8T49N105A-999NLGI

FemtoClock® NG Universal Frequency Translator IDT8T49N105I DATA SHEET General Description Features The IDT8T49N105I is a highly flexible FemtoClock® NG general purpose, low phase noise Universal Frequency Translator / Synthesizer with alarm and monitoring functions suitable for networking and communications applications. It is able to generate any output frequency in the 0.98MHz - 312.5MHz range and most output frequencies in the 312.5MHz - 1,300MHz range (see Table 3 for details). A wide range of input reference clocks and a range of low-cost fundamental mode crystal frequencies may be used as the source for the output frequency. • • • • • Fourth generation FemtoClock® NG technology • • • Input frequency range: 8kHz - 710MHz The IDT8T49N105I has three operating modes to support a very broad spectrum of applications: Synthesizes output frequencies from a 16MHz - 40MHz fundamental mode crystal. • Fractional feedback division is used, so there are no requirements for any specific crystal frequency to produce the desired output frequency with a high degree of accuracy. Single output (Q, nQ), programmable as LVPECL or LVDS Zero ppm frequency translation Single differential input supports the following input types: LVPECL, LVDS, LVHSTL, HCSL Crystal input frequency range: 16MHz - 40MHz Two factory-set register configurations for power-up default state • • • • 1) Frequency Synthesizer • Universal Frequency Translator (UFT) / Frequency Synthesizer Power-up default configuration pin or register selectable Configurations customized via One-Time Programmable ROM Settings may be overwritten after power-up via I2C I2C Serial interface for register programming • RMS phase jitter at 155.52MHz, using a 40MHz crystal LVDS Output (12kHz - 20MHz): 439fs (typical), Low Bandwidth Mode (FracN) 2) High-Bandwidth Frequency Translator • • Applications: PCI Express, Computing, General Purpose • Translates any input clock in the 16MHz - 710MHz frequency range into any supported output frequency. RMS phase jitter at 400MHz, using a 40MHz crystal (12kHz - 40MHz):285fs (typical), Synthesizer Mode (Integer FB) • • This mode has a high PLL loop bandwidth in order to track input reference changes, such as Spread-Spectrum Clock modulation, so it will not attenuate much jitter on the input reference. Output supply voltage modes: VCC/VCCA/VCCO 3.3V/3.3V/3.3V 3.3V/3.3V/2.5V (LVPECL only) 2.5V/2.5V/2.5V • • -40°C to 85°C ambient operating temperature 3) Low-Bandwidth Frequency Translator VEE nc nc 32 19 nc LF0 33 18 S_A0 LF1 34 VEE 35 8T49N105 40 Lead VFQFN 17 S_A1 6mm x 6mm x 0.925mm 16 36 E-Pad 4.65mm x 4.65mm 15 CONFIG K Package SDATA 38 nc 39 XTALBAD 40 Top View 2 3 4 5 6 7 8 SCLK 13 VCC 12 PLL_BYPASS 11 9 10 nc nc CLKBAD 14 nc 37 VEE HOLDOVER XTAL_IN XTAL_OUT 1 nc nc nc 1 IDT8T49N105ANLGI REVISION A MAY 24, 2013 VCCO 30 29 28 27 26 25 24 23 22 21 20 VCCA To implement other configurations, these power-up default settings can be overwritten after power-up using the I2C interface and the device can be completely reconfigured. However, these settings would have to be re-written next time the device powers-up. nQ 31 VCC One usage example might be to install the device on a line card with two optional daughter cards: an OC-12 option requiring a 622.08MHz LVDS clock translated from a 19.44MHz input and a Gigabit Ethernet option requiring a 125MHz LVPECL clock translated from the same 19.44MHz input reference. nc nCLK This device provides two factory-programmed default power-up configurations burned into One-Time Programmable (OTP) memory. The configuration to be used is selected by the CONFIG pin. The two configurations are specified by the customer and are programmed by IDT during the final test phase from an on-hand stock of blank devices. The two configurations may be completely independent of one another. Q LOCK_IND VCC Pin Assignment CLK This mode supports PLL loop bandwidths in the 10Hz - 580Hz range and makes use of an external crystal to provide significant jitter attenuation. Lead-free (RoHS 6) packaging OE • Translates any input clock in the 8kHz -710MHz frequency range into any supported output frequency. nc Applications: Networking & Communications. VCC • • ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Complete Block Diagram IDT8T49N105ANLGI REVISION A MAY 24, 2013 2 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 1. Pin Descriptions Number Name 1 2 XTAL_IN XTAL_OUT Input Crystal Oscillator interface designed for 12pF parallel resonant crystals. XTAL_IN (pin 1) is the input and XTAL_OUT (pin 2) is the output. 3, 7, 13, 29 VCC Power Core supply pins. All must be either 3.3V or 2.5V. 4, 9, 10, 11, 19, 20, 22, 23, 24, 31, 32, 39 nc Unused 8, 21, 35 VEE Power 5 CLK Input Pulldown Non-inverting differential clock input. Input Pullup/ Pulldown Inverting differential clock input. VCC/2 default when left floating (set by the internal pullup and pulldown resistors). Bypasses the VCXO PLL. In bypass mode, outputs are clocked off the falling edge of the input reference. LVCMOS/LVTTL interface levels. 0 = PLL Mode (default) 1 = PLL Bypassed 6 nCLK Type Description No connect. These pins are to be left unconnected. Negative supply pins. 12 PLL_BYPASS Input Pulldown 14 SDATA I/O Pullup I2C Data Input/Output. Open drain. 15 SCLK Input Pullup I2C Clock Input. LVCMOS/LVTTL interface levels. 16 CONFIG Input Pulldown Configuration Pin. Selects between one of two factory programmable pre-set power-up default configurations. The two configurations can have different output/input frequency translation ratios, different PLL loop bandwidths, etc. These default configurations can be overwritten after power-up via I2C if the user so desires. LVCMOS/LVTTL interface levels. 0 = Configuration 0 (default) 1 = Configuration 1 17 S_A1 Input Pulldown I2C Address Bit 1. LVCMOS/LVTTL interface levels. 18 S_A0 Input Pulldown I2C Address Bit 0. LVCMOS/LVTTL interface levels. 25 VCCO Power Output supply pins for Q, nQ output. Either 2.5V or 3.3V. 26, 27 nQ, Q Output Differential output pair. Output type is programmable to LVDS or LVPECL interface levels. 28 OE Input 30 LOCK_IND Output Lock Indicator - indicates that the PLL is in a locked condition. LVCMOS/LVTTL interface levels. 33, 34 LF0, LF1 Analog I/O Loop filter connection node pins. LF0 is the output. LF1 is the input. 36 VCCA Power Analog supply voltage. See Applications section for details on how to connect this pin. Pullup Active High Output Enable for Q, nQ. LVCMOS/LVTTL interface levels. 0 = Output pins high-impedance 1 = Output switching (default) 37 HOLDOVER Output Alarm output reflecting if the device is in a holdover state. LVCMOS/LVTTL interface levels. 0 = Device is locked to a valid input reference 1 = Device is not locked to a valid input reference 38 CLK_BAD Output Alarm output reflecting the state of CLK. LVCMOS/LVTTL interface levels. 0 = Input Clock is switching within specifications 1 = Input Clock is out of specification 40 XTAL_BAD Output Alarm output reflecting the state of XTAL. LVCMOS/LVTTL interface levels. 0 = crystal is switching within specifications 1 = crystal is out of specification NOTE: Pullup and Pulldown refer to internal input resistors. See Table 2, Pin Characteristics, for typical values. IDT8T49N105ANLGI REVISION A MAY 24, 2013 3 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 2. Pin Characteristics Symbol Parameter CIN Input Capacitance 3.5 pF RPULLUP Input Pullup Resistor 51 k RPULLDOWN Input Pulldown Resistor 51 k IDT8T49N105ANLGI REVISION A MAY 24, 2013 Test Conditions 4 Minimum Typical Maximum Units ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Functional Description The IDT8T49N105I is designed to provide almost any desired output frequency within its operating range (0.98 - 1300MHz) from any input source in the operating range (8kHz - 710MHz). It is capable of synthesizing frequencies from a crystal or crystal oscillator source. The output frequency is generated regardless of the relationship to the input frequency. The output frequency will be exactly the required frequency in most cases. In most others, it will only differ from the desired frequency by a few ppb. IDT configuration software will indicate the frequency error, if any. The IDT8T49N105I can translate the desired output frequency from one of two input clocks. Again, no relationship is required between the input and output frequencies in order to translate to the output clock rate. In this frequency translation mode, a low-bandwidth, jitter attenuation option is available that makes use of an external fixed-frequency crystal or crystal oscillator to translate from a noisy input source. If the input clock is known to be fairly clean or if some modulation on the input needs to be tracked, then the high-bandwidth frequency translation mode can be used, without the need for the external crystal. ratios within the IDT8T49N105I for the two different card configurations. Access via I2C would not be necessary for operation using either of the internal configurations. Operating Modes The IDT8T49N105I has three operating modes which are set by the MODE_SEL[1:0] bits. There are two frequency translator modes low bandwidth and high bandwidth and a frequency synthesizer mode. The device will operate in the same mode regardless of which configuration is active. Please make use of IDT-provided configuration applications to determine the best operating settings for the desired configurations of the device. Output Dividers & Supported Output Frequencies In all 3 operating modes, the output stage behaves the same way, but different operating frequencies can be specified in the two configurations. The input clock references and crystal input are monitored continuously and appropriate alarm outputs are raised both as register bits and hard-wired pins in the event of any out-of-specification conditions arising. Clock switching is supported in manual, revertive & non-revertive modes. The internal VCO is capable of operating in a range anywhere from 1.995GHz - 2.6GHz. It is necessary to choose an integer multiplier of the desired output frequency that results in a VCO operating frequency within that range. The output divider stage N[10:0] is limited to selection of integers from 2 to 2046. Please refer to Table 3 for the values of N applicable to the desired output frequency. The IDT8T49N105I has two factory-programmed configurations that may be chosen from as the default operating state after reset. This is intended to allow the same device to be used in two different applications without any need for access to the I2C registers. These defaults may be over-written by I2C register access at any time, but those over-written settings will be lost on power-down. Please contact IDT if a specific set of power-up default settings is desired. Table 3. Output Divider Settings & Frequency Ranges Register Setting Frequency Divider Minimum fOUT Maximum fOUT Nn[10:0] N (MHz) (MHz) Configuration Selection 0000000000x 2 997.5 1300 The IDT8T49N105I comes with two factory-programmed default configurations. When the device comes out of power-up reset the selected configuration is loaded into operating registers. The IDT8T49N105I uses the state of the CONFIG pin or CONFIG register bit (controlled by the CFG_PIN_REG bit) to determine which configuration is active. When the output frequency is changed either via the CONFIG pin or via internal registers, the output behavior may not be predictable during the register writing and output settling periods. Devices sensitive to glitches or runt pulses may have to be reset once reconfiguration is complete. 00000000010 2 997.5 1300 00000000011 3 665 866.7 00000000100 4 498.75 650 00000000101 5 399 520 0000000011x 6 332.5 433.3 0000000100x 8 249.4 325 0000000101x 10 199.5 260 0000000110x 12 166.3 216.7 0000000111x 14 142.5 185.7 0000001000x 16 124.7 162.5 Once the device is out of reset, the contents of the operating registers can be modified by write access from the I2C serial port. Users that have a custom configuration programmed may not require I2C access. It is expected that the IDT8T49N105I will be used almost exclusively in a mode where the selected configuration will be used from device power-up without any changes during operation. For example, the device may be designed into a communications line card that supports different I/O modules such as a standard OC-12 module running at 622.08MHz or a (255/237) FEC rate OC-12 module running at 669.32MHz. The different I/O modules would result in a different level on the CONFIG pin which would select different divider IDT8T49N105ANLGI REVISION A MAY 24, 2013 5 0000001001x 18 110.8 144.4 ... Even N 1995 / N 2600 / N 1111111111x 2046 0.98 1.27 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Frequency Synthesizer Mode The input reference frequency range is now extended up to 710MHz. A pre-divider stage P is needed to keep the operating frequencies at the phase detector within limits. This mode of operation allows an arbitrary output frequency to be generated from a fundamental mode crystal input. For improved phase noise performance, the crystal input frequency may be doubled. As can be seen from the block diagram in Figure 1, only the upper feedback loop is used in this mode of operation. It is recommended that CLK be left unused in this mode of operation. Low-Bandwidth Frequency Translator Mode As can be seen from the block diagram in Figure 3, this mode involves two PLL loops. The lower loop with the large integer dividers is the low bandwidth loop and it sets the output-to-input frequency translation ratio.This loop drives the upper DCXO loop (digitally controlled crystal oscillator) via an analog-digital converter. The upper feedback loop supports a delta-sigma fractional feedback divider. This allows the VCO operating frequency to be a non-integer multiple of the crystal frequency. By using an integer multiple only, lower phase noise jitter on the output can be achieved, however the use of the delta-sigma divider logic will provide excellent performance on the output if a fractional divisor is used. Figure 3. Low Bandwidth Frequency Translator Mode Block Diagram The pre-divider stage is used to scale down the input frequency by an integer value to achieve a frequency in this range. By dividing down the fed-back VCO operating frequency by the integer divider M1[16:0] to as close as possible to the same frequency, exact output frequency translations can be achieved. The phase detector of the lower loop is designed to work with frequencies in the 8kHz - 16kHz range. For improved phase noise performance, the crystal input frequency may be doubled. Figure 1. Frequency Synthesizer Mode Block Diagram High-Bandwidth Frequency Translator Mode This mode of operation is used to translate the input clock of the same nominal frequency into an output frequency with little jitter attenuation. As can be seen from the block diagram in Figure 2, similarly to the Frequency Synthesizer mode, only the upper feedback loop is used. Alarm Conditions & Status Bits The IDT8T49N105I monitors a number of conditions and reports their status via both output pins and register bits. All alarms will behave as indicated below in all modes of operation, but some of the conditions monitored have no valid meaning in some operating modes. For example, the status of CLK_BAD is not relevant in Frequency Synthesizer mode. The output will still be active and it is left to the user to determine which to monitor and how to respond to them based on the known operating mode. LOCK_IND - This status is asserted on the pin & register bit when the PLL is locked to the appropriate input reference for the chosen mode of operation. The status bit will not assert until frequency lock has been achieved, but will de-assert once lock is lost. Figure 2. High Bandwidth Frequency Translator Mode Block Diagram IDT8T49N105ANLGI REVISION A MAY 24, 2013 6 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Output Configuration XTAL_BAD - indicates if valid edges are being received on the crystal input. Detection is performed by comparing the input to the feedback signal at the upper loop’s Phase / Frequency Detector (PFD). If three edges are received on the feedback without an edge on the crystal input, the XTAL_BAD alarm is asserted on the pin & register bit. Once an edge is detected on the crystal input, the alarm is immediately deasserted. The output voltage of the IDT8T49N105I may be less than or equal to the core voltage (3.3V or 2.5V) the rest of the device is operating from. The output voltage level used is supplied on the VCCO pin. The output is selectable as an LVDS or LVPECL output type via the Q_TYPE register bit. This selection bit is provided in each configuration to allow different output type settings under each configuration. CLK_BAD - indicates if valid edges are being received on the CLK reference input. Detection is performed by comparing the input to the feedback signal at the appropriate Phase / Frequency Detector (PFD). When operating in high-bandwidth mode, the feedback at the upper PFD is used. In low-bandwidth mode, the feedback at the lower PFD is used. If three edges are received on the feedback without an edge on the divided down (÷P) CLK reference input, the CLK_BAD alarm is asserted on the pin & register bit. Once an edge is detected on the CLK reference input, the alarm is deasserted. The output can be enabled also via both register control bits and input pins. When the OE register bit and OE pin are enabled, then the output is enabled. The OE register bit defaults to enabled so that by default the output can be directly controlled by the input pin. Similarly, the input pin is provisioned with weak pull-ups so that if they are left unconnected, the output state can be directly controlled by the register bit. When the differential output is in the disabled state, it will show a high impedance condition. HOLDOVER - indicates that the device is not locked to a valid input reference clock. This can occur in Manual switchover mode if the reference input has gone bad. Serial Interface Configuration Description Holdover / Free-run Behavior The IDT8T49N105I has an I2C-compatible configuration interface to access any of the internal registers (Table 4D) for frequency and PLL parameter programming. The IDT8T49N105I acts as a slave device on the I2C bus and has the address 0b11011xx, where xx is set by the values on the S_A0 & S_A1 pins (see Table 4A for details). The interface accepts byte-oriented block write and block read operations. An address byte (P) specifies the register address (Table 4D) as the byte position of the first register to write or read. Data bytes (registers) are accessed in sequential order from the lowest to the highest byte (most significant bit first, see table 4B, 4C). Read and write block transfers can be stopped after any complete byte transfer. It is recommended to terminate I2C the read or write transfer after accessing byte #23. When the input reference has failed, the IDT8T49N105I will enter holdover (Low Bandwidth Frequency Translator mode) or free-run (High Bandwidth Frequency Translator mode) state. In both cases, once the input reference is lost, the PLL will stop making adjustments to the output phase. If operating in Low Bandwidth Frequency Translation mode, the PLL will continue to reference itself to the local oscillator and will hold its output phase and frequency in relation to that source. Output stability is determined by the stability of the local oscillator in this case. However, if operating in High Bandwidth Frequency Translation mode, the PLL no longer has any frequency reference to use and output stability is now determined by the stability of the internal VCO. Once the input reference recovers, the IDT8T49N105I will switch back to that reference. For full electrical I2C compliance, it is recommended to use external pull-up resistors for SDATA and SCLK. The internal pull-up resistors have a size of 50k typical. Note: if a different device slave address is desired, please contact IDT. Table 4A. I2C Device Slave Address 1 1 0 1 1 S_A1 S_A0 R/W Table 4B. Block Write Operation Bit 1 2:8 9 10 11:18 19 20:27 28 29-36 37 ... ... ... START Slave Address W (0) A C K Address Byte (P) A C K Data Byte (P) A C K Data Byte (P+1) A C K Data Byte ... A C K STOP 1 7 1 1 8 1 8 1 8 1 8 1 1 Description Length (bits) IDT8T49N105ANLGI REVISION A MAY 24, 2013 7 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 4C. Block Read Operation Bit 1 2:8 10 11:18 19 Address Byte (P) A C K Repeated START 8 1 1 START Slave Address W (0) A C K 1 7 1 1 Description Length (bits) 9 20 21:27 28 29 30:37 38 39-46 47 ... ... ... Slave Address R (1) A C K Data Byte (P) A C K Data Byte (P+1) A C K Data Byte ... A C K STOP 7 1 1 8 1 8 1 8 1 1 Register Descriptions Please consult IDT for configuration software and/or programming guides to assist in selection of optimal register settings for the desired configurations. Table 4D. I2C Register Map Register Bit Reg Binary Register Address D7 D6 D5 D4 D3 D2 D1 D0 0 00000 MFRAC0[17] MFRAC0[16] MFRAC0[15] MFRAC0[14] MFRAC0[13] MFRAC0[12] MFRAC0[11] MFRAC0[10] 1 00001 MFRAC1[17] MFRAC1[16] MFRAC1[15] MFRAC1[14] MFRAC1[13] MFRAC1[12] MFRAC1[11] MFRAC1[10] 2 00010 MFRAC0[9] MFRAC0[8] MFRAC0[7] MFRAC0[6] MFRAC0[5] MFRAC0[4] MFRAC0[3] MFRAC0[2] 3 00011 MFRAC1[9] MFRAC1[8] MFRAC1[7] MFRAC1[6] MFRAC1[5] MFRAC1[4] MFRAC1[3] MFRAC1[2] 4 00100 MFRAC0[1] MFRAC0[0] MINT0[7] MINT0[6] MINT0[5] MINT0[4] MINT0[3] MINT0[2] 5 00101 MFRAC1[1] MFRAC1[0] MINT1[7] MINT1[6] MINT1[5] MINT1[4] MINT1[3] MINT1[2] 6 00110 MINT0[1] MINT0[0] P0[16] P0[15] P0[14] P0[13] P0[12] P0[11] 7 00111 MINT1[1] MINT1[0] P1[16] P1[15] P1[14] P1[13] P1[12] P1[11] 8 01000 P0[10] P0[9] P0[8] P0[7] P0[6] P0[5] P0[4] P0[3] 9 01001 P1[10] P1[9] P1[8] P1[7] P1[6] P1[5] P1[4] P1[3] 10 01010 P0[2] P0[1] P0[0] M1_0[16] M1_0[15] M1_0[14] M1_0[13] M1_0[12] 11 01011 P1[2] P1[1] P1[0] M1_1[16] M1_1[15] M1_1[14] M1_1[13] M1_1[12] 12 01100 M1_0[11] M1_0[10] M1_0[9] M1_0[8] M1_0[7] M1_0[6] M1_0[5] M1_0[4] 13 01101 M1_1[11] M1_1[10] M1_1[9] M1_1[8] M1_1[7] M1_1[6] M1_1[5] M1_1[4] 14 01110 M1_0[3] M1_0[2] M1_0[1] M1_0[0] N0[10] N0[9] N0[8] N0[7] 15 01111 M1_1[3] M1_1[2] M1_1[1] M1_1[0] N1[10] N1[9] N1[8] N1[7] 16 10000 N0[6] N0[5] N0[4] N0[3] N0[2] N0[1] N0[0] BW0[6] 17 10001 N1[6] N1[5] N1[4] N1[3] N1[2] N1[1] N1[0] BW1[6] 18 10010 BW0[5] BW0[4] BW0[3] BW0[2] BW0[1] BW0[0] RSVD Q_TYPE0 19 10011 BW1[5] BW1[4] BW1[3] BW1[2] BW1[1] BW1[0] RSVD Q_TYPE1 20 10100 MODE_SEL[1] MODE_SEL[0] CONFIG CFG_PIN_REG 0 OE Rsvd Rsvd 21 10101 0 1 1 0 ADC_RATE[1] ADC_RATE[0] LCK_WIN[1] LCK_WIN[0] 22 10110 1 0 1 0 DBL_XTAL 0 0 0 HOLDOVER RSVD CLK_BAD XTAL_BAD LOCK_IND Rsvd Rsvd 23 10111 Register Bit Color Key Configuration 0 Specific Bits Configuration 1 Specific Bits Global Control & Status Bits IDT8T49N105ANLGI REVISION A MAY 24, 2013 8 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator The register bits described in Table 4E are duplicated, with one set applying for Configuration 0 and the other for Configuration 1. The functions of the bits are identical, but only apply when the configuration they apply to is enabled. Replace the lowercase n in the bit field description with 0 or 1 to find the field’s location in the bitmap in Table 4D. Table 4E. Configuration-Specific Control Bits Register Bits Q_TYPEn Pn[16:0] M1_n[16:0] M_INTn[7:0] M_FRACn[17:0] Function Determines the output type for output pair Q, nQ for Configuration n. 0 = LVPECL 1 = LVDS Reference Pre-Divider for Configuration n. Integer Feedback Divider in Lower Feedback Loop for Configuration n. Feedback Divider, Integer Value in Upper Feedback Loop for Configuration n. Feedback Divider, Fractional Value in Upper Feedback Loop for Configuration n. Nn[10:0] Output Divider for Configuration n. BWn[6:0] Internal Operation Settings for Configuration n. Please use IDT IDT8T49N105I Configuration Software to determine the correct settings for these bits for the specific configuration. Alternatively, please consult with IDT directly for further information on the functions of these bits.The function of these bits are explained in Tables 4J and 4K. Table 4F. Global Control Bits Register Bits Function MODE_SEL[1:0] PLL Mode Select 00 = Low Bandwidth Frequency Translator 01 = Frequency Synthesizer 10 = High Bandwidth Frequency Translator 11 = High Bandwidth Frequency Translator CFG_PIN_REG Configuration Control. Selects whether the configuration selection function is under pin or register control. 0 = Pin Control 1 = Register Control CONFIG Configuration Selection. Selects whether the device uses the register configuration set 0 or 1. This bit only has an effect when the CONFIG_PIN_REG bit is set to 1 to enable register control. OE Output Enable Control for Q, nQ output. Both the register bit and the corresponding Output Enable pin OE must be asserted to enable the Q, nQ output. 0 = Output Q, nQ disabled 1 = Output Q, nQ under control of the OE pin Rsvd Reserved bits - user should write a ‘0’ to these bit positions if a write to these registers is needed ADC_RATE[1:0] Sets the ADC sampling rate in Low-Bandwidth Mode as a fraction of the crystal input frequency. 00 = Crystal Frequency / 16 01 = Crystal Frequency / 8 10 = Crystal Frequency / 4 (recommended) 11 = Crystal Frequency / 2 LCK_WIN[1:0] DBL_XTAL Sets the width of the window in which a new reference edge must fall relative to the feedback edge: 00 = 2usec (recommended), 01 = 4usec, 10 = 8usec, 11 = 16usec When set, this bit will double the frequency of the crystal input before applying it to the Phase_Frequency Detector. IDT8T49N105ANLGI REVISION A MAY 24, 2013 9 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 4G. Global Status Bits Register Bits Function CLK_BAD Status Bit for input clock 0. This function is mirrored in the CLK_BAD pin. 0 = input CLK is good 1 = input CLK is bad. Self clears when input clock returns to good status XTAL_BAD Status Bit. This function is mirrored on the XTALBAD pin. 0 = crystal input good 1 = crystal input bad. Self-clears when the XTAL clock returns to good status LOCK_IND Status bit. This function is mirrored on the LOCK_IND pin. 0 = PLL unlocked 1 = PLL locked HOLDOVER Status Bit. This function is mirrored on the HOLDOVER pin. 0 = Input to phase detector is within specifications and device is tracking to it 1 = Phase detector input is not within specifications and DCXO is frozen at last value IDT8T49N105ANLGI REVISION A MAY 24, 2013 10 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 4J. BW[6:0] Bits Mode BW[6] BW[5] BW[4] BW[3] BW[2] BW[1] BW[0] Synthesizer Mode PLL2_LF[1] PLL2_LF[0] DSM_ORD DSM_EN PLL2_CP[1] PLL2_CP[0] PLL2_LOW_ICP High-Bandwidth Mode PLL2_LF[1] PLL2_LF[0] DSM_ORD DSM_EN PLL2_CP[1] PLL2_CP[0] PLL2_LOW_ICP Low-Bandwidth Mode ADC_GAIN[3] ADC_GAIN[2] ADC_GAIN[1] ADC_GAIN[0] PLL1_CP[1] PLL1_CP[0] PLL2_LOW_ICP Table 4K. Functions of Fields in BW[6:0] Register Bits Function PLL2_LF[1:0] Sets loop filter values for upper loop PLL in Frequency Synthesizer & High-Bandwidth modes. Defaults to setting of 00 when in Low Bandwidth Mode. See Table 4L for settings. DSM_ORD Sets Delta-Sigma Modulation to 2nd (0) or 3rd order (1) operation Enables Delta-Sigma Modulator 0 = Disabled - feedback in integer mode only 1 = Enabled - feedback in fractional mode DSM_EN Upper loop PLL charge pump current settings: 00 = 173A (defaults to this setting in Low Bandwidth Mode) 01 = 346A 10 = 692A 11 = reserved PLL2_CP[1:0] PLL2_LOW_ICP Reduces Charge Pump current by 1/3 to reduce bandwidth variations resulting from higher feedback register settings or high VCO operating frequency (>2.4GHz). ADC_GAIN[3:0] Gain setting for ADC in Low Bandwidth Mode. Lower loop PLL charge pump current settings (lower loop is only used in Low Bandwidth Mode): 00 = 800A 01 = 400A 10 = 200A 11 = 100A PLL1_CP[1:0] Table 4L. High Bandwidth Frequency and Frequency Synthesizer Bandwidth Settings Desired Bandwidth PLL2_CP PLL2_LOW_ICP 200kHz 00 1 00 400kHz 01 1 01 800kHz 10 1 10 2MHz 10 1 11 PLL2_LF Frequency Synthesizer Mode High Bandwidth Frequency Translator Mode 200kHz 00 1 00 400kHz 01 1 01 800kHz 10 1 10 4MHz 10 0 11 NOTE: To achieve 4MHz bandwidth, reference to the phase detector should be 80MHz. IDT8T49N105ANLGI REVISION A MAY 24, 2013 11 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Absolute Maximum Ratings NOTE: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These ratings are stress specifications only. Functional operation of product at these conditions or any conditions beyond those listed in the DC Characteristics or AC Characteristics is not implied. Exposure to absolute maximum rating conditions for extended periods may affect product reliability. Item Rating Supply Voltage, VCC 3.63V Inputs, VI XTAL_IN Other Inputs 0V to 2V -0.5V to VCC + 0.5V Outputs, VO (LVCMOS) -0.5V to VCCO + 0.5V Outputs, IO (LVPECL) Continuous Current Surge Current 50mA 100mA Outputs, IO (LVDS) Continuous Current Surge Current 10mA 15mA Package Thermal Impedance, JA 32.4C/W (0 mps) Storage Temperature, TSTG -65C to 150C DC Electrical Characteristics Table 5A. LVPECL Power Supply DC Characteristics, VCC = VCCO = 3.3V±5%, VEE = 0V, TA = -40°C to 85°C Symbol Parameter VCC Core Supply Voltage VCCA Test Conditions Minimum Typical Maximum Units 3.135 3.3 3.465 V Analog Supply Voltage VCC – 0.30 3.3 VCC V VCCO Output Supply Voltage 3.135 3.3 3.465 V IEE Power Supply Current 332 mA ICCA Analog Supply Current 30 mA Table 5B. LVPECL Power Supply DC Characteristics, VCC = 3.3V±5%, VCCO = 2.5V±5%, VEE = 0V, TA = -40°C to 85°C Symbol Parameter VCC Core Supply Voltage VCCA Minimum Typical Maximum Units 3.135 3.3 3.465 V Analog Supply Voltage VCC – 0.30 3.3 VCC V VCCO Output Supply Voltage 2.375 2.5 2.625 V IEE Power Supply Current 332 mA ICCA Analog Supply Current 30 mA IDT8T49N105ANLGI REVISION A MAY 24, 2013 Test Conditions 12 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 5C. LVPECL Power Supply DC Characteristics, VCC = VCCO = 2.5V±5%, VEE = 0V, TA = -40°C to 85°C Symbol Parameter VCC Core Supply Voltage VCCA Test Conditions Minimum Typical Maximum Units 2.375 2.5 2.625 V Analog Supply Voltage VCC – 0.26 2.5 VCC V VCCO Output Supply Voltage 2.375 2.5 2.625 V IEE Power Supply Current 319 mA ICCA Analog Supply Current 26 mA Table 5D. LVDS Power Supply DC Characteristics, VCC = VCCO = 3.3V±5%, TA = -40°C to 85°C Symbol Parameter VCC Core Supply Voltage VCCA Test Conditions Minimum Typical Maximum Units 3.135 3.3 3.465 V Analog Supply Voltage VCC – 0.30 3.3 VCC V VCCO Output Supply Voltage 3.135 3.3 3.465 V ICC Power Supply Current 284 mA ICCA Analog Supply Current 30 mA ICCO Output Supply Current 22 mA Table 5E. LVDS Power Supply DC Characteristics, VCC = VCCO = 2.5V±5%, TA = -40°C to 85°C Symbol Parameter VCC Core Supply Voltage VCCA Minimum Typical Maximum Units 2.375 2.5 2.625 V Analog Supply Voltage VCC – 0.26 2.5 VCC V VCCO Output Supply Voltage 2.375 2.5 2.625 V ICC Power Supply Current 275 mA ICCA Analog Supply Current 26 mA ICCO Output Supply Current 22 mA IDT8T49N105ANLGI REVISION A MAY 24, 2013 Test Conditions 13 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 5F. LVCMOS/LVTTL DC Characteristics, TA = -40°C to 85°C Symbol Parameter VIH Input High Voltage VIL Input Low Voltage IIH IIL VOH VOL Input High Current Input Low Current Test Conditions Minimum VCC = 3.3V Typical Maximum Units 2 VCC + 0.3 V VCC = 2.5V 1.7 VCC + 0.3 V VCC = 3.3V -0.3 0.8 V VCC = 2.5V -0.3 0.7 V CONFIG, PLL_BYPASS, S_A[0:1] VCC = VIN = 3.465V or 2.625V 150 µA OE, SCLK, SDATA VCC = VIN = 3.465V or 2.625V 5 µA CONFIG, PLL_BYPASS, S_A[0:1] VCC = 3.465V or 2.625V, VIN = 0V -5 µA OE, SCLK, SDATA VCC = 3.465V or 2.625V, VIN = 0V -150 µA VCC = 3.3V ± 5%, IOH = -8mA 2.6 V VCC = 2.5V ± 5%, IOH = -8mA 1.8 V Output High Voltage LOCK_IND, HOLDOVER, SDATA, CLK_BAD, XTAL_BAD Output Low Voltage LOCK_IND, HOLDOVER, SDATA, CLK_BAD, XTAL_BAD VCC = 3.3V ± 5% or 2.5V ± 5%, IOL = 8mA 0.5 V Table 5G. Differential DC Characteristics, VCC = VCCO = 3.3V±5% or 2.5V±5%, VEE = 0V, TA = -40°C to 85°C Symbol Parameter IIH Input High Current Test Conditions IIL Input Low Current VPP Peak-to-Peak Voltage; Note 1 0.15 1.3 V VCMR Common Mode Input Voltage; NOTE 1, 2 VEE + 0.5 VCC - 1.0 V Maximum Units CLK, nCLK Minimum Typical VCC = VIN = 3.465V or 2.625V Maximum Units 150 µA CLK VCC = 3.465V or 2.625V, VIN = 0V -5 µA nCLK VCC = 3.465V or 2.625V, VIN = 0V -150 µA NOTE 1: VIL should not be less than -0.3v. NOTE 2: Common mode input voltage is defined as the crosspoint. Table 5H. LVPECL DC Characteristics, VCC = VCCO = 3.3V±5%, VEE = 0V, TA = -40°C to 85°C Symbol Parameter Test Conditions Minimum Typical VOH Output High Voltage; NOTE 1 VCCO – 1.1 VCCO – 0.7 V VOL Output Low Voltage NOTE 1 VCCO – 2.0 VCCO – 1.5 V VSWING Peak-to-Peak Output Voltage Swing 0.6 1.0 V NOTE 1: Outputs terminated with 50 to VCCO – 2V. IDT8T49N105ANLGI REVISION A MAY 24, 2013 14 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Table 5I. LVPECL DC Characteristics, VCC = 3.3V±5% or 2.5V±5%, VCCO = 2.5V±5%, VEE = 0V, TA = -40°C to 85°C Symbol Parameter Test Conditions VOH Output High Voltage; NOTE 1 VOL Output Low Voltage NOTE 1 VSWING Peak-to-Peak Output Voltage Swing Minimum Typical Maximum Units VCCO – 1.1 VCCO – 0.8 V VCCO – 2.0 VCCO – 1.5 V 0.6 1.0 V Maximum Units 454 mV 50 mV 1.375 V 50 mV Maximum Units 454 mV 50 mV 1.375 V 50 mV Maximum Units 16 40 MHz High Bandwidth Mode 16 710 MHz Low Bandwidth Mode 0.008 710 MHz 5 MHz NOTE 1: Outputs terminated with 50 to VCCO – 2V. Table 5J. LVDS DC Characteristics, VCC = VCCO = 3.3V ± 5%, TA = -40°C to 85°C Symbol Parameter Test Conditions VOD Differential Output Voltage VOD VOD Magnitude Change VOS Offset Voltage VOS VOS Magnitude Change Minimum Typical 247 1.125 Table 5K. LVDS DC Characteristics, VCC = VCCO = 2.5V±5%, TA = -40°C to 85°C Symbol Parameter Test Conditions VOD Differential Output Voltage VOD VOD Magnitude Change VOS Offset Voltage VOS VOS Magnitude Change Minimum Typical 247 1.125 Table 6. Input Frequency Characteristics, VCC = VCCO = 3.3V ± 5%, TA = -40°C to 85°C Symbol Parameter Test Conditions XTAL_IN, XTAL_OUT; NOTE 1 fIN Input Frequency Minimum Typical CLK, nCLK SCLK NOTE 1: For the input crystal and CLK, nCLK frequency range, the M value must be set for the VCO to operate within the 1995MHz to 2600MHz range. Table 7. Crystal Characteristics Parameter Test Conditions Minimum Mode of Oscillation Typical Units 40 MHz 100  7 pF Fundamental Frequency 16 Equivalent Series Resistance (ESR) Shunt Capacitance Load Capacitance (CL) IDT8T49N105ANLGI REVISION A MAY 24, 2013 Maximum 12 15 pF ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator AC Electrical Characteristics Table 8. AC Characteristics, VCC = VCCO = 3.3V±5% or 2.5V±5%, or VCC = 3.3V±5%, VCCO = 2.5V±5% (LVPECL Only), VEE = 0V, TA = -40°C to 85°C Symbol Parameter fOUT Output Frequency tjit(Ø) tjit(per) Test Conditions RMS Phase Jitter; NOTE 2 Integer Divide Ratio RMS Period Jitter NOTE 3 tjit(cc) Cycle-to-Cycle Jitter; NOTE 3 tR / tF Output Rise/Fall Time LVPECL Outputs LVDS Outputs odc Output Duty Cycle tSET Output Re-configuration Settling Time Minimum Typical 0.98 Maximum Units 1300 MHz Synth Mode (Integer FB), fOUT = 400MHz, 40MHz XTAL, Integration Range: 12kHz – 40MHz 285 446 fs Synth Mode (FracN FB), fOUT = 698.81MHz, 40MHz XTAL, Integration Range: 12kHz – 20MHz 363 521 fs HBW Mode, (NOTE 1) fIN = 133.33MHz, fOUT = 400MHz, Integration Range: 12kHz – 20MHz 313 490 fs LBW Mode (FracN), 40MHz XTAL, fIN = 19.44MHz, fOUT = 155.52MHz, Integration Range: 12kHz – 20MHz (LVDS Output) 439 670 fs LBW Mode (FracN), 40MHz XTAL, fIN = 25MHz, fOUT = 161.1328125MHz, Integration Range: 12kHz – 20MHz (LVDS Output) 450 670 fs LVPECL Outputs 2.2 5.3 ps LVDS Output 5.1 8.7 ps Frequency Synthesizer Mode 30 ps Frequency Translator Mode 40 ps 100 520 ps 20% to 80% 20% to 80% 80 520 ps fOUT < 600MHz 45 55 % fOUT  600MHz 40 60 % from falling edge of the 8th SCLK for a register change 200 ns from edge on CONFIG pin 10 ns NOTE: Electrical parameters are guaranteed over the specified ambient operating temperature range, which is established when the device is mounted in a test socket with maintained transverse airflow greater than 500 lfpm. The device will meet specifications after thermal equilibrium has been reached under these conditions. NOTE 1: Measured using a Rohde & Schwarz SMA100 Signal Generator, 9kHz to 6GHz as the input source. NOTE 2: RMS Phase Jitter are measured with DBL_XTAL bit set to 1 and crystal CL = 12pf. NOTE 3: This parameter is defined in accordance with Jedec Standard 65. IDT8T49N105ANLGI REVISION A MAY 24, 2013 16 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Noise Power (dBc/Hz) Typical Phase Noise at 400MHz Offset Frequency (Hz) IDT8T49N105ANLGI REVISION A MAY 24, 2013 17 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Parameter Measurement Information 2V 2V 2V 2V VCC, VCCO VCC, VCCO VCCA VCCA -0.5V±0.125V -1.3V+0.165V 3.3 Core/3.3V LVPECL Output Load Test Circuit 2.5 Core/2.5V LVPECL Output Load Test Circuit 2.8V±0.04V 2V 2.8V±0.04V VCC Qx VCCO SCOPE VCC, VCCO VCCA VCCA nQx VEE -0.5V±0.125V 3.3 Core/2.5V LVPECL Output Load Test Circuit 3.3 Core/3.3V LVDS Output Load Test Circuit VCC SCOPE VCC, 2.5V±5% POWER SUPPLY + Float GND – Qx nCLK VCCO V CCA CLK nQx VEE 2.5 Core/2.5V LVDS Output Load Test Circuit IDT8T49N105ANLGI REVISION A MAY 24, 2013 Differential Input Levels 18 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Parameter Measurement Information, continued VOH VREF VOL 1σ contains 68.26% of all measurements 2σ contains 95.4% of all measurements 3σ contains 99.73% of all measurements 4σ contains 99.99366% of all measurements 6σ contains (100-1.973x10-7)% of all measurements Histogram Reference Point Mean Period (Trigger Edge) (First edge after trigger) RMS Phase Jitter Period Jitter nQ nQ Q Q tcycle n tcycle n+1 tjit(cc) = |tcycle n – tcycle n+1| 1000 Cycles Cycle-to-Cycle Jitter Differential Output Duty Cycle/Output Pulse Width/Period nQ nQ 80% 80% VOD Q 20% 20% tR Q tF LVDS Output Rise/Fall Time IDT8T49N105ANLGI REVISION A MAY 24, 2013 LVPECL Output Rise/Fall Time 19 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Parameter Measurement Information, continued Offset Voltage Setup Differential Output Voltage Setup IDT8T49N105ANLGI REVISION A MAY 24, 2013 20 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Applications Information Recommendations for Unused Input and Output Pins Inputs: Outputs: Crystal Inputs LVPECL Outputs For applications not requiring the use of the crystal oscillator input, both XTAL_IN and XTAL_OUT can be left floating. Though not required, but for additional protection, a 1k resistor can be tied from XTAL_IN to ground. All unused LVPECL output pairs can be left floating. We recommend that there is no trace attached. Both sides of the differential output pair should either be left floating or terminated. CLK/nCLK Inputs All unused LVDS output pairs can be either left floating or terminated with 100 across. If they are left floating there should be no trace attached. LVDS Outputs For applications not requiring the use of either differential input, both CLK and nCLK can be left floating. Though not required, but for additional protection, a 1k resistor can be tied from CLK to ground. It is recommended that CLK, nCLK be left unconnected in frequency synthesizer mode. LVCMOS Outputs All unused LVCMOS outputs can be left floating. There should be no trace attached. LVCMOS Control Pins All control pins have internal pullup or pulldown resistors; additional resistance is not required but can be added for additional protection. A 1k resistor can be used. Recommended Values for Low-Bandwidth Mode Loop Filter External loop filter components are not needed in Frequency Synthesizer or High-Bandwidth modes. In Low-Bandwidth mode, the loop filter structure and components are recommended. Please consult IDT if other values are needed. IDT8T49N105ANLGI REVISION A MAY 24, 2013 21 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Wiring the Differential Input to Accept Single-Ended Levels Figure 4 shows how a differential input can be wired to accept single ended levels. The reference voltage VREF = VCC/2 is generated by the bias resistors R1 and R2. The bypass capacitor (C1) is used to help filter noise on the DC bias. This bias circuit should be located as close to the input pin as possible. The ratio of R1 and R2 might need to be adjusted to position the VREF in the center of the input voltage swing. For example, if the input clock swing is 2.5V and VCC = 3.3V, R1 and R2 value should be adjusted to set VREF at 1.25V. The values below are for when both the single ended swing and VCC are at the same voltage. This configuration requires that the sum of the output impedance of the driver (Ro) and the series resistance (Rs) equals the transmission line impedance. In addition, matched termination at the input will attenuate the signal in half. This can be done in one of two ways. First, R3 and R4 in parallel should equal the transmission line impedance. For most 50 applications, R3 and R4 can be 100. The values of the resistors can be increased to reduce the loading for slower and weaker LVCMOS driver. When using single-ended signaling, the noise rejection benefits of differential signaling are reduced. Even though the differential input can handle full rail LVCMOS signaling, it is recommended that the amplitude be reduced. The datasheet specifies a lower differential amplitude, however this only applies to differential signals. For single-ended applications, the swing can be larger, however VIL cannot be less than -0.3V and VIH cannot be more than VCC + 0.3V. Though some of the recommended components might not be used, the pads should be placed in the layout. They can be utilized for debugging purposes. The datasheet specifications are characterized and guaranteed by using a differential signal. Figure 4. Recommended Schematic for Wiring a Differential Input to Accept Single-ended Levels IDT8T49N105ANLGI REVISION A MAY 24, 2013 22 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Overdriving the XTAL Interface The XTAL_IN input can be overdriven by an LVCMOS driver or by one side of a differential driver through an AC coupling capacitor. The XTAL_OUT pin can be left floating. The amplitude of the input signal should be between 500mV and 1.8V and the slew rate should not be less than 0.2V/nS. For 3.3V LVCMOS inputs, the amplitude must be reduced from full swing to at least half the swing in order to prevent signal interference with the power rail and to reduce internal noise. Figure 5A shows an example of the interface diagram for a high speed 3.3V LVCMOS driver. This configuration requires that the sum of the output impedance of the driver (Ro) and the series resistance (Rs) equals the transmission line impedance. In addition, matched termination at the crystal input will attenuate the signal in half. This VCC can be done in one of two ways. First, R1 and R2 in parallel should equal the transmission line impedance. For most 50 applications, R1 and R2 can be 100. This can also be accomplished by removing R1 and changing R2 to 50. The values of the resistors can be increased to reduce the loading for a slower and weaker LVCMOS driver. Figure 5B shows an example of the interface diagram for an LVPECL driver. This is a standard LVPECL termination with one side of the driver feeding the XTAL_IN input. It is recommended that all components in the schematics be placed in the layout. Though some components might not be used, they can be utilized for debugging purposes. The datasheet specifications are characterized and guaranteed by using a quartz crystal as the input. XTAL_OUT R1 100 Ro Rs C1 Zo = 50 ohms XTAL_IN R2 100 Zo = Ro + Rs .1uf LVCMOS Driver Figure 5A. General Diagram for LVCMOS Driver to XTAL Input Interface XTAL_OUT C2 Zo = 50 ohms XTAL_IN .1uf Zo = 50 ohms LVPECL Driver R1 50 R2 50 R3 50 Figure 5B. General Diagram for LVPECL Driver to XTAL Input Interface IDT8T49N105ANLGI REVISION A MAY 24, 2013 23 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Differential Clock Input Interface with the vendor of the driver component to confirm the driver termination requirements. For example, in Figure 6A, the input termination applies for IDT open emitter LVHSTL drivers. If you are using an LVHSTL driver from another vendor, use their termination recommendation. The CLK /nCLK accepts LVDS, LVPECL, LVHSTL, HCSL and other differential signals. Both VSWING and VOH must meet the VPP and VCMR input requirements. Figures 6A to 6E show interface examples for the CLK/nCLK input driven by the most common driver types. The input interfaces suggested here are examples only. Please consult 3.3V 3.3V 3.3V 1.8V Zo = 50Ω Zo = 50Ω CLK CLK Zo = 50Ω Zo = 50Ω nCLK nCLK Differential Input LVHSTL IDT LVHSTL Driver R1 50Ω R2 50Ω Differential Input LVPECL R1 50Ω R2 50Ω R2 50Ω Figure 6B. CLK/nCLK Input Driven by a 3.3V LVPECL Driver Figure 6A. CLK/nCLK Input Driven by an IDT Open Emitter LVHSTL Driver 3.3V 3.3V 3.3V 3.3V 3.3V Zo = 50Ω CLK CLK R1 100Ω nCLK Zo = 50Ω Differential Input LVPECL Figure 6D. CLK/nCLK Input Driven by a 3.3V LVDS Driver Figure 6C. CLK/nCLK Input Driven by a 3.3V LVPECL Driver 3.3V nCLK Receiver LVDS 3.3V *R3 CLK nCLK HCSL *R4 Differential Input Figure 6E. CLK/nCLK Input Driven by a 3.3V HCSL Driver IDT8T49N105ANLGI REVISION A MAY 24, 2013 24 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator LVDS Driver Termination For a general LVDS interface, the recommended value for the termination impedance (ZT) is between 90 and 132. The actual value should be selected to match the differential impedance (Z0) of your transmission line. A typical point-to-point LVDS design uses a 100 parallel resistor at the receiver and a 100 differential transmission-line environment. In order to avoid any transmission-line reflection issues, the components should be surface mounted and must be placed as close to the receiver as possible. IDT offers a full line of LVDS compliant devices with two types of output structures: current source and voltage source. The LVDS Driver standard termination schematic as shown in Figure 7A can be used with either type of output structure. Figure 7B, which can also be used with both output types, is an optional termination with center tap capacitance to help filter common mode noise. The capacitor value should be approximately 50pF. If using a non-standard termination, it is recommended to contact IDT and confirm if the output structure is current source or voltage source type. In addition, since these outputs are LVDS compatible, the input receiver’s amplitude and common-mode input range should be verified for compatibility with the output. ZO  ZT ZT LVDS Receiver Figure 7A. Standard Termination LVDS Driver ZO  ZT C ZT 2 LVDS ZT Receiver 2 Figure 7B. Optional Termination IDT8T49N105ANLGI REVISION A MAY 24, 2013 25 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Termination for 3.3V LVPECL Outputs The clock layout topology shown below is a typical termination for LVPECL outputs. The two different layouts mentioned are recommended only as guidelines. transmission lines. Matched impedance techniques should be used to maximize operating frequency and minimize signal distortion. Figures 8A and 8B show two different layouts which are recommended only as guidelines. Other suitable clock layouts may exist and it would be recommended that the board designers simulate to guarantee compatibility across all printed circuit and clock component process variations. The differential outputs are low impedance follower outputs that generate ECL/LVPECL compatible outputs. Therefore, terminating resistors (DC current path to ground) or current sources must be used for functionality. These outputs are designed to drive 50 R3 125 3.3V R4 125 3.3V 3.3V Zo = 50 + _ LVPECL Input Zo = 50 R1 84 Figure 8A. 3.3V LVPECL Output Termination IDT8T49N105ANLGI REVISION A MAY 24, 2013 R2 84 Figure 8B. 3.3V LVPECL Output Termination 26 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Termination for 2.5V LVPECL Outputs level. The R3 in Figure 9B can be eliminated and the termination is shown in Figure 9C. Figure 9A and Figure 9B show examples of termination for 2.5V LVPECL driver. These terminations are equivalent to terminating 50 to VCCO – 2V. For VCCO = 2.5V, the VCCO – 2V is very close to ground 2.5V VCCO = 2.5V 2.5V 2.5V VCCO = 2.5V R1 250 R3 250 50 + 50 + 50 – 50 2.5V LVPECL Driver – R1 50 2.5V LVPECL Driver R2 62.5 R2 50 R4 62.5 R3 18 Figure 9A. 2.5V LVPECL Driver Termination Example Figure 9B. 2.5V LVPECL Driver Termination Example 2.5V VCCO = 2.5V 50 + 50 – 2.5V LVPECL Driver R1 50 R2 50 Figure 9C. 2.5V LVPECL Driver Termination Example IDT8T49N105ANLGI REVISION A MAY 24, 2013 27 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator VFQFN EPAD Thermal Release Path In order to maximize both the removal of heat from the package and the electrical performance, a land pattern must be incorporated on the Printed Circuit Board (PCB) within the footprint of the package corresponding to the exposed metal pad or exposed heat slug on the package, as shown in Figure 10. The solderable area on the PCB, as defined by the solder mask, should be at least the same size/shape as the exposed pad/slug area on the package to maximize the thermal/electrical performance. Sufficient clearance should be designed on the PCB between the outer edges of the land pattern and the inner edges of pad pattern for the leads to avoid any shorts. and dependent upon the package power dissipation as well as electrical conductivity requirements. Thus, thermal and electrical analysis and/or testing are recommended to determine the minimum number needed. Maximum thermal and electrical performance is achieved when an array of vias is incorporated in the land pattern. It is recommended to use as many vias connected to ground as possible. It is also recommended that the via diameter should be 12 to 13mils (0.30 to 0.33mm) with 1oz copper via barrel plating. This is desirable to avoid any solder wicking inside the via during the soldering process which may result in voids in solder between the exposed pad/slug and the thermal land. Precautions should be taken to eliminate any solder voids between the exposed heat slug and the land pattern. Note: These recommendations are to be used as a guideline only. For further information, please refer to the Application Note on the Surface Mount Assembly of Amkor’s Thermally/ Electrically Enhance Lead frame Base Package, Amkor Technology. While the land pattern on the PCB provides a means of heat transfer and electrical grounding from the package to the board through a solder joint, thermal vias are necessary to effectively conduct from the surface of the PCB to the ground plane(s). The land pattern must be connected to ground through these vias. The vias act as “heat pipes”. The number of vias (i.e. “heat pipes”) are application specific PIN PIN PAD SOLDER EXPOSED HEAT SLUG GROUND PLANE THERMAL VIA SOLDER LAND PATTERN (GROUND PAD) PIN PIN PAD Figure 10. P.C. Assembly for Exposed Pad Thermal Release Path – Side View (drawing not to scale) IDT8T49N105ANLGI REVISION A MAY 24, 2013 28 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Schematic Example Figure 11 shows an example of IDT8T49N105 application schematic. In this example, the device is operated at VDD = VDDA = 3.3V and VDDO_x = 2.5V. The schematic example focuses on functional connections and is not configuration specific. Refer to the pin description and functional tables in the datasheet to ensure that the logic control inputs are properly set. power supply isolation is required. The IDT8T49N105 provides separate power supplies to isolate any high switching noise from coupling into the internal PLL. In order to achieve the best possible filtering, it is recommended that the placement of the filter components be on the device side of the PCB as close to the power pins as possible. If space is limited, the 0.1uf capacitor in each power pin filter should be placed on the device side. The other components can be on the opposite side of the PCB. A 12pF parallel resonant 25MHz crystal is used. For this device, the crystal load capacitors are required for proper operation. The load capacitance, C1 = 5pF and C2 = 5pF, are recommended for frequency accuracy. Depending on the variation of the parasitic stray capacity of the printed circuit board traces between the crystal and the Xtal_In and Xtal_Out pins, the values of C1 and C2 might require a slight adjustment to optimize the frequency accuracy. Crystals with other load capacitance specifications can be used, but this will require adjusting C1 and C2. Power supply filter recommendations are a general guideline to be used for reducing external noise from coupling into the devices. The filter performance is designed for a wide range of noise frequencies. This low-pass filter starts to attenuate noise at approximately 10 kHz. If a specific frequency noise component is known, such as switching power supplies frequencies, it is recommended that component values be adjusted and if required, additional filtering be added. Additionally, good general design practices for power plane voltage stability suggests adding bulk capacitance in the local area of all devices. The ePAD provides a low thermal impedance connection between the internal device and the PCB. It also provides an electrical connection to the die and must be connected to ground. As with any high speed analog circuitry, the power supply pins are vulnerable to random noise. To achieve optimum jitter performance, IDT8T49N105ANLGI REVISION A MAY 24, 2013 29 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Place each 0.1uF bypass cap directly adjacent to its corresponding VCC, VCCA or VCCO pin. C12 0. 1uF C13 0. 1uF FB1 3.3V 2 1 BLM18BB221SN1 C5 10uF C4 0.1uF VCC R1 4.7K 12 16 28 S_A1 S_A0 17 18 R2 4.7K 29 C6 0.1uF PLL_BYPASS CONF IG OE VCC 13 VCC VCC 3 PLL_BYPASS CONF IG OE VCC U1 7 VCC C11 0.1uF 36 VCCA C7 0.1uF S_A1 S_A0 25 14 SCLK C9 BLM18BB221SN1 10uF 30 C1 5 pF X1 37 38 XTAL_OUT XTAL_BAD 40 Z o = 50 Ohm 27 CLK Q nCLK nQ + Z o = 50 Ohm Z o = 50 Ohm CLK1_N6 R4 50 26 - R3 50 R8 50 R5 50 nc nc nc nc nc nc nc nc nc nc nc nc 34 LF1 220k 33 LF0 R31 470k C52 1nF XTAL_BAD Z o = 50 Ohm 5 CLK1_P R30 CLK_BAD CLK_BAD C2 5 pF +3.3V PECL Driver HOLDOVER HOLDOVER 2 XTAL_OUT C8 0.1uF LOCK_IND LOCK_I ND XTAL_IN 25MHz (12pf ) 1 SCLK 1 XTAL_IN FB2 2 VCCO C10 0.1uF SDATA 15 C3 10uF 2.5V VCCO SDATA R9 10 VCCA C24 10nF ePAD 41 35 VEE VEE 21 8 VEE 1uF +2.5V PECL Rec eiv er R7 18 Logic Control Input E xamples VCC Set Logic Input to '1' RU1 1K C25 3-pole loop filter - (optional) 39 32 31 24 23 22 20 19 11 10 9 4 R6 50 VCC Set Logic Input to '0' RU2 Not I ns tall To Logic Input pins RD1 Not Install To Logic Input pins RD2 1K Figure 11. IDT8T49N105I Schematic Example IDT8T49N105ANLGI REVISION A MAY 24, 2013 30 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator LVPECL Power Considerations This section provides information on power dissipation and junction temperature for the IDT8T49N105I. Equations and example calculations are also provided. 1. Power Dissipation. The total power dissipation for the IDT8T49N105I is the sum of the core power plus the power dissipated in the load(s). The following is the power dissipation for VCC = 3.3V + 5% = 3.465V, which gives worst case results. NOTE: Please refer to Section 3 for details on calculating power dissipated in the load. • Power (core)MAX = VCC_MAX * IEE_MAX = 3.465V * 332mA = 1150.4W • Power (outputs)MAX = 33.2mW/Loaded Output pair Total Power_MAX (3.465V, with all outputs switching) = 1150.4mW + 33.2mW = 1183.6mW 2. Junction Temperature. Junction temperature, Tj, is the temperature at the junction of the bond wire and bond pad directly affects the reliability of the device. The maximum recommended junction temperature is 125°C. Limiting the internal transistor junction temperature, Tj, to 125°C ensures that the bond wire and bond pad temperature remains below 125°C. The equation for Tj is as follows: Tj = JA * Pd_total + TA Tj = Junction Temperature JA = Junction-to-Ambient Thermal Resistance Pd_total = Total Device Power Dissipation (example calculation is in section 1 above) TA = Ambient Temperature In order to calculate junction temperature, the appropriate junction-to-ambient thermal resistance JA must be used. Assuming no air flow and a multi-layer board, the appropriate value is 32.4°C/W per Table 9 below. Therefore, Tj for an ambient temperature of 85°C with all outputs switching is: 85°C + 1.184W * 32.4°C/W = 123.4°C. This is below the limit of 125°C. This calculation is only an example. Tj will obviously vary depending on the number of loaded outputs, supply voltage, air flow and the type of board (multi-layer). Table 9. Thermal Resistance JA for 40 Lead VFQFN, Forced Convection JA by Velocity Meters per Second Multi-Layer PCB, JEDEC Standard Test Boards IDT8T49N105ANLGI REVISION A MAY 24, 2013 0 1 2.5 32.4°C/W 25.7°C/W 23.4°C/W 31 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator 3. Calculations and Equations. The purpose of this section is to calculate the power dissipation for the LVPECL output pairs. LVPECL output driver circuit and termination are shown in Figure 12. VCCO Q1 VOUT RL 50Ω VCCO - 2V Figure 12. LVPECL Driver Circuit and Termination To calculate worst case power dissipation into the load, use the following equations which assume a 50 load, and a termination voltage of VCCO – 2V. • For logic high, VOUT = VOH_MAX = VCCO_MAX – 0.7V (VCCO_MAX – VOH_MAX) = 0.7V • For logic low, VOUT = VOL_MAX = VCCO_MAX – 1.5V (VCCO_MAX – VOL_MAX) = 1.5V Pd_H is power dissipation when the output drives high. Pd_L is the power dissipation when the output drives low. Pd_H = [(VOH_MAX – (VCCO_MAX – 2V))/RL] * (VCCO_MAX – VOH_MAX) = [(2V – (VCCO_MAX – VOH_MAX))/RL] * (VCCO_MAX – VOH_MAX) = [(2V – 0.7V)/50] * 0.7V = 18.2mW Pd_L = [(VOL_MAX – (VCCO_MAX – 2V))/RL] * (VCCO_MAX – VOL_MAX) = [(2V – (VCCO_MAX – VOL_MAX))/RL] * (VCCO_MAX – VOL_MAX) = [(2V – 1.5V)/50] * 1.5V = 15mW Total Power Dissipation per output pair = Pd_H + Pd_L = 33.2mW IDT8T49N105ANLGI REVISION A MAY 24, 2013 32 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator LVDS Power Considerations This section provides information on power dissipation and junction temperature for the IDT8T49N203I. Equations and example calculations are also provided. 1. Power Dissipation. The total power dissipation for the IDT8T49N203I is the sum of the core power plus the power dissipated in the load(s). The following is the power dissipation for VCC = 3.3V + 5% = 3.465V, which gives worst case results. NOTE: Please refer to Section 3 for details on calculating power dissipated in the load. • Power (core)MAX = VCC_MAX * (ICC_MAX + ICCA_MAX) = 3.465V * (284mA + 30mA) = 1088.01mW • Power (outputs)MAX = VCCO_MAX * ICCO_MAX = 3.465V * 22mA = 76.23mW Total Power_MAX = 1088.01mW + 76.23mW = 1164.33mW 2. Junction Temperature. Junction temperature, Tj, is the temperature at the junction of the bond wire and bond pad directly affects the reliability of the device. The maximum recommended junction temperature is 125°C. Limiting the internal transistor junction temperature, Tj, to 125°C ensures that the bond wire and bond pad temperature remains below 125°C. The equation for Tj is as follows: Tj = JA * Pd_total + TA Tj = Junction Temperature JA = Junction-to-Ambient Thermal Resistance Pd_total = Total Device Power Dissipation (example calculation is in section 1 above) TA = Ambient Temperature In order to calculate junction temperature, the appropriate junction-to-ambient thermal resistance JA must be used. Assuming no air flow and a multi-layer board, the appropriate value is 32.4°C/W per Table 10 below. Therefore, Tj for an ambient temperature of 85°C with all outputs switching is: 85°C + 1.164W * 32.4°C/W = 122.7°C. This is below the limit of 125°C. This calculation is only an example. Tj will obviously vary depending on the number of loaded outputs, supply voltage, air flow and the type of board (multi-layer). Table 10. Thermal Resistance JA for 40 Lead VFQFN, Forced Convection JA by Velocity Meters per Second Multi-Layer PCB, JEDEC Standard Test Boards IDT8T49N105ANLGI REVISION A MAY 24, 2013 0 1 2.5 32.4°C/W 25.7°C/W 23.4°C/W 33 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Reliability Information Table 11. JA vs. Air Flow Table for a 40 Lead VFQFN JA vs. Air Flow Meters per Second Multi-Layer PCB, JEDEC Standard Test Boards 0 1 2.5 32.4°C/W 25.7°C/W 23.4°C/W Transistor Count The transistor count for IDT8T49N105I is: TBD IDT8T49N105ANLGI REVISION A MAY 24, 2013 34 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator 40 Lead VFQFN Package Outline and Package Dimensions IDT8T49N105ANLGI REVISION A MAY 24, 2013 35 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator 40 Lead VFQFN Package Outline and Package Dimensions, continued 40 Lead VFQFN, D2/E2 EPAD Dimensions: 4.65mm x 4.65mm IDT8T49N105ANLGI REVISION A MAY 24, 2013 36 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator Ordering Information Table 12. Ordering Information Part/Order Number Marking Package Shipping Packaging Temperature 8T49N105A-dddNLGI IDT8T49N105A-dddNLGI “Lead-Free” 40 Lead VFQFN Tray -40C to +85C 8T49N105A-dddNLGI8 IDT8T49N105A-dddNLGI “Lead-Free” 40 Lead VFQFN Tape & Reel -40C to +85C NOTE: For the specific -ddd order codes, refer to FemtoClock NG Universal Frequency Translator Ordering Product Information document. IDT8T49N105ANLGI REVISION A MAY 24, 2013 37 ©2013 Integrated Device Technology, Inc. IDT8T49N105I Data Sheet FemtoClock® NG Universal Frequency Translator We’ve Got Your Timing Solution 6024 Silver Creek Valley Road San Jose, California 95138 Sales 800-345-7015 (inside USA) +408-284-8200 (outside USA) Fax: 408-284-2775 www.IDT.com/go/contactIDT Technical Support Sales netcom@idt.com +480-763-2056 DISCLAIMER Integrated Device Technology, Inc. (IDT) and its subsidiaries reserve the right to modify the products and/or specifications described herein at any time and at IDT’s sole discretion. All information in this document, including descriptions of product features and performance, is subject to change without notice. Performance specifications and the operating parameters of the described products are determined in the independent state and are not guaranteed to perform the same way when installed in customer products. The information contained herein is provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the suitability of IDT’s products for any particular purpose, an implied warranty of merchantability, or non-infringement of the intellectual property rights of others. This document is presented only as a guide and does not convey any license under intellectual property rights of IDT or any third parties. IDT’s products are not intended for use in applications involving extreme environmental conditions or in life support systems or similar devices where the failure or malfunction of an IDT product can be reasonably expected to significantly affect the health or safety of users. Anyone using an IDT product in such a manner does so at their own risk, absent an express, written agreement by IDT. Integrated Device Technology, IDT and the IDT logo are registered trademarks of IDT. Other trademarks and service marks used herein, including protected names, logos and designs, are the property of IDT or their respective third party owners. Copyright 2013. All rights reserved.