 484 COM 5-11 Ordering Information MachXO2 Family Data Sheet Ultra Low Power Industrial Grade Devices, Halogen Free (RoHS) Packaging Part Number LUTs Supply Voltage Grade Leads Temp. 256 1.2 V –1 Halogen-Free QFN 32 IND LCMXO2-256ZE-2SG32I 256 1.2 V –2 Halogen-Free QFN 32 IND LCMXO2-256ZE-3SG32I 256 1.2 V –3 Halogen-Free QFN 32 IND LCMXO2-256ZE-1SG32I Package LCMXO2-256ZE-1UMG64I 256 1.2 V –1 Halogen-Free ucBGA 64 IND LCMXO2-256ZE-2UMG64I 256 1.2 V –2 Halogen-Free ucBGA 64 IND LCMXO2-256ZE-3UMG64I 256 1.2 V –3 Halogen-Free ucBGA 64 IND LCMXO2-256ZE-1TG100I 256 1.2 V –1 Halogen-Free TQFP 100 IND LCMXO2-256ZE-2TG100I 256 1.2 V –2 Halogen-Free TQFP 100 IND LCMXO2-256ZE-3TG100I 256 1.2 V –3 Halogen-Free TQFP 100 IND LCMXO2-256ZE-1MG132I 256 1.2 V –1 Halogen-Free csBGA 132 IND LCMXO2-256ZE-2MG132I 256 1.2 V –2 Halogen-Free csBGA 132 IND LCMXO2-256ZE-3MG132I 256 1.2 V –3 Halogen-Free csBGA 132 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-640ZE-1TG100I 640 1.2 V –1 Halogen-Free TQFP 100 IND LCMXO2-640ZE-2TG100I 640 1.2 V –2 Halogen-Free TQFP 100 IND LCMXO2-640ZE-3TG100I 640 1.2 V –3 Halogen-Free TQFP 100 IND LCMXO2-640ZE-1MG132I 640 1.2 V –1 Halogen-Free csBGA 132 IND LCMXO2-640ZE-2MG132I 640 1.2 V –2 Halogen-Free csBGA 132 IND LCMXO2-640ZE-3MG132I 640 1.2 V –3 Halogen-Free csBGA 132 IND Part Number Part Number Package LUTs Supply Voltage Grade Leads Temp. 1280 1.2 V –1 Halogen-Free WLCSP 25 IND 3 1280 1.2 V –1 Halogen-Free WLCSP 25 IND LCMXO2-1200ZE-1UWG25ITR1K2 1280 1.2 V –1 Halogen-Free WLCSP 25 IND LCMXO2-1200ZE-1UWG25ITR1 LCMXO2-1200ZE-1UWG25ITR50 Package LCMXO2-1200ZE-1SG32I 1280 1.2 V –1 Halogen-Free QFN 32 IND LCMXO2-1200ZE-2SG32I 1280 1.2 V –2 Halogen-Free QFN 32 IND LCMXO2-1200ZE-3SG32I 1280 1.2 V –3 Halogen-Free QFN 32 IND LCMXO2-1200ZE-1TG100I 1280 1.2 V –1 Halogen-Free TQFP 100 IND LCMXO2-1200ZE-2TG100I 1280 1.2 V –2 Halogen-Free TQFP 100 IND LCMXO2-1200ZE-3TG100I 1280 1.2 V –3 Halogen-Free TQFP 100 IND LCMXO2-1200ZE-1MG132I 1280 1.2 V –1 Halogen-Free csBGA 132 IND LCMXO2-1200ZE-2MG132I 1280 1.2 V –2 Halogen-Free csBGA 132 IND LCMXO2-1200ZE-3MG132I 1280 1.2 V –3 Halogen-Free csBGA 132 IND LCMXO2-1200ZE-1TG144I 1280 1.2 V –1 Halogen-Free TQFP 144 IND LCMXO2-1200ZE-2TG144I 1280 1.2 V –2 Halogen-Free TQFP 144 IND LCMXO2-1200ZE-3TG144I 1280 1.2 V –3 Halogen-Free TQFP 144 IND 1. This part number has a tape and reel quantity of 5,000 units with a minimum order quantity of 10,000 units. Order quantities must be in increments of 5,000 units. For example, a 10,000 unit order will be shipped in two reels with one reel containing 5,000 units and the other reel with less than 5,000 units (depending on test yields). Unserviced backlog will be canceled. 2. This part number has a tape and reel quantity of 1,000 units with a minimum order quantity of 1,000. Order quantities must be in increments of 1,000 units. For example, a 5,000 unit order will be shipped as 5 reels of 1000 units each. 3. This part number has a tape and reel quantity of 50 units with a minimum order quantity of 50. Order quantities must be in increments of 50 units. For example, a 1,000 unit order will be shipped as 20 reels of 50 units each. 5-12 Ordering Information MachXO2 Family Data Sheet Part Number LCMXO2-2000ZE-1UWG49ITR1 LCMXO2-2000ZE-1UWG49ITR50 3 LCMXO2-2000ZE-1UWG49ITR1K 2 LUTs Supply Voltage Grade Leads Temp. 2112 1.2 V –1 Halogen-Free WLCSP Package 49 IND 2112 1.2 V –1 Halogen-Free WLCSP 49 IND 2112 1.2 V –1 Halogen-Free WLCSP 49 IND LCMXO2-2000ZE-1TG100I 2112 1.2 V –1 Halogen-Free TQFP 100 IND LCMXO2-2000ZE-2TG100I 2112 1.2 V –2 Halogen-Free TQFP 100 IND LCMXO2-2000ZE-3TG100I 2112 1.2 V –3 Halogen-Free TQFP 100 IND LCMXO2-2000ZE-1MG132I 2112 1.2 V –1 Halogen-Free csBGA 132 IND LCMXO2-2000ZE-2MG132I 2112 1.2 V –2 Halogen-Free csBGA 132 IND LCMXO2-2000ZE-3MG132I 2112 1.2 V –3 Halogen-Free csBGA 132 IND LCMXO2-2000ZE-1TG144I 2112 1.2 V –1 Halogen-Free TQFP 144 IND LCMXO2-2000ZE-2TG144I 2112 1.2 V –2 Halogen-Free TQFP 144 IND LCMXO2-2000ZE-3TG144I 2112 1.2 V –3 Halogen-Free TQFP 144 IND LCMXO2-2000ZE-1BG256I 2112 1.2 V –1 Halogen-Free caBGA 256 IND LCMXO2-2000ZE-2BG256I 2112 1.2 V –2 Halogen-Free caBGA 256 IND LCMXO2-2000ZE-3BG256I 2112 1.2 V –3 Halogen-Free caBGA 256 IND LCMXO2-2000ZE-1FTG256I 2112 1.2 V –1 Halogen-Free ftBGA 256 IND LCMXO2-2000ZE-2FTG256I 2112 1.2 V –2 Halogen-Free ftBGA 256 IND LCMXO2-2000ZE-3FTG256I 2112 1.2 V –3 Halogen-Free ftBGA 256 IND 1. This part number has a tape and reel quantity of 5,000 units with a minimum order quantity of 10,000 units. Order quantities must be in increments of 5,000 units. For example, a 10,000 unit order will be shipped in two reels with one reel containing 5,000 units and the other reel with less than 5,000 units (depending on test yields). Unserviced backlog will be canceled. 2. This part number has a tape and reel quantity of 1,000 units with a minimum order quantity of 1,000. Order quantities must be in increments of 1,000 units. For example, a 5,000 unit order will be shipped as 5 reels of 1000 units each. 3. This part number has a tape and reel quantity of 50 units with a minimum order quantity of 50. Order quantities must be in increments of 50 units. For example, a 1,000 unit order will be shipped as 20 reels of 50 units each. 5-13 Ordering Information MachXO2 Family Data Sheet Part Number LUTs Supply Voltage Grade LCMXO2-4000ZE-1QN84I 4320 1.2 V –1 LCMXO2-4000ZE-2QN84I 4320 1.2 V –2 LCMXO2-4000ZE-3QN84I 4320 1.2 V LCMXO2-4000ZE-1MG132I 4320 LCMXO2-4000ZE-2MG132I 4320 Package Leads Temp. Halogen-Free QFN 84 IND Halogen-Free QFN 84 IND –3 Halogen-Free QFN 84 IND 1.2 V –1 Halogen-Free csBGA 132 IND 1.2 V –2 Halogen-Free csBGA 132 IND LCMXO2-4000ZE-3MG132I 4320 1.2 V –3 Halogen-Free csBGA 132 IND LCMXO2-4000ZE-1TG144I 4320 1.2 V –1 Halogen-Free TQFP 144 IND LCMXO2-4000ZE-2TG144I 4320 1.2 V –2 Halogen-Free TQFP 144 IND LCMXO2-4000ZE-3TG144I 4320 1.2 V –3 Halogen-Free TQFP 144 IND LCMXO2-4000ZE-1BG256I 4320 1.2 V –1 Halogen-Free caBGA 256 IND LCMXO2-4000ZE-2BG256I 4320 1.2 V –2 Halogen-Free caBGA 256 IND LCMXO2-4000ZE-3BG256I 4320 1.2 V –3 Halogen-Free caBGA 256 IND LCMXO2-4000ZE-1FTG256I 4320 1.2 V –1 Halogen-Free ftBGA 256 IND LCMXO2-4000ZE-2FTG256I 4320 1.2 V –2 Halogen-Free ftBGA 256 IND LCMXO2-4000ZE-3FTG256I 4320 1.2 V –3 Halogen-Free ftBGA 256 IND LCMXO2-4000ZE-1BG332I 4320 1.2 V –1 Halogen-Free caBGA 332 IND LCMXO2-4000ZE-2BG332I 4320 1.2 V –2 Halogen-Free caBGA 332 IND LCMXO2-4000ZE-3BG332I 4320 1.2 V –3 Halogen-Free caBGA 332 IND LCMXO2-4000ZE-1FG484I 4320 1.2 V –1 Halogen-Free fpBGA 484 IND LCMXO2-4000ZE-2FG484I 4320 1.2 V –2 Halogen-Free fpBGA 484 IND LCMXO2-4000ZE-3FG484I 4320 1.2 V –3 Halogen-Free fpBGA 484 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-7000ZE-1TG144I 6864 1.2 V –1 Halogen-Free TQFP 144 IND LCMXO2-7000ZE-2TG144I 6864 1.2 V –2 Halogen-Free TQFP 144 IND LCMXO2-7000ZE-3TG144I 6864 1.2 V –3 Halogen-Free TQFP 144 IND LCMXO2-7000ZE-1BG256I 6864 1.2 V –1 Halogen-Free caBGA 256 IND LCMXO2-7000ZE-2BG256I 6864 1.2 V –2 Halogen-Free caBGA 256 IND LCMXO2-7000ZE-3BG256I 6864 1.2 V –3 Halogen-Free caBGA 256 IND LCMXO2-7000ZE-1FTG256I 6864 1.2 V –1 Halogen-Free ftBGA 256 IND LCMXO2-7000ZE-2FTG256I 6864 1.2 V –2 Halogen-Free ftBGA 256 IND LCMXO2-7000ZE-3FTG256I 6864 1.2 V –3 Halogen-Free ftBGA 256 IND LCMXO2-7000ZE-1BG332I 6864 1.2 V –1 Halogen-Free caBGA 332 IND LCMXO2-7000ZE-2BG332I 6864 1.2 V –2 Halogen-Free caBGA 332 IND LCMXO2-7000ZE-3BG332I 6864 1.2 V –3 Halogen-Free caBGA 332 IND LCMXO2-7000ZE-1FG484I 6864 1.2 V –1 Halogen-Free fpBGA 484 IND LCMXO2-7000ZE-2FG484I 6864 1.2 V –2 Halogen-Free fpBGA 484 IND LCMXO2-7000ZE-3FG484I 6864 1.2 V –3 Halogen-Free fpBGA 484 IND Part Number 5-14 Package Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade LCMXO2-1200ZE-1TG100IR11 Part Number 1280 1.2 V –1 Package 1 LCMXO2-1200ZE-2TG100IR1 1280 1.2 V –2 Halogen-Free TQFP 100 IND LCMXO2-1200ZE-3TG100IR11 1280 1.2 V –3 Halogen-Free TQFP 100 IND LCMXO2-1200ZE-1MG132IR11 1280 1.2 V –1 Halogen-Free csBGA 132 IND Halogen-Free TQFP Leads Temp. 100 IND LCMXO2-1200ZE-2MG132IR11 1280 1.2 V –2 Halogen-Free csBGA 132 IND LCMXO2-1200ZE-3MG132IR11 1280 1.2 V –3 Halogen-Free csBGA 132 IND LCMXO2-1200ZE-1TG144IR11 1280 1.2 V –1 Halogen-Free TQFP 144 IND LCMXO2-1200ZE-2TG144IR11 1280 1.2 V –2 Halogen-Free TQFP 144 IND LCMXO2-1200ZE-3TG144IR11 1280 1.2 V –3 Halogen-Free TQFP 144 IND 1. Specifications for the “LCMXO2-1200ZE-speed package IR1” are the same as the “LCMXO2-1200ZE-speed package I” devices respectively, except as specified in the R1 Device Specifications section of this data sheet. 5-15 Ordering Information MachXO2 Family Data Sheet High-Performance Industrial Grade Devices with Voltage Regulator, Halogen Free (RoHS) Packaging LUTs Supply Voltage Grade Leads Temp. LCMXO2-256HC-4SG32I Part Number 256 2.5 V / 3.3 V –4 Halogen-Free QFN Package 32 IND LCMXO2-256HC-5SG32I 256 2.5 V / 3.3 V –5 Halogen-Free QFN 32 IND LCMXO2-256HC-6SG32I 256 2.5 V / 3.3 V –6 Halogen-Free QFN 32 IND LCMXO2-256HC-4SG48I 256 2.5 V / 3.3 V –4 Halogen-Free QFN 48 IND LCMXO2-256HC-5SG48I 256 2.5 V / 3.3 V –5 Halogen-Free QFN 48 IND LCMXO2-256HC-6SG48I 256 2.5 V / 3.3 V –6 Halogen-Free QFN 48 IND LCMXO2-256HC-4UMG64I 256 2.5 V / 3.3 V –4 Halogen-Free ucBGA 64 IND LCMXO2-256HC-5UMG64I 256 2.5 V / 3.3 V –5 Halogen-Free ucBGA 64 IND LCMXO2-256HC-6UMG64I 256 2.5 V / 3.3 V –6 Halogen-Free ucBGA 64 IND LCMXO2-256HC-4TG100I 256 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 IND LCMXO2-256HC-5TG100I 256 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 IND LCMXO2-256HC-6TG100I 256 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 IND LCMXO2-256HC-4MG132I 256 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 IND LCMXO2-256HC-5MG132I 256 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 IND LCMXO2-256HC-6MG132I 256 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 IND LUTs Supply Voltage Grade Leads Temp. Part Number Package LCMXO2-640HC-4SG48I 640 2.5 V / 3.3 V –4 Halogen-Free QFN 48 IND LCMXO2-640HC-5SG48I 640 2.5 V / 3.3 V –5 Halogen-Free QFN 48 IND LCMXO2-640HC-6SG48I 640 2.5 V / 3.3 V –6 Halogen-Free QFN 48 IND LCMXO2-640HC-4TG100I 640 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 IND LCMXO2-640HC-5TG100I 640 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 IND LCMXO2-640HC-6TG100I 640 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 IND LCMXO2-640HC-4MG132I 640 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 IND LCMXO2-640HC-5MG132I 640 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 IND LCMXO2-640HC-6MG132I 640 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-640UHC-4TG144I Part Number 640 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 IND LCMXO2-640UHC-5TG144I 640 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 IND LCMXO2-640UHC-6TG144I 640 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 IND 5-16 Package Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200HC-4SG32I Part Number 1280 2.5 V / 3.3 V –4 Halogen-Free QFN Package 32 IND LCMXO2-1200HC-5SG32I 1280 2.5 V / 3.3 V –5 Halogen-Free QFN 32 IND LCMXO2-1200HC-6SG32I 1280 2.5 V / 3.3 V –6 Halogen-Free QFN 32 IND LCMXO2-1200HC-4TG100I 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 IND LCMXO2-1200HC-5TG100I 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 IND LCMXO2-1200HC-6TG100I 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 IND LCMXO2-1200HC-4MG132I 1280 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 IND LCMXO2-1200HC-5MG132I 1280 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 IND LCMXO2-1200HC-6MG132I 1280 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 IND LCMXO2-1200HC-4TG144I 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 IND LCMXO2-1200HC-5TG144I 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 IND LCMXO2-1200HC-6TG144I 1280 2.5 V/ 3.3 V –6 Halogen-Free TQFP 144 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200UHC-4FTG256I Part Number 1280 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 IND LCMXO2-1200UHC-5FTG256I 1280 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 IND LCMXO2-1200UHC-6FTG256I 1280 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000HC-4TG100I 2112 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 IND LCMXO2-2000HC-5TG100I 2112 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 IND LCMXO2-2000HC-6TG100I 2112 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 IND LCMXO2-2000HC-4MG132I 2112 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 IND Part Number Package Package LCMXO2-2000HC-5MG132I 2112 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 IND LCMXO2-2000HC-6MG132I 2112 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 IND LCMXO2-2000HC-4TG144I 2112 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 IND LCMXO2-2000HC-5TG144I 2112 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 IND LCMXO2-2000HC-6TG144I 2112 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 IND LCMXO2-2000HC-4BG256I 2112 2.5 V / 3.3 V –4 Halogen-Free caBGA 256 IND LCMXO2-2000HC-5BG256I 2112 2.5 V / 3.3 V –5 Halogen-Free caBGA 256 IND LCMXO2-2000HC-6BG256I 2112 2.5 V / 3.3 V –6 Halogen-Free caBGA 256 IND LCMXO2-2000HC-4FTG256I 2112 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 IND LCMXO2-2000HC-5FTG256I 2112 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 IND LCMXO2-2000HC-6FTG256I 2112 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000UHC-4FG484I Part Number 2112 2.5 V / 3.3 V –4 Halogen-Free fpBGA 484 IND LCMXO2-2000UHC-5FG484I 2112 2.5 V / 3.3 V –5 Halogen-Free fpBGA 484 IND LCMXO2-2000UHC-6FG484I 2112 2.5 V / 3.3 V –6 Halogen-Free fpBGA 484 IND 5-17 Package Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-4000HC-4QN84I Part Number 4320 2.5 V / 3.3 V –4 Halogen-Free QFN Package 84 IND LCMXO2-4000HC-5QN84I 4320 2.5 V / 3.3 V –5 Halogen-Free QFN 84 IND LCMXO2-4000HC-6QN84I 4320 2.5 V / 3.3 V –6 Halogen-Free QFN 84 IND LCMXO2-4000HC-4TG144I 4320 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 IND LCMXO2-4000HC-5TG144I 4320 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 IND LCMXO2-4000HC-6TG144I 4320 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 IND LCMXO2-4000HC-4MG132I 4320 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 IND LCMXO2-4000HC-5MG132I 4320 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 IND LCMXO2-4000HC-6MG132I 4320 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 IND LCMXO2-4000HC-4BG256I 4320 2.5 V / 3.3 V –4 Halogen-Free caBGA 256 IND LCMXO2-4000HC-5BG256I 4320 2.5 V / 3.3 V –5 Halogen-Free caBGA 256 IND LCMXO2-4000HC-6BG256I 4320 2.5 V / 3.3 V –6 Halogen-Free caBGA 256 IND LCMXO2-4000HC-4FTG256I 4320 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 IND LCMXO2-4000HC-5FTG256I 4320 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 IND LCMXO2-4000HC-6FTG256I 4320 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 IND LCMXO2-4000HC-4BG332I 4320 2.5 V / 3.3 V –4 Halogen-Free caBGA 332 IND LCMXO2-4000HC-5BG332I 4320 2.5 V / 3.3 V –5 Halogen-Free caBGA 332 IND LCMXO2-4000HC-6BG332I 4320 2.5 V / 3.3 V –6 Halogen-Free caBGA 332 IND LCMXO2-4000HC-4FG484I 4320 2.5 V / 3.3 V –4 Halogen-Free fpBGA 484 IND LCMXO2-4000HC-5FG484I 4320 2.5 V / 3.3 V –5 Halogen-Free fpBGA 484 IND LCMXO2-4000HC-6FG484I 4320 2.5 V / 3.3 V –6 Halogen-Free fpBGA 484 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-7000HC-4TG144I Part Number 6864 2.5 V / 3.3 V –4 Halogen-Free TQFP Package 144 IND LCMXO2-7000HC-5TG144I 6864 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 IND LCMXO2-7000HC-6TG144I 6864 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 IND LCMXO2-7000HC-4BG256I 6864 2.5 V / 3.3 V –4 Halogen-Free caBGA 256 IND LCMXO2-7000HC-5BG256I 6864 2.5 V / 3.3 V –5 Halogen-Free caBGA 256 IND LCMXO2-7000HC-6BG256I 6864 2.5 V / 3.3 V –6 Halogen-Free caBGA 256 IND LCMXO2-7000HC-4FTG256I 6864 2.5 V / 3.3 V –4 Halogen-Free ftBGA 256 IND LCMXO2-7000HC-5FTG256I 6864 2.5 V / 3.3 V –5 Halogen-Free ftBGA 256 IND LCMXO2-7000HC-6FTG256I 6864 2.5 V / 3.3 V –6 Halogen-Free ftBGA 256 IND LCMXO2-7000HC-4BG332I 6864 2.5 V / 3.3 V –4 Halogen-Free caBGA 332 IND LCMXO2-7000HC-5BG332I 6864 2.5 V / 3.3 V –5 Halogen-Free caBGA 332 IND LCMXO2-7000HC-6BG332I 6864 2.5 V / 3.3 V –6 Halogen-Free caBGA 332 IND LCMXO2-7000HC-4FG400I 6864 2.5 V / 3.3 V –4 Halogen-Free fpBGA 400 IND LCMXO2-7000HC-5FG400I 6864 2.5 V / 3.3 V –5 Halogen-Free fpBGA 400 IND LCMXO2-7000HC-6FG400I 6864 2.5 V / 3.3 V –6 Halogen-Free fpBGA 400 IND LCMXO2-7000HC-4FG484I 6864 2.5 V / 3.3 V –4 Halogen-Free fpBGA 484 IND LCMXO2-7000HC-5FG484I 6864 2.5 V / 3.3 V –5 Halogen-Free fpBGA 484 IND LCMXO2-7000HC-6FG484I 6864 2.5 V / 3.3 V –6 Halogen-Free fpBGA 484 IND 5-18 Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-1200HC-4TG100IR11 Part Number 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 100 IND 1 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 100 IND LCMXO2-1200HC-6TG100IR11 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 100 IND 1 1280 2.5 V / 3.3 V –4 Halogen-Free csBGA 132 IND LCMXO2-1200HC-5MG132IR11 1280 2.5 V / 3.3 V –5 Halogen-Free csBGA 132 IND 1 LCMXO2-1200HC-5TG100IR1 LCMXO2-1200HC-4MG132IR1 LCMXO2-1200HC-6MG132IR1 Package 1280 2.5 V / 3.3 V –6 Halogen-Free csBGA 132 IND LCMXO2-1200HC-4TG144IR11 1280 2.5 V / 3.3 V –4 Halogen-Free TQFP 144 IND LCMXO2-1200HC-5TG144IR11 1280 2.5 V / 3.3 V –5 Halogen-Free TQFP 144 IND LCMXO2-1200HC-6TG144IR11 1280 2.5 V / 3.3 V –6 Halogen-Free TQFP 144 IND 1. Specifications for the “LCMXO2-1200HC-speed package IR1” are the same as the “LCMXO2-1200ZE-speed package I” devices respectively, except as specified in the R1 Device Specifications section of this data sheet. 5-19 Ordering Information MachXO2 Family Data Sheet High Performance Industrial Grade Devices Without Voltage Regulator, Halogen Free (RoHS) Packaging Part Number LCMXO2-2000HE-4TG100I LUTs Supply Voltage Grade 2112 1.2 V –4 Package Halogen-Free TQFP Leads Temp. 100 IND LCMXO2-2000HE-5TG100I 2112 1.2 V –5 Halogen-Free TQFP 100 IND LCMXO2-2000HE-6TG100I 2112 1.2 V –6 Halogen-Free TQFP 100 IND LCMXO2-2000HE-4MG132I 2112 1.2 V –4 Halogen-Free csBGA 132 IND LCMXO2-2000HE-5MG132I 2112 1.2 V –5 Halogen-Free csBGA 132 IND LCMXO2-2000HE-6MG132I 2112 1.2 V –6 Halogen-Free csBGA 132 IND LCMXO2-2000HE-4TG144I 2112 1.2 V –4 Halogen-Free TQFP 144 IND LCMXO2-2000HE-5TG144I 2112 1.2 V –5 Halogen-Free TQFP 144 IND LCMXO2-2000HE-6TG144I 2112 1.2 V –6 Halogen-Free TQFP 144 IND LCMXO2-2000HE-4BG256I 2112 1.2 V –4 Halogen-Free caBGA 256 IND LCMXO2-2000HE-5BG256I 2112 1.2 V –5 Halogen-Free caBGA 256 IND LCMXO2-2000HE-6BG256I 2112 1.2 V –6 Halogen-Free caBGA 256 IND LCMXO2-2000HE-4FTG256I 2112 1.2 V –4 Halogen-Free ftBGA 256 IND LCMXO2-2000HE-5FTG256I 2112 1.2 V –5 Halogen-Free ftBGA 256 IND LCMXO2-2000HE-6FTG256I 2112 1.2 V –6 Halogen-Free ftBGA 256 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-2000UHE-4FG484I Part Number 2112 1.2 V –4 Halogen-Free fpBGA 484 IND LCMXO2-2000UHE-5FG484I 2112 1.2 V –5 Halogen-Free fpBGA 484 IND LCMXO2-2000UHE-6FG484I 2112 1.2 V –6 Halogen-Free fpBGA 484 IND 5-20 Package Ordering Information MachXO2 Family Data Sheet LUTs Supply Voltage Grade Leads Temp. LCMXO2-4000HE-4MG132I Part Number 4320 1.2 V –4 Halogen-Free csBGA Package 132 IND LCMXO2-4000HE-5MG132I 4320 1.2 V –5 Halogen-Free csBGA 132 IND LCMXO2-4000HE-6MG132I 4320 1.2 V –6 Halogen-Free csBGA 132 IND LCMXO2-4000HE-4TG144I 4320 1.2 V –4 Halogen-Free TQFP 144 IND LCMXO2-4000HE-5TG144I 4320 1.2 V –5 Halogen-Free TQFP 144 IND LCMXO2-4000HE-6TG144I 4320 1.2 V –6 Halogen-Free TQFP 144 IND LCMXO2-4000HE-4MG184I 4320 1.2 V –4 Halogen-Free csBGA 184 IND LCMXO2-4000HE-5MG184I 4320 1.2 V –5 Halogen-Free csBGA 184 IND LCMXO2-4000HE-6MG184I 4320 1.2 V –6 Halogen-Free csBGA 184 IND LCMXO2-4000HE-4BG256I 4320 1.2 V –4 Halogen-Free caBGA 256 IND LCMXO2-4000HE-5BG256I 4320 1.2 V –5 Halogen-Free caBGA 256 IND LCMXO2-4000HE-6BG256I 4320 1.2 V –6 Halogen-Free caBGA 256 IND LCMXO2-4000HE-4FTG256I 4320 1.2 V –4 Halogen-Free ftBGA 256 IND LCMXO2-4000HE-5FTG256I 4320 1.2 V –5 Halogen-Free ftBGA 256 IND LCMXO2-4000HE-6FTG256I 4320 1.2 V –6 Halogen-Free ftBGA 256 IND LCMXO2-4000HE-4BG332I 4320 1.2 V –4 Halogen-Free caBGA 332 IND LCMXO2-4000HE-5BG332I 4320 1.2 V –5 Halogen-Free caBGA 332 IND LCMXO2-4000HE-6BG332I 4320 1.2 V –6 Halogen-Free caBGA 332 IND LCMXO2-4000HE-4FG484I 4320 1.2 V –4 Halogen-Free fpBGA 484 IND LCMXO2-4000HE-5FG484I 4320 1.2 V –5 Halogen-Free fpBGA 484 IND LCMXO2-4000HE-6FG484I 4320 1.2 V –6 Halogen-Free fpBGA 484 IND LUTs Supply Voltage Grade Leads Temp. LCMXO2-7000HE-4TG144I 6864 1.2 V –4 Halogen-Free TQFP 144 IND LCMXO2-7000HE-5TG144I 6864 1.2 V –5 Halogen-Free TQFP 144 IND LCMXO2-7000HE-6TG144I 6864 1.2 V –6 Halogen-Free TQFP 144 IND LCMXO2-7000HE-4BG256I 6864 1.2 V –4 Halogen-Free caBGA 256 IND LCMXO2-7000HE-5BG256I 6864 1.2 V –5 Halogen-Free caBGA 256 IND LCMXO2-7000HE-6BG256I 6864 1.2 V –6 Halogen-Free caBGA 256 IND LCMXO2-7000HE-4FTG256I 6864 1.2 V –4 Halogen-Free ftBGA 256 IND LCMXO2-7000HE-5FTG256I 6864 1.2 V –5 Halogen-Free ftBGA 256 IND LCMXO2-7000HE-6FTG256I 6864 1.2 V –6 Halogen-Free ftBGA 256 IND LCMXO2-7000HE-4BG332I 6864 1.2 V –4 Halogen-Free caBGA 332 IND LCMXO2-7000HE-5BG332I 6864 1.2 V –5 Halogen-Free caBGA 332 IND LCMXO2-7000HE-6BG332I 6864 1.2 V –6 Halogen-Free caBGA 332 IND LCMXO2-7000HE-4FG484I 6864 1.2 V –4 Halogen-Free fpBGA 484 IND LCMXO2-7000HE-5FG484I 6864 1.2 V –5 Halogen-Free fpBGA 484 IND LCMXO2-7000HE-6FG484I 6864 1.2 V –6 Halogen-Free fpBGA 484 IND Part Number 5-21 Package Ordering Information MachXO2 Family Data Sheet R1 Device Specifications The LCMXO2-1200ZE/HC “R1” devices have the same specifications as their Standard (non-R1) counterparts except as listed below. For more details on the R1 to Standard migration refer to AN8086, Designing for Migration from MachXO2-1200-R1 to Standard Non-R1) Devices. • The User Flash Memory (UFM) cannot be programmed through the internal WISHBONE interface. It can still be programmed through the JTAG/SPI/I2C ports. • The on-chip differential input termination resistor value is higher than intended. It is approximately 200 as opposed to the intended 100. It is recommended to use external termination resistors for differential inputs. The on-chip termination resistors can be disabled through Lattice design software. • Soft Error Detection logic may not produce the correct result when it is run for the first time after configuration. To use this feature, discard the result from the first operation. Subsequent operations will produce the correct result. • Under certain conditions, IIH exceeds data sheet specifications. The following table provides more details: Condition Clamp Pad Rising IIH Max. Pad Falling IIH Min. Steady State Pad High IIH Steady State Pad Low IIL VPAD > VCCIO OFF 1 mA –1 mA 1 mA 10 µA VPAD = VCCIO ON 10 µA –10 µA 10 µA 10 µA VPAD = VCCIO OFF 1 mA –1 mA 1 mA 10 µA VPAD < VCCIO OFF 10 µA –10 µA 10 µA 10 µA • The user SPI interface does not operate correctly in some situations. During master read access and slave write access, the last byte received does not generate the RRDY interrupt. • In GDDRX2, GDDRX4 and GDDR71 modes, ECLKSYNC may have a glitch in the output under certain conditions, leading to possible loss of synchronization. • When using the hard I2C IP core, the I2C status registers I2C_1_SR and I2C_2_SR may not update correctly. • PLL Lock signal will glitch high when coming out of standby. This glitch lasts for about 10 µsec before returning low. • Dual boot only available on HC devices, requires tying VCC and VCCIO2 to the same 3.3 V or 2.5 V supply. 5-22 MachXO2 Family Data Sheet Supplemental Information April 2012 Data Sheet DS1035 For Further Information A variety of technical notes for the MachXO2 family are available on the Lattice web site. • TN1198, Power Estimation and Management for MachXO2 Devices • TN1199, MachXO2 sysCLOCK PLL Design and Usage Guide • TN1201, Memory Usage Guide for MachXO2 Devices • TN1202, MachXO2 sysIO Usage Guide • TN1203, Implementing High-Speed Interfaces with MachXO2 Devices • TN1204, MachXO2 Programming and Configuration Usage Guide • TN1205, Using User Flash Memory and Hardened Control Functions in MachXO2 Devices • TN1206, MachXO2 SRAM CRC Error Detection Usage Guide • TN1207, Using TraceID in MachXO2 Devices • TN1074, PCB Layout Recommendations for BGA Packages • TN1087, Minimizing System Interruption During Configuration Using TransFR Technology • AN8086, Designing for Migration from MachXO2-1200-R1 to Standard (non-R1) Devices • AN8066, Boundary Scan Testability with Lattice sysIO Capability • MachXO2 Device Pinout Files • Thermal Management document • Lattice design tools For further information on interface standards, refer to the following web sites: • JEDEC Standards (LVTTL, LVCMOS, LVDS, DDR, DDR2, LPDDR): www.jedec.org • PCI: www.pcisig.com © 2012 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 DS1035 Further Info_01.3 MachXO2 Family Data Sheet Revision History March 2017 Data Sheet DS1035 Date Version Section March 2017 3.3 DC and Switching Characteristics Change Summary Updated the Absolute Maximum Ratings section. Added standards. Updated the sysIO Recommended Operating Conditions section. Added standards. Updated the sysIO Single-Ended DC Electrical Characteristics section. Added standards. Updated the MachXO2 External Switching Characteristics – HC/HE Devices section.  Under 7:1 LVDS Outputs – GDDR71_TX.ECLK.7:1, the DVB and the DVA parameters were changed to DIB and DIA. The parameter descriptions were also modified. Updated the MachXO2 External Switching Characteristics – ZE Devices section.  Under 7:1 LVDS Outputs – GDDR71_TX.ECLK.7:1, the DVB and the DVA parameters were changed to DIB and DIA. The parameter descriptions were also modified. Updated the sysCONFIG Port Timing Specifications section.  Corrected the tINITL units from ns to µs. Pinout Information Updated the Signal Descriptions section. Revised the descriptions of the PROGRAMN, INITN, and DONE signals. Updated the Pinout Information Summary section. Added footnote to MachXO2-1200 32 QFN. Ordering Information Updated the MachXO2 Part Number Description section. Corrected the MG184, BG256, FTG256 package information. Added “(0.8 mm Pitch)” to BG332. Updated the Ultra Low Power Industrial Grade Devices, Halogen Free (RoHS) Packaging section. — Updated LCMXO2-1200ZE-1UWG25ITR50 footnote. — Corrected footnote numbering typo. — Added the LCMXO2-2000ZE-1UWG49ITR50 and LCMXO22000ZE-1UWG49ITR1K part numbers. Updated/added footnote/s. © 2016 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 DS1035 Revision History Revision History MachXO2 Family Data Sheet Date Version Section Change Summary May 2016 3.2 All Moved designation for 84 QFN package information from 'Advanced' to 'Final'. Introduction Updated the Features section. Revised Table 1-1, MachXO2 Family Selection Guide.  — Added ‘Advanced’ 48 QFN package. — Revised footnote 6. — Added footnote 9. DC and Switching Characteristics Updated the MachXO2 External Switching Characteristics – HC/HE Devices section. Added footnote 12. Updated the MachXO2 External Switching Characteristics – ZE Devices section. Added footnote 12. Pinout Information Updated the Signal Descriptions section. Added information on GND signal. Updated the Pinout Information Summary section.  — Added ‘Advanced’ MachXO2-256 48 QFN values. — Added ‘Advanced’ MachXO2-640 48 QFN values. — Added footnote to GND. — Added footnotes 2 and 3. Ordering Information Updated the MachXO2 Part Number Description section. Added ‘Advanced’ SG48 package and revised footnote. Updated the Ordering Information section.  — Added part numbers for ‘Advanced’ QFN 48 package. March 2016 3.1 Introduction Updated the Features section. Revised Table 1-1, MachXO2 Family Selection Guide.  — Added 32 QFN value for XO2-1200. — Added 84 QFN (7 mm x 7 mm, 0.5 mm) package. — Modified package name to 100-pin TQFP. — Modified package name to 144-pin TQFP. — Added footnote. Architecture Updated the Typical I/O Behavior During Power-up section. Removed reference to TN1202. DC and Switching Characteristics Updated the sysCONFIG Port Timing Specifications section. Revised tDPPDONE and tDPPINIT Max. values per PCN 03A-16, released March 2016. Pinout Information Updated the Pinout Information Summary section.  — Added MachXO2-1200 32 QFN values. — Added ‘Advanced’ MachXO2-4000 84 QFN values. Ordering Information Updated the MachXO2 Part Number Description section. Added ‘Advanced’ QN84 package and footnote. Updated the Ordering Information section.  — Added part numbers for 1280 LUTs QFN 32 package. — Added part numbers for 4320 LUTs QFN 84 package. March 2015 3.0 Introduction Updated the Features section. Revised Table 1-1, MachXO2 Family Selection Guide.  — Changed 64-ball ucBGA dimension. Architecture Updated the Device Configuration section. Added JTAGENB to TAP dual purpose pins. 7-2 Revision History MachXO2 Family Data Sheet Date Version Section Change Summary December 2014 2.9 Introduction Updated the Features section. Revised Table 1-1, MachXO2 Family Selection Guide.  — Removed XO2-4000U data. — Removed 400-ball ftBGA.  — Removed 25-ball WLCSP value for XO2-2000U. DC and Switching Characteristics Updated the Recommended Operating Conditions section. Adjusted Max. values for VCC and VCCIO. Updated the sysIO Recommended Operating Conditions section. Adjusted Max. values for LVCMOS 3.3, LVTTL, PCI, LVDS33 and LVPECL. Pinout Information Ordering Information Updated the Pinout Information Summary section. Removed MachXO2-4000U. Updated the MachXO2 Part Number Description section. Removed BG400 package. Updated the High-Performance Commercial Grade Devices with Voltage Regulator, Halogen Free (RoHS) Packaging section. Removed LCMXO2-4000UHC part numbers. Updated the High-Performance Industrial Grade Devices with Voltage Regulator, Halogen Free (RoHS) Packaging section. Removed LCMXO2-4000UHC part numbers. November 2014 2.8 Introduction Updated the Features section.  — Revised I/Os under Flexible Logic Architecture. — Revised standby power under Ultra Low Power Devices. — Revise input frequency range under Flexible On-Chip Clocking. Updated Table 1-1, MachXO2 Family Selection Guide.  — Added XO2-4000U data. — Removed HE and ZE device options for XO2-4000. — Added 400-ball ftBGA. Pinout Information Ordering Information Updated the Pinout Information Summary section. Added MachXO24000U caBGA400 and MachXO2-7000 caBGA400. Updated the MachXO2 Part Number Description section. Added BG400 package. Updated the Ordering Information section. Added MachXO2-4000U caBGA400 and MachXO2-7000 caBGA400 part numbers. October 2014 2.7 Ordering Information Updated the Ultra Low Power Industrial Grade Devices, Halogen Free (RoHS) Packaging section. Fixed typo in LCMXO2-2000ZE1UWG49ITR part number package. Architecture Updated the Supported Standards section. Added MIPI information to Table 2-12. Supported Input Standards and Table 2-13. Supported Output Standards. DC and Switching Characteristics Updated the BLVDS section. Changed output impedance nominal values in Table 3-2, BLVDS DC Condition. Updated the LVPECL section. Changed output impedance nominal value in Table 3-3, LVPECL DC Condition. Updated the sysCONFIG Port Timing Specifications section. Updated INITN low time values. July 2014 2.6 DC and Switching Characteristics Updated sysIO Single-Ended DC Electrical Characteristics1, 2 section. Updated footnote 4. Updated Register-to-Register Performance section. Updated footnote. Ordering Information Updated UW49 package to UWG49 in MachXO2 Part Number Description. Updated LCMXO2-2000ZE-1UWG49CTR package in Ultra Low Power Commercial Grade Devices, Halogen Free (RoHS) Packaging. 7-3 Revision History MachXO2 Family Data Sheet Date Version Section May 2014 2.5 Architecture Updated TransFR (Transparent Field Reconfiguration) section. Updated TransFR description for PLL use during background Flash programming. February 2014 02.4 Introduction Included the 49 WLCSP package in the MachXO2 Family Selection Guide table. Architecture Added information to Standby Mode and Power Saving Options section. Pinout Information Added the XO2-2000 49 WLCSP in the Pinout Information Summary table. Ordering Information Change Summary Added UW49 package in MachXO2 Part Number Description. Added and LCMXO2-2000ZE-1UWG49CTR in Ultra Low Power Commercial Grade Devices, Halogen Free (RoHS) Packaging section. Added and LCMXO2-2000ZE-1UWG49ITR in Ultra Low Power Industrial Grade Devices, Halogen Free (RoHS) Packaging section. December 2013 02.3 Architecture DC and Switching Characteristics Updated information on CLKOS output divider in sysCLOCK Phase Locked Loops (PLLs) section. Updated Static Supply Current – ZE Devices table. Updated footnote 4 in sysIO Single-Ended DC Electrical Characteristics table; Updated VIL Max. (V) data for LVCMOS 25 and LVCMOS 28. Updated VOS test condition in sysIO Differential Electrical Characteristics - LVDS table. September 2013 02.2 Architecture Removed I2C Clock-Stretching feature per PCN #10A-13. Removed information on PDPR memory in RAM Mode section. Updated Supported Input Standards table. DC and Switching Characteristics June 2013 02.1 Architecture Updated Power-On-Reset Voltage Levels table. Architecture Overview – Added information on the state of the register on power up and after configuration. sysCLOCK Phase Locked Loops (PLLs) section – Added missing cross reference to sysCLOCK PLL Timing table. DC and Switching Characteristics Added slew rate information to footnote 2 of the MachXO2 External Switching Characteristics – HC/HE Devices and the MachXO2 External Switching Characteristics – ZE Devices tables. Power-On-Reset Voltage Levels table – Added symbols. 7-4 Revision History MachXO2 Family Data Sheet Date Version Section January 2013 02.0 Introduction Updated the total number IOs to include JTAGENB. Change Summary Architecture Supported Output Standards table – Added 3.3 VCCIO (Typ.) to LVDS row. Changed SRAM CRC Error Detection to Soft Error Detection. DC and Switching Characteristics Power Supply Ramp Rates table – Updated Units column for tRAMP symbol. Added new Maximum sysIO Buffer Performance table. sysCLOCK PLL Timing table – Updated Min. column values for fIN, fOUT, fOUT2 and fPFD parameters. Added tSPO parameter. Updated footnote 6. MachXO2 Oscillator Output Frequency table – Updated symbol name for tSTABLEOSC. DC Electrical Characteristics table – Updated conditions for IIL, IIH symbols. Corrected parameters tDQVBS and tDQVAS Corrected MachXO2 ZE parameters tDVADQ and tDVEDQ Pinout Information Ordering Information April 2012 01.9 Architecture Ordering Information Included the MachXO2-4000HE 184 csBGA package. Updated part number. Removed references to TN1200. Updated the Device Status portion of the MachXO2 Part Number Description to include the 50 parts per reel for the WLCSP package. Added new part number and footnote 2 for LCMXO2-1200ZE1UWG25ITR50. Updated footnote 1 for LCMXO2-1200ZE-1UWG25ITR. Supplemental Information March 2012 01.8 Introduction Removed references to TN1200. Added 32 QFN packaging information to Features bullets and MachXO2 Family Selection Guide table. DC and Switching Characteristics Changed ‘STANDBY’ to ‘USERSTDBY’ in Standby Mode timing diagram. Pinout Information Removed footnote from Pin Information Summary tables. Added 32 QFN package to Pin Information Summary table. Ordering Information Updated Part Number Description and Ordering Information tables for 32 QFN package. Updated topside mark diagram in the Ordering Information section. 7-5 Revision History MachXO2 Family Data Sheet Date Version Section February 2012 01.7 All 01.6 — Introduction DC and Switching Characteristics Change Summary Updated document with new corporate logo. Data sheet status changed from preliminary to final. MachXO2 Family Selection Guide table – Removed references to  49-ball WLCSP. Updated Flash Download Time table. Modified Storage Temperature in the Absolute Maximum Ratings section. Updated IDK max in Hot Socket Specifications table. Modified Static Supply Current tables for ZE and HC/HE devices. Updated Power Supply Ramp Rates table. Updated Programming and Erase Supply Current tables. Updated data in the External Switching Characteristics table. Corrected Absolute Maximum Ratings for Dedicated Input Voltage Applied for LCMXO2 HC. DC Electrical Characteristics table – Minor corrections to conditions for IIL, IIH. Pinout Information Removed references to 49-ball WLCSP. Signal Descriptions table – Updated description for GND, VCC, and VCCIOx. Updated Pin Information Summary table – Number of VCCIOs, GNDs, VCCs, and Total Count of Bonded Pins for MachXO2-256, 640, and 640U and Dual Function I/O for MachXO2-4000 332caBGA. Ordering Information August 2011 01.5 DC and Switching Characteristics Ordering Information 01.4 Architecture Removed references to 49-ball WLCSP Updated ESD information. Updated footnote for ordering WLCSP devices. Updated information in Clock/Control Distribution Network and sysCLOCK Phase Locked Loops (PLLs). DC and Switching Characteristics Updated IIL and IIH conditions in the DC Electrical Characteristics table. Pinout Information Included number of 7:1 and 8:1 gearboxes (input and output) in the pin information summary tables. Updated Pin Information Summary table: Dual Function I/O, DQS Groups Bank 1, Total General Purpose Single-Ended I/O, Differential  I/O Per Bank, Total Count of Bonded Pins, Gearboxes. Added column of data for MachXO2-2000 49 WLCSP. Ordering Information Updated R1 Device Specifications text section with information on migration from MachXO2-1200-R1 to Standard (non-R1) devices. Corrected Supply Voltage typo for part numbers: LCMX02-2000UHE4FG484I, LCMX02-2000UHE-5FG484I, LCMX02-2000UHE6FG484I. Added footnote for WLCSP package parts. Supplemental Information Removed reference to Stand-alone Power Calculator for MachXO2 Devices. Added reference to AN8086, Designing for Migration from MachXO2-1200-R1 to Standard (non-R1) Devices. 7-6 Revision History MachXO2 Family Data Sheet Date Version Section May 2011 01.3 Multiple Change Summary Replaced “SED” with “SRAM CRC Error Detection” throughout the document. DC and Switching Characteristics Added footnote 1 to Program Erase Specifications table. Pinout Information Updated Pin Information Summary tables. Signal name SO/SISPISO changed to SO/SPISO in the Signal Descriptions table. April 2011 01.2 — Data sheet status changed from Advance to Preliminary. Introduction Updated MachXO2 Family Selection Guide table. Architecture Updated Supported Input Standards table. Updated sysMEM Memory Primitives diagram. Added differential SSTL and HSTL IO standards. DC and Switching Characteristics Updates following parameters: POR voltage levels, DC electrical characteristics, static supply current for ZE/HE/HC devices, static power consumption contribution of different components – ZE devices, programming and erase Flash supply current. Added VREF specifications to sysIO recommended operating conditions. Updating timing information based on characterization. Added differential SSTL and HSTL IO standards. Ordering Information Added Ordering Part Numbers for R1 devices, and devices in WLCSP packages. Added R1 device specifications. January 2011 01.1 All DC and Switching Characteristics Included ultra-high I/O devices. Recommended Operating Conditions table – Added footnote 3. DC Electrical Characteristics table – Updated data for IIL, IIH. VHYST typical values updated. Generic DDRX2 Outputs with Clock and Data Aligned at Pin (GDDRX2_TX.ECLK.Aligned) Using PCLK Pin for Clock Input tables – Updated data for TDIA and TDIB. Generic DDRX4 Outputs with Clock and Data Aligned at Pin (GDDRX4_TX.ECLK.Aligned) Using PCLK Pin for Clock Input tables – Updated data for TDIA and TDIB. Power-On-Reset Voltage Levels table - clarified note 3. Clarified VCCIO related recommended operating conditions specifications. Added power supply ramp rate requirements. Added Power Supply Ramp Rates table. Updated Programming/Erase Specifications table. Removed references to VCCP. Pinout Information Included number of 7:1 and 8:1 gearboxes (input and output) in the pin information summary tables. Removed references to VCCP. November 2010 01.0 — Initial release. 7-7
LCMXO2-4000HC-C-EVN
物料型号:文档中没有明确列出特定的物料型号,但提到了MachXO2 Family,这可能指的是Lattice Semiconductor的FPGA系列。

器件简介:文档是关于MachXO2系列的数据手册,涵盖了DC和Switching Characteristics,包括不同的I/O标准和性能参数。

引脚分配:文档提供了详细的引脚分配信息,包括通用I/O、差分I/O、电源和地引脚等,但具体的引脚分配需要根据具体的MachXO2设备型号来确定。

参数特性:文档列出了多种参数特性,包括但不限于: - DDRX2和DDRX4的输出数据有效时间(tDVB、tDVA) - DDRX2和DDRX4的串行输出数据速度(fDATA) - DDRX2和DDRX4的ECLK频率(fDDRX2、fDDRX4) - LVDS输出的参数,如7:1 LVDS输出的频率(fCLKOUT) - LPDDR、DDR和DDR2的输入数据有效时间(tDVADQ) - 不同模式下的SCLK频率(fSCLK)

功能详解:文档详细解释了各种功能参数,如DDRX2、DDRX4、LPDDR、DDR和DDR2的输入输出时序要求,以及它们的数据传输速率。

应用信息:文档中没有直接提供应用信息,但通过参数特性可以推断这些FPGA适用于需要高速数据传输和多种I/O标准的应用。

封装信息:文档提到了多种封装类型,包括QFN、BGA、WLCSP等,具体的封装信息需要根据具体的MachXO2设备型号来确定。
LCMXO2-4000HC-C-EVN 价格&库存

很抱歉,暂时无法提供与“LCMXO2-4000HC-C-EVN”相匹配的价格&库存,您可以联系我们找货

免费人工找货