Specify the JESD204C interface mode. See Table 7-22.

Note: This register should only be changed when JESD_EN=0.

Specify the number of sample streams to enable (JESD204C M parameter). The supported settings for JESD_M depend on the DUC interpolation (DUC_L) and Mx.

L_DUC: Supported Settings for JESD_M

1x: 1 or 2 (but never larger than Mx)

2x or 3x: 2 (but never larger than Mx)

4x or 6x: 2 or 4 (but never larger than Mx)

8x or higher:2, 4, 6 or 8 (but never larger than Mx)

See Table 7-22 for the Mx value associated with each JMODE. The number of lanes enabled (L) is computed as: L=ceiling(M/Mx*Lx). An I/Q pair counts as two streams. For example, when inputting 4 IQ streams, program JESD_M=8.

Note: This register should only be changed when JESD_EN=0 and DP_EN=0.

0 : JESD204C standard mode (default)

1 : TI Mode - set this when using TI FPGA transmitter IP

Specify how the elastic buffer is released:

0 : Subclass 0 operation (default). Release the elastic buffer immediately once all lanes have starting writing to the buffer.

1 : Subclass 1 operation. Release the elastic buffer on a release opportunity defined by the LMFC/LEMC and RBD.

0 : Use 8b/10b link layer

1 : Use 64b/66b link layer

K is the number of frames per multiframe, and K-1 shall be programmed here when using the 8b/10b link layer (see JENC). Depending on the JMODE setting, there are constraints on the legal values of K (see Table 7-22 and KR). Programming an illegal value for K will cause the link to malfunction.

The default value is KM1=31, which corresponds to K=32.

Note: For modes using the 64b/66b link layer, the KM1 register is ignored. The effective value of K is 256*E/F.

Note: This register should only be changed when JESD_EN=0.

This register shifts the elastic buffer release opportunities. Increasing RBD by 1 delays the release opportunities by 4 bytes (octets).

The legal RBD range is 0 to K*F/4-1.

For 64b/66b modes, the legal RBD range is 0 to 63.

See Programming RBD.

Note: This register should only be changed when JESD_EN=0.

When set, indicates that the JESD204C link is up (elastic buffer released).

Returns the state of the JESD204C SYNC signal.

0 : SYNC asserted

1 : SYNC de-asserted

When any clock dividers or the LMFC/LEMC counters are realigned by SYSREF, this bit gets set. Write a 1 to clear this bit.

The behavior of this bit is undefined when SUBCLASS=0.

Specifies the frequency divisor to generate the PHY PLL reference clock (FREF) from the DAC clock (F_CLK). See PLL Control.

The following values are legal: 2, 3, 4, 5, 6, 8, 10, 12, 16, 20, 24, 32, 40, 48. All other values are reserved and produce undefined behavior.

PRBS Test Modes:

0 : Test mode disabled. Normal operation (default)

1 : PRBS7 test mode

2 : PRBS9 test mode

3 : PRBS15 test mode

4 : PRBS31 test mode

5-31: RESERVED

When a PRBS test mode is enabled, see BER_EN.

This register determines how much the watchdog counter is decremented when the link is up and CRC_FAULT is not set.

JTR : Watchdog Counter Decrement : Approximate Link Uptime % required to prevent the SerDes from being reset

0 : 1 : 99.25%

1 : 2 : 98.46%

2 : 8 : 94.12%

3 : 16 : 88.89%

Specifies the pulse width of SYNC that is used for reporting errors to the transmitter. When an error is detected that does not require link resynchronization, SYNC is asserted for SYNC_EPW link clock cycles (equal to 4*SYNC_EPW character durations). To disable error reporting over SYNC, set SYNC_EPW=0. The legal range for SYNC_EPW is 0 to 7.

Note: This register should only be changed when JESD_EN= 0.

Specify how many contiguous, error-free multiblocks must be received to reset the CRC error counter (and un-trigger the CRC alarm if triggered).

0 : 1 multiblock

1 : 4 multiblocks

2 : 16 multiblocks

3 : 64 multiblocks

Specify how many multi-blocks must have CRC errors to trigger the CRC alarm. The receiver counts each error, but if a run of error-free multi-blocks occurs (as specified by CRC_ERR_REC), the error counter resets.

0 : 1 multiblock

1 : 2 multiblocks

2 : 4 multiblocks

3 : 8 multiblocks

Note: For each lane, the internal signal, CRC_FAULT, is set if the number of multi-blocks with CRC errors exceeds the threshold set by CRC_ERR_TH without a run of contiguous, error-free multi-blocks specified by CRC_ERR_REC. CRC_FAULT is cleared when a run of contiguous, error-free multi-blocks specified by CRC_ERR_REC is detected.

Note: This register should only be changed when JESD_EN=0.

This bit is set when lane arrival times are captured and available for read in LANE_ARR. Lane arrival data is captured when all lanes are ready and the chip attempts to release the elastic buffer. This bit is cleared when JESD_EN=0 or JESD_RST=1.

Specify which physical lane (0 to 15) is bound to logical lane n. To bind physical lane p to logical lane n, program LANE_SEL[n]=p. For example, to bind logical lane 0 to physical lane 3, program LANE_SEL[0]=3.

Note: This register should only be changed when JESD_EN=0.

Returns the arrival time of lane n with respect to the internal LMFC/LEMC that is established by SYSREF. The value returned can be between 0 and 63 (inclusive), regardless of the multiframe/EMB length. These registers are valid only when LANE_ARR_RDY =1. See Programming RBD.

Note: The lane arrival data is captured when attempting to release the elastic buffer and LANE_ARR_RDY=0. All values are from the same release attempt.

Returns 1 if logical lane n has frame or EMB synchronization.

Returns 1 if logical lane n has code-group or block synchronization.

Returns 1 if logical lane n is detecting a data signal (using loss-of-signal detector in PHY).

This register returns the difference between the write and read pointers inside the gearbox FIFO for logical lane n.

For 8b/10b, values from 0-14 will be returned. For 64b/66b, values from 0-16 will be returned.

The values at the ends of the range (0 & 14 for 8b/10b or 0 & 16 for 64b/66b) indicate error positions that will cause the Gearbox FIFO overflow/underflow flag to be set in LANE_ERR. In both cases, 1 indicates minimum setup and the max value minus 1 indicates minimum hold.

Values are measured in the read clock. The tread size is approximately ½ of the effective link layer clock period (0.5/(LCR*FDR)). In terms of UI:

• In 8b/10b mode, the nominal tread size is 20UI. The nominal tread size for the final tread (14) is 380UI±20UI.

• In 64b/66b mode, the nominal tread size is 16.5UI. The nominal tread size for the final tread (16) is 412.5UI±16.5UI.

The PDIFF[n] value for disabled lanes and lanes enabled by EXTRA_LANE are undefined.

Control CDR (clock-data-recovery) setting. The default value should be appropriate, but other settings can be used to adjust the tracking rate or reduce CDR power consumption. The 2nd order modes are for tracking a frequency offset when the Tx and Rx do not share a common reference clock. This is not applicable to JESD204C. See CDR Settings.

0x1F: 365 MHz (default setting for full and half-rate, RATE = 0 or 1)

0x1E: 275 MHz

0x1D: 195 MHz

0x1B: 140 MHz (default setting for quarter-rate mode, RATE = 2)

0x19: 105 MHz

0x10: 75 MHz

0x08: 55 MHz (default setting for eighth-rate, RATE = 3)

0x00: 50 MHz

Controls EQ boost for physical lane n.

EQBOOST : GAIN Boost : BW Change : Power Increase

0 : 0dB : 0% : 0mW

1 : 2dB : -30% : 0mW

2 : 4dB : +10% : 5mW

3 : 6dB : -20% : 5mW

When EQ_OVR=1, this field controls the equalization level for lane n. The valid range is from 0 (least equalization) to 16 (most equalization).

Specify the length of the eye-scan test. Larger values will give more consistent results, but will take longer.

ESLEN : Number of Samples Analyzed

0 : 127

1 : 1032

2 : 8191

3 : 65535

Note: Many eye-scan modes only analyze zeros (or ones). Since they don’t analyze every sample, those modes will take longer to complete compared to a mode that analyzes all samples.

Specify the eye-scan mode. Applies to all lanes.

ES : Eye-Scan Mode

0 : Eye-scan disabled (default)

1 : Compare. Counts mismatches between the normal sampler and the eye-scan sampler. Analyzes zeros and ones.

2 : Compare zeros. Same as ES=1, but only analyzes zeros.

3 : Compare ones. Same as ES=1, but only analyzes ones.

4 : Count ones. Increments ECOUNTn when the eye-scan sample is 1.

5-7 : RESERVED

8 : Average zero. Adjusts ESVO_Sn to the average voltage for a zero.

9 : Outer zero. Adjusts ESVO_Sn to the lowest voltage for a zero.

10 : Inner zero. Adjusts ESVO_Sn to the highest voltage for a zero.

11 : RESERVED

12 : Average one. Adjusts ESVO_Sn to the average voltage for a one.

13 : Outer one. Adjusts ESVO_Sn to the highest voltage for a one.

14 : Inner one. Adjusts ESVO_Sn to the lowest voltage for a one.

15 : RESERVED

Eye-scan phase offset for all lanes. This adjusts the sampling instant of the eye-scan sampler compared to the normal sampler. This is a signed value from -64 to +63 and the step size is 1/32th of a UI.

Note: Only change this register while ESRUN=0.

Eye-scan voltage offset for all lanes. This adjusts the voltage threshold of the eye-scan sampler. This is a signed value from -32 to +31. The step size is about 10mV (giving an adjustment range of about -320mV to +310mV). This field is ignored for eye-scan modes that adjust the voltage offset automatically and return a result on ESVO_S[n].

Note: This register should only be changed when ESRUN=0.

Eye-scan only runs on every 20th bit. This field specifies which bit position the eye-scan runs on (valid range is 0 to 19). Eye-scans may be run with all possible values of ES_BIT_SELECT and the results combined. Alternatively, results can be kept separate to see the effects of any duty cycle distortion / repetitive jitter.

Note: This register should only be changed when ESRUN=0.

Specifies the threshold for the loss-of-signal detector. Applies when LOS_EN=1. Affects all lanes.

LOS_TH : Approximate Threshold (mV)

0, 1 : RESERVED

2 - 15 : 15*(LOS_TH)

Equalizer counter size: Adjusts how many votes must be accumulated to cause the adaptive equalizer gain to change. Affects all lanes. This is for debug purposes only and the user should generally not need to change this setting.

EQCNTSZ : Equalizer Vote Counter Size (votes required to adjust gain)

0 : (default) 511

1 : RESERVED

2 : 1

3 : 3

4 : 7

5 : 15

6 : 31

7 : 63

8 : 127

9 : 255

10-15 : RESERVED

bit 0: lanes 0 - 3

bit 1: lanes 4 - 7

bit 2: lanes 8 - 11

bit 3: lanes 12 - 15

Setting this bit enables datapath operation. When cleared, the datapath is held in reset. This bit should be set after the chip is configured for proper operation.

Note: This register should only be changed from 0 to 1 when FUSE_DONE=1.

DUC Interpolation Factor

0: 1x

1: 2x

2: 3x

3: 4x

4: 6x

5: 8x

6: 12x

7: 16x

8: 24x

9: 32x

10: 48x

11: 64x

12: 96x

13: 128x

14: 192x

15: 256x

Note: This register should only be changed when JESD_EN=0 and DP_EN=0.

0: DUC outputs are real (DUC mixer converts complex to real by discarding the imaginary part). Up to 4 DUCs can be enabled.

1: DUC outputs are complex. Up to 2 DUCs can be enabled (DUC0 and DUC1).

Note: This register should only be changed when DP_EN=0.

Specify the DAC pulse format for DACB.

0: Normal mode (non-return-to-zero or NRZ) (sinc nulls at n*FS)

1: RF Mode (return to inverse or RTI) (sinc nulls at DC and 2n*FS)

2: Return-to-Zero (RTZ) (sinc nulls at 2n*FS)

3: DES2X – Samples provided by the DES interpolator (low-pass mode)

4: DES2XH – Samples provided by the DES interpolator (high-pass mode)

5: DES1X – Both samples are provided by the input stream

6: Disabled – DACA is disabled

7: RESERVED

Note: If either MXMODE1 or MXMODE0 is set to DES1X, the other must be set to either DES1X or Disabled. User must also set DUC_L=0.

Specify the DAC pulse format for DACA.

0: Normal mode (non-return-to-zero or NRZ) (sinc nulls at n*FS)

1: RF Mode (return to inverse or RTI) (sinc nulls at DC and 2n*FS)

2: Return-to-Zero (RTZ) (sinc nulls at 2n*FS)

3: DES2X – Samples provided by the DES interpolator (low-pass mode)

4: DES2XH – Samples provided by the DES interpolator (high-pass mode)

5: DES1X – Both samples are provided by the input stream

6: Disabled – DACA is disabled

7: RESERVED

Note: If either MXMODE1 or MXMODE0 is set to DES1X, the other must be set to either DES1X or Disabled. User must also set DUC_L=0.

0: Transmission is disabled after DEM and dither by sending a static aging safe code. For some configurations and frequencies, the outputs will have higher noise than a static mid-scale code would normally have. However, this mode has the lowest latency from transmit enable to DAC output.

1: When transmission is disabled, the input to DEM and dither is muted to minimize the output noise. This increases the latency from transmit enable to DAC output by 56 DAC clocks

Note: This bit may only be set when FAST_TX_EN=1.

0: When the transmit enables are both low, JESD and datapath clocks are shutdown to save power. When transmission is re-enabled the outputs remain muted until valid data is available at the output.

1: No power saving is performed and transmit enables can be used independently. Latency from transmit enable to DAC outputs is reduced in this mode.

0: DACB is controlled by the TXEN1 ball. In this mode, TX_EN1 register is ignored.

1: DACB is controlled by the TX_EN1 register. In this mode the TXEN1 ball input does not affect the transmit enable for DACB.

Note: USE_TX_EN1 and USE_TX_EN0 should be programmed to the same value (individual channel control is not supported).

0: DACA is controlled by the TXEN0 ball. In this mode, TX_EN0 register is ignored.

1: DACA is controlled by the TX_EN0 register. In this mode the TXEN0 ball input does not affect the transmit enable for DACA.

Note: USE_TX_EN1 and USE_TX_EN0 should be programmed to the same value (individual channel control is not supported).

Note: TX_EN1 and TX_EN0 should be programmed to the same value (individual channel control is not supported).

Note: TX_EN1 and TX_EN0 should be programmed to the same value (individual channel control is not supported).

For each bit NCO_CONT[n], if set, NCOn operates in phase-continuous mode. This means that frequency changes occur without seeding the phase accumulator. If the bit is clear, NCOn operates in phase-coherent mode. During frequency changes, the phase accumulator is seeded from a main counter. This means that if changing from frequency A to B and then back to A, the phase returns to what it would have been if the change never occurred.

Note: This register should only be changed when DP_EN=0.

If FR_EN=0:

This register determines how NCO synchronization events will be triggered. This includes both accumulator resets specified by NCO_AR and the application of changes to NCO_DITH_EN, FREQ, and PHASE.

0: Setting SPI_SYNC will immediately perform specified events. (All will occur in the same clock cycle.)

1: Setting SPI_SYNC will cause the specified events to occur on the next SYSREF rising edge.

2: While SPI_SYNC is high, the specified events will occur on every SYSREF rising edge.

3: While SPI_SYNC is high, the LSb of the “I” input to DUC0 will cause the specified events. To trigger the event, the LSb must be low for 4 or more consecutive samples and then high for 4 consecutive samples. The sync will occur coincident with the 4th high sample arriving at the DUC0 input.

If FR_EN=1:

This register determines how NCO synchronization events will be triggered. This includes both accumulator resets specified by FR_NCO_AR and the application of changes to FR_NCO_DITH_EN, FR_FREQL, FR_FREQS, and FR_PHASE.

0: If FRS is set, the specified events is performed at the rising edge of FRCS. (All will occur in the same clock cycle.)

1: Reserved

2: RESERVED

3: If FRS is set, the LSb of the “I” input to DUC0 will cause the specified events following the rising edge of FRCS. To trigger the event, the LSb must be low for 4 or more consecutive samples and then high for 4 consecutive samples. The sync will occur coincident with the 4th high sample arriving at the DUC0 input. While waiting for the LSb trigger, zero will be used for the LSb data. The LSb will immediately return to being used as data after the 4th consecutive high sample.

Note: This register should only be changed when SPI_SYNC=0 and the FR interface is idle (FRCS=1).

For each bit NCO_AR[n], if set, the accumulator for NCOn will be reset on every sync event specified by NCO_SYNC_SRC.

Note: This register has no effect when FR_EN=1.

Writing ‘1’ to this register when it is ‘0’ will trigger synchronization events that are bound to this register (see NCO_SYNC_SRC). This register will return the last value written.

Note: Whether this register is edge or level sensitive depends on the setting for NCO_SYNC_SRC.

Note: This register has no effect when FR_EN=1.