SBAS860 August   2017 ADC31RF80

PRODUCTION DATA.  

  1. Features
  2. Applications
  3. Description
  4. Revision History
  5. Pin Configuration and Functions
  6. Specifications
    1. 6.1  Absolute Maximum Ratings
    2. 6.2  ESD Ratings
    3. 6.3  Recommended Operating Conditions
    4. 6.4  Thermal Information
    5. 6.5  Electrical Characteristics
    6. 6.6  AC Performance Characteristics: fS = 2949.12 MSPS
    7. 6.7  AC Performance Characteristics: fS = 2457.6 MSPS (Performance Optimized for F + A + D Band)
    8. 6.8  AC Performance Characteristics: fS = 2457.6 MSPS (Performance Optimized for F + A Band)
    9. 6.9  Digital Requirements
    10. 6.10 Timing Requirements
    11. 6.11 Typical Characteristics
  7. Parameter Measurement Information
    1. 7.1 Input Clock Diagram
  8. Detailed Description
    1. 8.1 Overview
    2. 8.2 Functional Block Diagram
    3. 8.3 Feature Description
      1. 8.3.1  Analog Inputs
        1. 8.3.1.1 Input Clamp Circuit
      2. 8.3.2  Clock Input
      3. 8.3.3  SYSREF Input
        1. 8.3.3.1 Using SYSREF
        2. 8.3.3.2 Frequency of the SYSREF Signal
      4. 8.3.4  DDC Block
        1. 8.3.4.1 Operating Mode: Receiver
        2. 8.3.4.2 Operating Mode: Wide-Bandwidth Observation Receiver
        3. 8.3.4.3 Decimation Filters
          1. 8.3.4.3.1  Divide-by-4
          2. 8.3.4.3.2  Divide-by-6
          3. 8.3.4.3.3  Divide-by-8
          4. 8.3.4.3.4  Divide-by-9
          5. 8.3.4.3.5  Divide-by-10
          6. 8.3.4.3.6  Divide-by-12
          7. 8.3.4.3.7  Divide-by-16
          8. 8.3.4.3.8  Divide-by-18
          9. 8.3.4.3.9  Divide-by-20
          10. 8.3.4.3.10 Divide-by-24
          11. 8.3.4.3.11 Divide-by-32
          12. 8.3.4.3.12 Latency With Decimation Options
        4. 8.3.4.4 Numerically-Controlled Oscillators (NCOs) and Mixers
      5. 8.3.5  NCO Switching
      6. 8.3.6  SerDes Transmitter Interface
      7. 8.3.7  Eye Diagrams
      8. 8.3.8  Alarm Outputs: Power Detectors for AGC Support
        1. 8.3.8.1 Absolute Peak Power Detector
        2. 8.3.8.2 Crossing Detector
        3. 8.3.8.3 RMS Power Detector
        4. 8.3.8.4 GPIO AGC MUX
      9. 8.3.9  Power-Down Mode
      10. 8.3.10 ADC Test Pattern
        1. 8.3.10.1 Digital Block
        2. 8.3.10.2 Transport Layer
        3. 8.3.10.3 Link Layer
    4. 8.4 Device Functional Modes
      1. 8.4.1 Device Configuration
      2. 8.4.2 JESD204B Interface
        1. 8.4.2.1 JESD204B Initial Lane Alignment (ILA)
        2. 8.4.2.2 JESD204B Frame Assembly
        3. 8.4.2.3 JESD204B Frame Assembly with Decimation (Single-Band DDC): Complex Output
        4. 8.4.2.4 JESD204B Frame Assembly with Decimation (Single-Band DDC): Real Output
        5. 8.4.2.5 JESD204B Frame Assembly with Decimation (Single-Band DDC): Real Output
        6. 8.4.2.6 JESD204B Frame Assembly with Decimation (Dual-Band DDC): Complex Output
        7. 8.4.2.7 JESD204B Frame Assembly with Decimation (Dual-Band DDC): Real Output
      3. 8.4.3 Serial Interface
        1. 8.4.3.1 Serial Register Write: Analog Bank
        2. 8.4.3.2 Serial Register Readout: Analog Bank
        3. 8.4.3.3 Serial Register Write: Digital Bank
        4. 8.4.3.4 Serial Register Readout: Digital Bank
        5. 8.4.3.5 Serial Register Write: Decimation Filter and Power Detector Pages
    5. 8.5 Register Maps
      1. 8.5.1  Example Register Writes
      2. 8.5.2  Register Descriptions
        1. 8.5.2.1 General Registers
          1. 8.5.2.1.1 Register 000h (address = 000h), General Registers
          2. 8.5.2.1.2 Register 002h (address = 002h), General Registers
          3. 8.5.2.1.3 Register 003h (address = 003h), General Registers
          4. 8.5.2.1.4 Register 004h (address = 004h), General Registers
          5. 8.5.2.1.5 Register 010h (address = 010h), General Registers
          6. 8.5.2.1.6 Register 011h (address = 011h), General Registers
          7. 8.5.2.1.7 Register 012h (address = 012h), General Registers
      3. 8.5.3  Master Page (M = 0)
        1. 8.5.3.1 Register 020h (address = 020h), Master Page
        2. 8.5.3.2 Register 032h (address = 032h), Master Page
        3. 8.5.3.3 Register 039h (address = 039h), Master Page
        4. 8.5.3.4 Register 03Ch (address = 03Ch), Master Page
        5. 8.5.3.5 Register 05Ah (address = 05Ah), Master Page
        6. 8.5.3.6 Register 03Dh (address = 3Dh), Master Page
        7. 8.5.3.7 Register 057h (address = 057h), Master Page
        8. 8.5.3.8 Register 058h (address = 058h), Master Page
      4. 8.5.4  ADC Page (FFh, M = 0)
        1. 8.5.4.1 Register 03Fh (address = 03Fh), ADC Page
        2. 8.5.4.2 Register 042h (address = 042h), ADC Page
      5. 8.5.5  Digital Function Page (610000h, M = 1)
        1. 8.5.5.1 Register A6h (address = 0A6h), Digital Function Page
      6. 8.5.6  Offset Corr Page (610000h, M = 1)
        1. 8.5.6.1 Register 034h (address = 034h), Offset Corr Page
        2. 8.5.6.2 Register 068h (address = 068h), Offset Corr Page
      7. 8.5.7  Digital Gain Page (610005h, M = 1)
        1. 8.5.7.1 Register 0A6h (address = 0A6h), Digital Gain Page
      8. 8.5.8  Main Digital Page (680000h, M = 1)
        1. 8.5.8.1  Register 000h (address = 000h), Main Digital Page
        2. 8.5.8.2  Register 0A2h (address = 0A2h), Main Digital Page
        3. 8.5.8.3  Register 0A5h (address = 0A5h), Main Digital Page
        4. 8.5.8.4  Register 0A9h (address = 0A9h), Main Digital Page
        5. 8.5.8.5  Register 0B0h (address = 0B0h), Main Digital Page
        6. 8.5.8.6  Register 0B1h (address = 0B1h), Main Digital Page
        7. 8.5.8.7  Register 0B2h (address = 0B2h), Main Digital Page
        8. 8.5.8.8  Register 0B3h (address = 0B3h), Main Digital Page
        9. 8.5.8.9  Register 0B4h (address = 0B4h), Main Digital Page
        10. 8.5.8.10 Register 0B5h (address = 0B5h), Main Digital Page
        11. 8.5.8.11 Register 0B6h (address = 0B6h), Main Digital Page
        12. 8.5.8.12 Register 0B7h (address = 0B7h), Main Digital Page
        13. 8.5.8.13 Register 0B8h (address = 0B8h), Main Digital Page
        14. 8.5.8.14 Register 0B9h (address = 0B9h), Main Digital Page
        15. 8.5.8.15 Register 0BAh (address = 0BAh), Main Digital Page
        16. 8.5.8.16 Register 0BBh (address = 0BBh), Main Digital Page
      9. 8.5.9  JESD Digital Page (6900h, M = 1)
        1. 8.5.9.1  Register 001h (address = 001h), JESD Digital Page
        2. 8.5.9.2  Register 002h (address = 002h ), JESD Digital Page
        3. 8.5.9.3  Register 003h (address = 003h), JESD Digital Page
        4. 8.5.9.4  Register 004h (address = 004h), JESD Digital Page
        5. 8.5.9.5  Register 006h (address = 006h), JESD Digital Page
        6. 8.5.9.6  Register 007h (address = 007h), JESD Digital Page
        7. 8.5.9.7  Register 016h (address = 016h), JESD Digital Page
        8. 8.5.9.8  Register 017h (address = 017h), JESD Digital Page
        9. 8.5.9.9  Register 032h-035h (address = 032h-035h), JESD Digital Page
        10. 8.5.9.10 Register 036h (address = 036h), JESD Digital Page
        11. 8.5.9.11 Register 037h (address = 037h), JESD Digital Page
        12. 8.5.9.12 Register 03Ch (address = 03Ch), JESD Digital Page
        13. 8.5.9.13 Register 03Eh (address = 03Eh), JESD Digital Page
      10. 8.5.10 Decimation Filter Page
        1. 8.5.10.1  Register 000h (address = 000h), Decimation Filter Page
        2. 8.5.10.2  Register 001h (address = 001h), Decimation Filter Page
        3. 8.5.10.3  Register 002h (address = 2h), Decimation Filter Page
        4. 8.5.10.4  Register 005h (address = 005h), Decimation Filter Page
        5. 8.5.10.5  Register 007h (address = 007h), Decimation Filter Page
        6. 8.5.10.6  Register 008h (address = 008h), Decimation Filter Page
        7. 8.5.10.7  Register 009h (address = 009h), Decimation Filter Page
        8. 8.5.10.8  Register 00Ah (address = 00Ah), Decimation Filter Page
        9. 8.5.10.9  Register 00Bh (address = 00Bh), Decimation Filter Page
        10. 8.5.10.10 Register 00Ch (address = 00Ch), Decimation Filter Page
        11. 8.5.10.11 Register 00Dh (address = 00Dh), Decimation Filter Page
        12. 8.5.10.12 Register 00Eh (address = 00Eh), Decimation Filter Page
        13. 8.5.10.13 Register 00Fh (address = 00Fh), Decimation Filter Page
        14. 8.5.10.14 Register 010h (address = 010h), Decimation Filter Page
        15. 8.5.10.15 Register 011h (address = 011h), Decimation Filter Page
        16. 8.5.10.16 Register 014h (address = 014h), Decimation Filter Page
        17. 8.5.10.17 Register 016h (address = 016h), Decimation Filter Page
        18. 8.5.10.18 Register 01Eh (address = 01Eh), Decimation Filter Page
        19. 8.5.10.19 Register 01Fh (address = 01Fh), Decimation Filter Page
        20. 8.5.10.20 Register 033h-036h (address = 033h-036h), Decimation Filter Page
        21. 8.5.10.21 Register 037h (address = 037h), Decimation Filter Page
        22. 8.5.10.22 Register 038h (address = 038h), Decimation Filter Page
        23. 8.5.10.23 Register 039h (address = 039h), Decimation Filter Page
        24. 8.5.10.24 Register 03Ah (address = 03Ah), Decimation Filter Page
      11. 8.5.11 Power Detector Page
        1. 8.5.11.1  Register 000h (address = 000h), Power Detector Page
        2. 8.5.11.2  Register 001h-002h (address = 001h-002h), Power Detector Page
        3. 8.5.11.3  Register 003h (address = 003h), Power Detector Page
        4. 8.5.11.4  Register 007h-00Ah (address = 007h-00Ah), Power Detector Page
        5. 8.5.11.5  Register 00Bh-00Ch (address = 00Bh-00Ch), Power Detector Page
        6. 8.5.11.6  Register 00Dh (address = 00Dh), Power Detector Page
        7. 8.5.11.7  Register 00Eh (address = 00Eh), Power Detector Page
        8. 8.5.11.8  Register 00Fh, 010h-012h, and 016h-019h (address = 00Fh, 010h-012h, and 016h-019h), Power Detector Page
        9. 8.5.11.9  Register 013h-01Ah (address = 013h-01Ah), Power Detector Page
        10. 8.5.11.10 Register 01Dh-01Eh (address = 01Dh-01Eh), Power Detector Page
        11. 8.5.11.11 Register 020h (address = 020h), Power Detector Page
        12. 8.5.11.12 Register 021h (address = 021h), Power Detector Page
        13. 8.5.11.13 Register 022h-025h (address = 022h-025h), Power Detector Page
        14. 8.5.11.14 Register 027h (address = 027h), Power Detector Page
        15. 8.5.11.15 Register 02Bh (address = 02Bh), Power Detector Page
        16. 8.5.11.16 Register 032h-035h (address = 032h-035h), Power Detector Page
        17. 8.5.11.17 Register 037h (address = 037h), Power Detector Page
        18. 8.5.11.18 Register 038h (address = 038h), Power Detector Page
  9. Application and Implementation
    1. 9.1 Application Information
      1. 9.1.1 Start-Up Sequence
      2. 9.1.2 Hardware Reset
      3. 9.1.3 SNR and Clock Jitter
        1. 9.1.3.1 External Clock Phase Noise Consideration
      4. 9.1.4 Power Consumption in Different Modes
      5. 9.1.5 Using DC Coupling in the ADC31RF80
        1. 9.1.5.1 Bypassing the Offset Corrector Block
          1. 9.1.5.1.1 Effect of Temperature
    2. 9.2 Typical Application
      1. 9.2.1 Design Requirements
        1. 9.2.1.1 Transformer-Coupled Circuits
      2. 9.2.2 Detailed Design Procedure
      3. 9.2.3 Application Curves
  10. 10Power Supply Recommendations
  11. 11Layout
    1. 11.1 Layout Guidelines
    2. 11.2 Layout Example
  12. 12Device and Documentation Support
    1. 12.1 Documentation Support
      1. 12.1.1 Related Documentation
    2. 12.2 Receiving Notification of Documentation Updates
    3. 12.3 Community Resources
    4. 12.4 Trademarks
    5. 12.5 Electrostatic Discharge Caution
    6. 12.6 Glossary
  13. 13Mechanical, Packaging, and Orderable Information

パッケージ・オプション

メカニカル・データ(パッケージ|ピン)
サーマルパッド・メカニカル・データ
発注情報

Detailed Description

Overview

The ADC31RF80 is a single-channel, 14-bit, 2949.12-MSPS, telecom receiver and feedback device containing an analog-to-digital converter (ADC) followed by multi-band digital down-converters (DDCs), and a back-end JESD204B digital interface.

The ADC is preceded by an input buffer and on-chip termination to provide a uniform input impedance over a large input frequency range. Furthermore, an internal differential clamping circuit provides first-level protection against overvoltage conditions. The ADC is internally interleaved four times and equipped with background, analog and digital, and interleaving correction.

The on-chip DDC enables single- or dual-band internal processing to pre-select and filter smaller bands of interest and also reduces the digital output data traffic. Each DDC is equipped with up to three independent,
16-bit numerically-controlled oscillators (NCOs) for phase coherent frequency hopping; the NCOs can be controlled through the SPI or GPIO pins. The ADC31RF80 also provides three different power detectors on-chip with alarm outputs in order to support external automatic gain control (AGC) loops.

The processed data are passed into the JESD204B interface where the data are framed, encoded, serialized, and output on one to four lanes, depending on the ADC sampling rate and decimation. The CLKIN, SYSREF, and SYNCB inputs provide the device clock and the SYSREF and SYNCB signals to the JESD204B interface that are used to derive the internal local frame and local multiframe clocks and establish the serial link. All features of the ADC31RF80 are configurable through the SPI.

Functional Block Diagram

ADC31RF80 frontpage_sbas860.gif

Feature Description

Analog Inputs

The ADC31RF80 analog signal inputs are designed to be driven differentially. The analog input pins have internal analog buffers that drive the sampling circuit. The ADC31RF80 provides on-chip, differential termination to minimize reflections. The buffer also helps isolate the external driving circuit from the internal switching currents of the sampling circuit, thus resulting in a more constant SFDR performance across input frequencies.

The common-mode voltage of the signal inputs is internally biased to CM using the 32.5-Ω termination resistors that allow for ac-coupling of the input drive network. Figure 80 and Figure 81 show SDD11 at the analog inputs from dc to 5 GHz with a 100-Ω reference impedance.

ADC31RF80 equvlnt_inpt_imdnce_sbas860.gif
Figure 80. Equivalent Input Impedance
ADC31RF80 D120_SBAS747.png Figure 81. SDD11 Over the Input Frequency Range

The input impedance of analog inputs can also be modelled as parallel combination of equivalent resistance and capacitance. Figure 82 and Figure 83 show how equivalent impedance (CIN and RIN) vary over frequency.

ADC31RF80 D063_SBAS747.gif Figure 82. Differential Input Capacitance vs
Input Frequency
ADC31RF80 D064_SBAS747.gif Figure 83. Differential Input Resistance vs Input Frquency

Each input pin (INP, INM) must swing symmetrically between (CM + 0.3375 V) and (CM – 0.3375 V), resulting in a 1.35-VPP (default) differential input swing. Figure 84 shows that the input sampling circuit has a 3-dB bandwidth that extends up to approximately 3.2 GHz.

ADC31RF80 D062_SBAS747.gif
Figure 84. Input Bandwidth with a 100-Ω Source Resistance

Input Clamp Circuit

The ADC31RF80 analog inputs include an internal, differential clamp for overvoltage protection. The clamp triggers for any input signals at approximately 600 mV above the input common-mode voltage, as shown in Figure 85 and Figure 86, effectively limiting the maximum input signal to approximately 2.4 VPP.

When the clamp circuit conducts, the maximum differential current flowing through the circuit (via input pins) must be limited to 20 mA.

ADC31RF80 clamp_circuit_sbas860.gif
Figure 85. Clamp Circuit in the ADC31RF80
ADC31RF80 dgtl_rqrmnts_dgm_sbas747.gif
Figure 86. Clamp Response Timing Diagram

Clock Input

The ADC31RF80 sampling clock input includes internal 100-Ω differential termination along with on-chip biasing. The clock input is recommended to be ac-coupled externally. The input bandwidth of the clock input is approximately 3 GHz; Figure 87 shows the clock input impedance with a 100-Ω reference impedance.

ADC31RF80 D119_SBAS747.png Figure 87. SDD11 of the Clock Input

The analog-to-digital converter (ADC) aperture jitter is a function of the clock amplitude applied to the pins. Figure 88 shows the equivalent aperture jitter for input frequencies at a 1-GHz and a 2-GHz input. Depending on the clock frequency, a matching circuit can be designed in order to maximize the clock amplitude.

ADC31RF80 D061_SBAS747.gif Figure 88. Equivalent Aperture Jitter vs Input Clock Amplitude

SYSREF Input

The SYSREF signal is a periodic signal that is sampled by the ADC31RF80 device clock and is used to align the boundary of the local multiframe clock inside the data converter. SYSREF is also used to reset critical blocks [such as the clock divider for the interleaved ADCs, numerically-controlled oscillators (NCOs), decimation filters and so forth].

The SYSREF input requires external biasing. Furthermore, SYSREF must be established before the SPI registers are programmed. A programmable delay on the SYSREF input, as shown in Figure 89, is available to help with skew adjustment when the sampling clock and SYSREF are not provided from the same source.

ADC31RF80 sysref_inpt_sbas747.gif Figure 89. SYSREF Internal Circuit Diagram

Using SYSREF

The ADC31RF80 uses SYSREF information to reset the clock divider, the NCO phase, and the LMFC counter of the JESD interface. The device provides flexibility to provide SYSREF information either from dedicated pins or through SPI register bits. SYSREF is asserted by a low-to-high transition on the SYSREF pins or a 0-to-1 change in the ASSERT SYSREF REG bit, as shown in Figure 90, when using SPI registers.

ADC31RF80 sysref_dvdr_countr_sbas747.gif Figure 90. Using SYSREF to Reset the Clock Divider, the NCO, and the LMFC Counter

The ADC31RF80 samples the SYSREF signal on the input clock rising edge. Required setup and hold time are listed in the Timing Requirements table. The input clock divider gets reset each time that SYSREF is asserted, as shown in Table 1, whereas the NCO phase and the LMFC counter of the JESD interface are reset on each SYSREF assertion after disregarding the first two assertions.

Table 1. Asserting SYSREF

SYSREF ASSERTION INDEX ACTION
INPUT CLOCK DIVIDER NCO PHASE LMFC COUNTER
1 Gets reset Does not get reset Does not get reset
2 Gets reset Does not get reset Does not get reset
3 Gets reset Gets reset Gets reset
4 and onwards Gets reset Gets reset Gets reset

The SESREF use-cases can be classified broadly into two categories:

  1. SYSREF is applied as aperiodic multi-shot pulses.
  2. Figure 91 shows a case when only a counted number of pulses are applied as SYSREF to the ADC.

    ADC31RF80 sysref_countr_sbas774.gif
    Alternatively, the SYSREF buffer can be powered down with the PDN SYSREF bit.
    Figure 91. SYSREF Used as Aperiodic, Finite Number of Pulses

    After the first SYSREF pulse is applied, allow the DLL in the clock path to settle by waiting for the tDLL time (> 40 µs) before applying the second pulse. During this time, mask the SYSREF going to the input clock divider by setting the MASK CLKDIV SYSREF bit so that the divider output phase remains stable. The NCO phase and LMFC counter are reset on the third SYSREF pulse. After the third SYSREF pulse, the SYSREF going to the NCO and JESD block can be disabled by setting the MASK NCO SYSREF bit to avoid any unwanted resets.

  3. SYSREF is applied as a periodic pulse.
  4. Figure 92 shows how SYSREF can be applied as a continuous periodic waveform.

    ADC31RF80 sysref_priodic_waveform_sbas747.gif
    tSYSREF is a period of the SYSREF waveform.
    Alternatively, the SYSREF buffer can be powered down using the PDN SYSREF bit.
    Figure 92. SYSREF Used as a Periodic Waveform

    After applying the SYSREF signal, DLL must be allowed to lock, and the NCO phase and LMFC counter must be allowed to reset by waiting for at least the tDLL (40 µs) + 2 × tSYSREF time. Then, the SYSREF going to the NCO and JESD can be masked by setting the MASK NCO SYSREF register bit.

Frequency of the SYSREF Signal

When SYSREF is a periodic signal, as described in Equation 1, its frequency is required to be a sub-harmonic of the internal local multi-frame clock (LMFC) frequency. The LMFC frequency is determined by the selected decimation, frames per multi-frame setting (K), samples per frame (S), and device input clock frequency.

Equation 1. SYSREF = LMFC / N

where

  • N is an integer value (1, 2, 3, and so forth)

In order for the interleaving correction engine to synchronize properly, the SYSREF frequency must also be a multiple of fS / 64. Table 2 provides a summary of the valid LMFC clock settings.

Table 2. . SYSREF and LMFC Clock Frequency

OPERATING MODE LMFS SETTING LMFC CLOCK FREQUENCY SYSREF FRQUENCY
Decimation Various fS(1) / (D × S(4) × K(3)) fS / (N × LCM(2) (64, D(5) × S × K))
fS = sampling (device) clock frequency.
LCM = least-common multiple.
K = number of frames per multi-frame.
S = samples per frame.
D = decimation ratio.

The SYSREF signal is recommended to be a low-frequency signal less than 5 MHz in order to reduce coupling to the signal path both on the printed circuit board (PCB) as well as internal to the device.

Example: fS = 2949.12 MSPS, Divide-by-4 (LMFS = 8411), K = 16

SYSREF = 2949.12 MSPS / LCM (4 ,64, 16) = 46.08 MHz / N

Operate SYSREF at 2.88 MHz (effectively divide-by-1024, N = 16)

For proper device operation, disable the SYSREF signal after the JESD synchronization is established.

DDC Block

The ADC31RF80 provides a sophisticated on-chip, digital down converter (DDC) block that can be controlled through SPI register settings and the general-purpose input/output (GPIO) pins. The DDC block supports two basic operating modes: receiver (RX) mode with single- or dual-band DDC and wide-bandwidth observation receiver mode.

Figure 93 shows that the ADC channel is followed by two DDC chains consisting of the digital filter along with a complex digital mixer with a 16-bit numerically-controlled oscillator (NCO). The NCOs allow accurate frequency tuning within the Nyquist zone prior to the digital filtering. One DDC chain is intended for supporting a dual-band DDC configuration in receiver mode and the second DDC chain supports the wide-bandwidth output option for the observation configuration. At any given time, either the single-band DDC, the dual-band DDC, or the wideband DDC can be enabled. Furthermore, three different NCO frequencies can be selected on that path and are quickly switched using the SPI or the GPIO pins to enable wide-bandwidth observation in a multi-band application.

ADC31RF80 ddc_block_sbas747.gif

NOTE:

Red traces show SYSREF going to the NCO blocks.
Figure 93. DDC Chains Overview

Additionally, the decimation filter block provides the option to convert the complex output back to real format at twice the decimated, complex output rate. The filter response with a real output is identical to a complex output. The band is centered in the middle of the Nyquist zone (mixed with fOUT / 4) based on a final output data rate of fOUT.

Operating Mode: Receiver

Figure 94 shows that the DDC block can be configured to single- or dual-band operation in receiver mode. Both DDC chains use the same decimation filter setting and the available options are discussed in the Decimation Filters section. The decimation filter setting also directly affects the interface rate and number of lanes of the JESD204B interface.

ADC31RF80 operating_mode_receiver_sbas747.gif

NOTE:

Red traces show SYSREF going to the NCO blocks.
Figure 94. Decimation Filter Option for Single- or Dual-Band Operation

Operating Mode: Wide-Bandwidth Observation Receiver

This mode is intended for using a DDC with a wide bandwidth output, but for multiple bands. As shown in Figure 95, this mode uses a single DDC chain where up to three NCOs can be used to perform wide-bandwidth observation in a multi-band environment. The three NCOs can be switched dynamically using either the GPIO pins or an SPI command. All three NCOs operate continuously to ensure phase continuity; however, when the NCO is switched, the output data are invalid until the decimation filters are completely flushed with data from the new band.

ADC31RF80 operating_mode_wide_bw_rcvr_sbas747.gif

NOTE:

Red traces show SYSREF going to the NCO blocks.
Figure 95. Decimation Filter Implementation for Single-Band and Wide-Bandwidth Mode

Decimation Filters

The stop-band rejection of the decimation filters is approximately 90 dB with a pass-band bandwidth of approximately 80%. Table 3 gives an overview of the pass-band bandwidth depending on decimation filter setting and ADC sampling rate.

Table 3. Decimation Filter Summary and Maximum Available Output Bandwidth

DECIMATION SETTING NO. OF DDCS NOMINAL PASSBAND GAIN BANDWIDTH ADC SAMPLE RATE = N MSPS ADC SAMPLE RATE = 3 GSPS
3 dB (%) 1 dB (%) OUTPUT RATE (MSPS) PER BAND OUTPUT BANDWIDTH (MHz) PER BAND COMPLEX OUTPUT RATE (MSPS) PER BAND OUTPUT BANDWIDTH (MHz) PER BAND
Divide-by-4 complex 1 –0.4 dB 90.9 86.8 N / 4 complex 0.4 × N / 2 750 600
Divide-by-6 complex 1 –0.65 dB 90.6 86.1 N / 6 complex 0.4 × N / 3 500 400
Divide-by-8 complex 2 –0.27 dB 91.0 86.8 N / 8 complex 0.4 × N / 4 375 300
Divide-by-9 complex 2 –0.45 dB 90.7 86.3 N / 9 complex 0.4 × N / 4.5 333.3 266.6
Divide-by-10 complex 2 –0.58 dB 90.7 86.3 N / 10 complex 0.4 × N / 5 300 240
Divide-by-12 complex 2 –0.55 dB 90.7 86.4 N / 12 complex 0.4 × N / 6 250 200
Divide-by-16 complex 2 –0.42 dB 90.8 86.4 N / 16 complex 0.4 × N / 8 187.5 150
Divide-by-18 complex 2 –0.83 dB 91.2 87.0 N / 18 complex 0.4 × N / 9 166.6 133
Divide-by-20 complex 2 –0.91 dB 91.2 87.0 N / 20 complex 0.4 × N / 10 150 120
Divide-by-24 complex 2 –0.95 db 91.1 86.9 N / 24 complex 0.4 × N / 12 125 100
Divide-by-32 complex 2 –0.78 dB 91.1 86.8 N / 32 complex 0.4 × N / 16 93.75 75

Figure 96 shows a dual-band example with a divide-by-8 complex.

ADC31RF80 dual_band_ddc_sbas860.gif Figure 96. Dual-Band Example

The decimation filter responses normalized to the ADC sampling clock are illustrated in Figure 96 to Figure 119 and can be interpreted as follows:

Figure 97 shows that each figure contains the filter pass-band, transition bands, and alias bands. The x-axis in Figure 97 shows the offset frequency (after the NCO frequency shift) normalized to the ADC sampling clock frequency.

For example, in the divide-by-4 complex, the output data rate is an fS / 4 complex with a Nyquist zone of fS / 8 or 0.125 × fS. The transition band is centered around 0.125 × fS and the alias transition band is centered at 0.375 × fS. The alias bands that alias on top of the wanted signal band are centered at 0.25 × fS and 0.5 × fS (and are colored in red).

The decimation filters of the ADC31RF80 provide greater than 90-dB attenuation for the alias bands.

ADC31RF80 plot_example_sbas747.gif Figure 97. Interpretation of the Decimation Filter Plots

Divide-by-4

Peak-to-peak pass-band ripple: approximately 0.22 dB

ADC31RF80 D123_SBAS747.gif
Figure 98. Divide-by-4 Filter Response
ADC31RF80 D124_SBAS747.gif
Figure 99. Divide-by-4 Filter Response (Zoomed)

Divide-by-6

Peak-to-peak pass-band ripple: approximately 0.38 dB

ADC31RF80 D125_SBAS747.gif
Figure 100. Divide-by-6 Filter Response
ADC31RF80 D126_SBAS747.gif
Figure 101. Divide-by-6 Filter Response (Zoomed)

Divide-by-8

Peak-to-peak pass-band ripple: approximately 0.25 dB

ADC31RF80 D127_SBAS747.gif
Figure 102. Divide-by-8 Filter Response
ADC31RF80 D128_SBAS747.gif
Figure 103. Divide-by-8 Filter Response (Zoomed)

Divide-by-9

Peak-to-peak pass-band ripple: approximately 0.39 dB

ADC31RF80 D129_SBAS747.gif
Figure 104. Divide-by-9 Filter Response
ADC31RF80 D130_SBAS747.gif
Figure 105. Divide-by-9 Filter Response (Zoomed)

Divide-by-10

Peak-to-peak pass-band ripple: approximately 0.39 dB

ADC31RF80 D131_SBAS747.gif
Figure 106. Divide-by-10 Filter Response
ADC31RF80 D132_SBAS747.gif
Figure 107. Divide-by-10 Filter Response (Zoomed)

Divide-by-12

Peak-to-peak pass-band ripple: approximately 0.36 dB

ADC31RF80 D133_SBAS747.gif
Figure 108. Divide-by-12 Filter Response
ADC31RF80 D134_SBAS747.gif
Figure 109. Divide-by-12 Filter Response (Zoomed)

Divide-by-16

Peak-to-peak pass-band ripple: approximately 0.29 dB

ADC31RF80 D135_SBAS747.gif
Figure 110. Divide-by-16 Filter Response
ADC31RF80 D136_SBAS747.gif
Figure 111. Divide-by-16 Filter Response (Zoomed)

Divide-by-18

Peak-to-peak pass-band ripple: approximately 0.33 dB

ADC31RF80 D137_SBAS747.gif
Figure 112. Divide-by-18 Filter Response
ADC31RF80 D138_SBAS747.gif
Figure 113. Divide-by-18 Filter Response (Zoomed)

Divide-by-20

Peak-to-peak pass-band ripple: approximately 0.32 dB

ADC31RF80 D139_SBAS747.gif
Figure 114. Divide-by-20 Filter Response
ADC31RF80 D140_SBAS747.gif
Figure 115. Divide-by-20 Filter Response (Zoomed)

Divide-by-24

Peak-to-peak pass-band ripple: approximately 0.30 dB

ADC31RF80 D141_SBAS747.gif
Figure 116. Divide-by-24 Filter Response
ADC31RF80 D142_SBAS747.gif
Figure 117. Divide-by-24 Filter Response (Zoomed)

Divide-by-32

Peak-to-peak pass-band ripple: approximately 0.24 dB

ADC31RF80 D143_SBAS747.gif
Figure 118. Divide-by-32 Filter Response
ADC31RF80 D144_SBAS747.gif
Figure 119. Divide-by-32 Filter Response (Zoomed)

Latency With Decimation Options

Table 4 describes device latency for different DDC options. At higher decimation options, latency increases because of the increase in number of taps in the decimation filter.

Table 4. Latency With Different Decimation Options

DECIMATION OPTION TOTAL LATENCY, DEVICE CLOCK CYCLES
Divide-by-4 516
Divide-by-6 746
Divide-by-8 621
Divide-by-9 763.5
Divide-by-10 811
Divide-by-12 897
Divide-by-16 1045
Divide-by-18 1164
Divide-by-20 1256
Divide-by-24 1443
Divide-by-32 1773

Numerically-Controlled Oscillators (NCOs) and Mixers

The ADC31RF80 is equipped with three independent, complex NCOs. Equation 2 shows how the oscillator generates a complex exponential sequence.

Equation 2. x[n] = e–jωn

where

  • frequency (ω) is specified as a signed number by the 16-bit register setting

The complex exponential sequence is multiplied by the real input from the ADC to mix the desired carrier down to 0 Hz.

The ADC has two DDCs. The first DDC has three NCOs and the second DDC has one NCO. The first DDC can dynamically select one of the three NCOs based on the GPIO pin or SPI selection. In wide-bandwidth mode (lower decimation factors, for example, 4 and 6), there can only be one active DDC. The NCO frequencies can be programmed independently through the DDCx, NCO[4:1], and the MSB and LSB register settings.

Equation 3 gives the NCO frequency setting that is set by the 16-bit register:

Equation 3. ADC31RF80 nco_frequency_eq_sbas747.gif

where

  • x = 0, 1
  • y = 1 to 4

For example:

If fS = 2949.12 MSPS, then the NCO register setting = 38230 (decimal).

Thus, Equation 4 defines fNCO:

Equation 4. ADC31RF80 eq_fnco_sbas774.gif

Any register setting changes that occur after the JESD204B interface is operational results in a non-deterministic NCO phase. If a deterministic phase is required, the JESD204B interface must be reinitialized after changing the register setting.

NCO Switching

The first DDC (DDC0) provides three different NCOs that can be used for phase-coherent frequency hopping. This feature is available in both single-band and dual-band mode, but only affects DDC0.

The NCOs can be switched by using the GPIO pins with the register configurations shown in Table 5 or through an SPI control. The assignment of which GPIO pin to use for INSEL0 and INSEL1 is done based on Table 6, using register 5438h. The NCO selection, shown in Table 7 and Figure 120, is done based on the logic selection on the GPIO pins.

Table 5. NCO Register Configurations

REGISTER ADDRESS DESCRIPTION
NCO CONTROL THROUGH GPIO PINS
NCO SEL PIN 500Fh Selects the NCO control through the SPI (default) or a GPIO pin.
INSEL0[1:0], INSEL1[1:0] 5438h Selects which two GPIO pins are used to control the NCO.
NCO CONTROL THROUGH SPI CONTROL
NCO SEL PIN 500Fh Selects the NCO control through the SPI (default) or a GPIO pin.
NCO SEL[1:0] 5010h Selects which NCO to use for DDC0.

Table 6. GPIO Pin Assignment

INSELx[1:0] (Where x = 0 or 1) GPIO PIN SELECTED
00 GPIO4
01 GPIO1
10 GPIO3
11 GPIO2

Table 7. NCO Selection

NCO SEL[1:0] NCO SELECTED
00 NCO1
01 NCO2
10 NCO3
11 n/a
ADC31RF80 GPIO_sel_mux_sbas860.gif Figure 120. NCO Switching from GPIO and SPI

SerDes Transmitter Interface

Each 12.3-Gbps serializer, deserializer (SerDes) LVDS transmitter output requires ac-coupling between the transmitter and receiver. Terminate the differential pair, as shown in Figure 121, with 100-Ω resistance (that is, two 50-Ω resistors) as close to the receiving device as possible to avoid unwanted reflections and signal degradation.

ADC31RF80 cml_serdes_transmtr_intrfc_sbas860.gif Figure 121. External Serial JESD204B Interface Connection

Eye Diagrams

Figure 122 and Figure 123 show the serial output eye diagrams of the ADC31RF80 at 5.0 Gbps and 12 Gbps against the JESD204B mask.

ADC31RF80 eye_dgm1_sbas747.gif Figure 122. Data Eye at 5 Gbps
ADC31RF80 eye_dgm2_sbas747.gif Figure 123. Data Eye at 12 Gbps

Alarm Outputs: Power Detectors for AGC Support

The GPIO pins can be configured as alarm outputs. The ADC31RF80 supports three different power detectors (an absolute peak power detector, crossing detector, and RMS power detector) as well as fast overrange from the ADC. The power detectors operate off the full-rate ADC output prior to the decimation filters.

Absolute Peak Power Detector

In this detector mode, the peak is computed over eight samples of the ADC output. Next, the peak for a block of N samples (N × S`) is computed over a programmable block length and then compared against a threshold to either set or reset the peak detector output (Figure 124 and Figure 125). There are two sets of thresholds and each set has two thresholds for hysteresis. The programmable DWELL-time counter is used for clearing the block detector alarm output.

ADC31RF80 abslt_pk_pwr_dtctr_sbas747.gif Figure 124. Peak Power Detector Implementation
ADC31RF80 abslt_pk_pwr_dtctr_tmg_dgm_sbas747.gif Figure 125. Peak Power Detector Timing Diagram

Table 8 shows the register configurations required to set up the absolute peak power detector. The detector operates in the fS / 8 clock domain; one peak sample is calculated over eight actual samples.

The automatic gain control (AGC) modes can be configured using registers in the power-detector page (54xxh).

Table 8. Registers Required for the Peak Power Detector

REGISTER ADDRESS DESCRIPTION
PKDET EN 5400h Enables peak detector
BLKPKDET 5401h, 5402h, 5403h Sets the block length N of number of samples (S`). Number of actual ADC samples is 8x this value: N is 17 bits: 1 to 216.
BLKTHHH, BLKTHHL, BLKTHLH, BLKTHLL 5407h, 5408h, 5409h, 540Ah Sets the different thresholds for the hysteresis function values from 0 to 256 (where 256 is equivalent to the peak amplitude).
For example: if BLKTHHH is to –2 dBFS from peak, 10(–2 / 20) × 256 = 203, then set 5407h = CBh.
DWELL 540Bh, 540Ch When the computed block peak crosses the upper thresholds BLKTHHH or BLKTHLH, the peak detector output flags are set. In order to be reset, the computed block peak must remain continuously lower than the lower threshold (BLKTHHL or BLKTHLL) for the period specified by the DWELL value. This threshold is 16 bits and is specified in terms of fS / 8 clock cycles.
OUTSEL GPIO[4:1] 5432h, 5433h, 5434h, 5435h Connects the BLKPKDETH, BLKPKDETL alarms to the GPIO pins; common register.
IODIR 5437h Selects the direction for the four GPIO pins; common register.
RESET AGC 542Bh After configuration, reset the AGC module to start operation.

Crossing Detector

In this detector mode the peak is computed over eight samples of the ADC output. Next, the peak for a block of N samples (N × S`) is computed over a programmable block length and then the peak is compared against two sets of programmable thresholds (with hysteresis). The crossing detector counts how many fS / 8 clock cycles that the block detector outputs are set high over a programmable time period and compares the counter value against the programmable thresholds. Figure 126 and Figure 127 show that the alarm outputs are updated at the end of the time period, routed to the GPIO pins, and held in that state through the next cycle. Alternatively, a 2-bit format can be used but (because the ADC31RF80 has four GPIO pins available) this feature uses all four pins.

ADC31RF80 crssng_dtctr_sbas747.gif Figure 126. Crossing Detector Implementation
ADC31RF80 crssng_dtctr_tmg_dgm_sbas747.gif Figure 127. Crossing Detector Timing Diagram

Table 9 shows the register configurations required to set up the crossing detector. The detector operates in the
fS / 8 clock domain. The AGC modes can be configured through registers located in the power detector page (54xxh).

Table 9. Registers Required for the Crossing Detector Operation

REGISTER ADDRESS DESCRIPTION
PKDET EN 5400h Enables peak detector
BLKPKDET 5401h, 5402h, 5403h Sets the block length N of number of samples (S`).
Number of actual ADC samples is 8x this value: N is 17 bits: 1 to 216.
BLKTHHH, BLKTHHL, BLKTHLH, BLKTHLL 5407h, 5408h, 5409h, 540Ah Sets the different thresholds for the hysteresis function values from 0 to 256 (where 256 is equivalent to the peak amplitude).
For example: if BLKTHHH is to –2 dBFS from peak, 10(–2 / 20) × 256 = 203, then set 5407h = CBh.
FILT0LPSEL 540Dh Select block detector output or 2-bit output mode as the input to the interrupt identification register (IIR) filter.
TIMECONST 540Eh, 540Fh, Sets the crossing detector time period for N = 0 to 15 as 2N × fS / 8 clock cycles.
The maximum time period is 32768 × fS / 8 clock cycles (approximately 87 µs at 3 GSPS).
FIL0THH, FIL0THL, FIL1THH, FIL1THL 540Fh-5412h, 5416h-5419h Comparison thresholds for the crossing detector counter. These thresholds are 16-bit thresholds in 2.14-signed notation. A value of 1 (4000h) corresponds to 100% crossings, a value of 0.125 (0800h) corresponds to 12.5% crossings.
DWELLIIR 541Dh, 541Eh DWELL counter for the IIR filter hysteresis.
IIR0 2BIT EN,
IIR1 2BIT EN
5413h, 54114h Enables 2-bit output format for the crossing detector.
OUTSEL GPIO[4:1] 5432h, 5433h,
5434h, 5435h
Connects the IIRPKDET0, IIRPKDET1 alarms to the GPIO pins; common register.
IODIR 5437h Selects the direction for the four GPIO pins; common register.
RESET AGC 542Bh After configuration, reset the AGC module to start operation.

RMS Power Detector

In this detector mode the peak power is computed for a block of N samples over a programmable block length and then compared against two sets of programmable thresholds (with hysteresis).

Figure 128 shows the configuration options provided by the RMS power detector circuit. The RMS power value (1 or 2 bit) can be output onto the GPIO pins. In 2-bit output mode, two different thresholds are used whereas the 1-bit output provides one threshold together with hysteresis.

ADC31RF80 rms_pwr_dtctr_sbas747.gif Figure 128. RMS Power Detector Implementation

Table 10 shows the register configurations required to set up the RMS power detector. The detector operates in the fS / 8 clock domain. The AGC modes can be configured through registers located in the power detector page (54xxh).

Table 10. Registers Required for Using the RMS Power Detector Feature

REGISTER ADDRESS DESCRIPTION
RMSDET EN 5420h Enables RMS detector
PWRDETACCU 5421h Programs the block length to be used for RMS power computation. The block length is defined in terms of fS / 8 clocks.
The block length can be programmed as 2M with M = 0 to 16.
PWRDETH, PWRDETL 5422h, 5423h, 5424h, 5425h The computed average power is compared against these high and low thresholds. One LSB of the thresholds represents 1 / 216. For example: is PWRDETH is set to –14 dBFS from peak, [10(–14 / 20)]2 × 216 = 2609, then set 5422h, 5423h = 0A31h.
RMS2BIT EN 5427h Enables 2-bit output format for the RMS detector output.
OUTSEL GPIO[4:1] 5432h, 5433h,
5434h, 5435h
Connects the PWRDET alarms to the GPIO pins; common register.
IODIR 5437h Selects the direction for the four GPIO pins; common register.
RESET AGC 542Bh After configuration, reset the AGC module to start operation.

GPIO AGC MUX

The GPIO pins can be used to control the NCO in wideband DDC mode or as alarm outputs. Figure 129 shows that the GPIO pins can be configured through the SPI control to output the alarm from the peak power (1 bit), crossing detector (1 or 2 bit), faster overrange, or the RMS power output.

The programmable output MUX allows connecting any signal (including the NCO control) to any of the four GPIO pins. These pins can be configured as outputs (AGC alarm) or inputs (NCO control) through SPI programming.

ADC31RF80 opt_mux_sbas747.gif Figure 129. GPIO Output MUX Implementation

Power-Down Mode

The ADC31RF80 provides a lot of configurability for the power-down mode. Power-down can be enabled using the PDN pin or the SPI register writes.

ADC Test Pattern

The ADC31RF80 provides several different options to output test patterns instead of the actual output data of the ADC in order to simplify the serial interface and system debug of the JESD204B digital interface link. Figure 130 shows the output data path.

ADC31RF80 adc_test_pattern_sbas747.gif Figure 130. Test Pattern Generator Implementation

Digital Block

The ADC test pattern replaces the actual output data of the ADC. The test patterns listed in Table 11 are available when the DDC is enabled and located in register 37h of the decimation filter page. When programmed, the test patterns are output for each converter (M) stream. The number of converter streams increases by 2 when complex (I, Q) output or dual-band DDC is selected.

Additionally, a 12-bit test pattern is also available.

NOTE

The number of converters increases in dual-band DDC mode and with a complex output.

Table 11. Test Pattern Options (Register 37h and 38h in Decimation Filter Page)

BIT NAME DEFAULT DESCRIPTION
Address 37h, 38h (bits 7-0) TEST PATTERN DDC1 I-DATA,
TEST PATTERN DDC1 Q-DATA,
TEST PATTERN DDC2 I-DATA,
TEST PATTERN DDC2 Q-DATA,
0000 Test pattern outputs on when the I and Q stream DDC option is chosen.
0000 = Normal operation using ADC output data
0001 = Outputs all 0s
0010 = Outputs all 1s
0011 = Outputs toggle pattern: output data are an alternating sequence of 10101010101010 and 01010101010101
0100 = Output digital ramp: output data increment by one LSB every clock cycle from code 0 to 65535
0110 = Single pattern: output data are a custom pattern 1 (75h and 76h)
0111 Double pattern: output data alternate between custom pattern 1 and custom pattern 2
1000 = Deskew pattern: output data are AAAAh
1001 = SYNC pattern: output data are FFFFh

Transport Layer

The transport layer maps the ADC output data into 8-bit octets and constructs the JESD204B frames using the LMFS parameters. Tail bits or 0's are added when needed. Alternatively, the JESD204B long transport layer test pattern can be substituted, as shown in Table 12, instead of the ADC data with the JESD frame.

Table 12. Transport Layer Test Mode EN (Register 01h)

BIT NAME DEFAULT DESCRIPTION
4 TESTMODE EN 0 Generates long transport layer test pattern mode according to section 5.1.6.3 of the JESD204B specification.
0 = Test mode disabled
1 = Test mode disabled

Link Layer

The link layer contains the scrambler and the 8b, 10b encoding of any data passed on from the transport layer. Additionally, the link layer also handles the initial lane alignment sequence that can be manually restarted.

The link layer test patterns are intended for testing the quality of the link (jitter testing and so forth). The test patterns do not pass through the 8b, 10b encoder and contain the options listed in Table 13.

Table 13. Link Layer Test Mode (Register 03h)

BIT NAME DEFAULT DESCRIPTION
7-5 LINK LAYER TESTMODE 000 Generates a pattern according to section 5.3.3.8.2 of the JESD204B document.
000 = Normal ADC data
001 = D21.5 (high-frequency jitter pattern)
010 = K28.5 (mixed-frequency jitter pattern)
011 = Repeat the initial lane alignment (generates a K28.5 character and repeats lane alignment sequences continuously)
100 = 12-octet random pattern (RPAT) jitter pattern

Furthermore, a 215 pseudo-random binary sequence (PRBS) can be enabled by setting up a custom test pattern (AAAAh) in the ADC section and running AAAAh through the 8b, 10b encoder with scrambling enabled.

Device Functional Modes

Device Configuration

The ADC31RF80 can be configured using a serial programming interface, as described in the Serial Interface section. In addition, the device has one dedicated parallel pin (PDN) for controlling the power-down modes.

JESD204B Interface

The ADC31RF80 supports device subclass 1 with a maximum output data rate of 12.5 Gbps for each serial transmitter.

An external SYSREF signal is used to align all internal clock phases and the local multiframe clock to a specific sampling clock edge. This alignment allows synchronization of multiple devices in a system and minimizes timing and alignment uncertainty. Figure 131 shows that the SYNCB input is used to control the JESD204B SerDes blocks.

Depending on the ADC sampling rate, the JESD204B output interface can be operated with one, two, or four lanes. The JESD204B setup and configuration of the frame assembly parameters is controlled through the SPI interface.

ADC31RF80 jesd204b_intrfc_sbas860.gif Figure 131. JESD Signal Overview

The JESD204B transmitter block, shown in Figure 132, consists of the transport layer, the data scrambler, and the link layer. The transport layer maps the ADC output data into the selected JESD204B frame data format and manages if the ADC output data or test patterns are transmitted. The link layer performs the 8b, 10b data encoding as well as the synchronization and initial lane alignment using the SYNC input signal. Optionally, data from the transport layer can be scrambled.

ADC31RF80 jesd204b_block_sbas747.gif Figure 132. JESD Digital Block Implementation

JESD204B Initial Lane Alignment (ILA)

The receiving device starts the initial lane alignment process by deasserting the SYNCB signal. The SYNCB signal can be issued using the SYNCB input pins or by setting the proper SPI bits. When a logic low is detected on the SYNCB input, as shown in Figure 133, the ADC31RF80 starts transmitting comma (K28.5) characters to establish the code group synchronization.

When synchronization completes, the receiving device reasserts the SYNCB signal and the ADC31RF80 starts the initial lane alignment sequence with the next local multiframe clock boundary. The ADC31RF80 transmits four multiframes, each containing K frames (K is SPI programmable). Each of the multiframes contains the frame start and end symbols. The second multiframe also contains the JESD204 link configuration data.

ADC31RF80 jesd204b_lane_algnmnt_sbas747.gif Figure 133. JESD Internal Timing Information

JESD204B Frame Assembly

The JESD204B standard defines the following parameters:

  • F is the number of octets per frame clock period
  • L is the number of lanes per link
  • M is the number of converters for the device
  • S is the number of samples per frame

JESD204B Frame Assembly with Decimation (Single-Band DDC): Complex Output

Table 14 lists the available JESD204B interface formats and valid ranges for the ADC31RF80 with decimation (single-band DDC) when using a complex output format. The ranges are limited by the SerDes line rate and the maximum ADC sample frequency. Table 15 shows the sample alignment on the different lanes.

Table 14. JESD Mode Options: Single-Band Complex Output

DECIMATION SETTING (Complex) NUMBER OF ACTIVE DDCS L M F S PLL MODE JESD MODE0 JESD MODE1 JESD MODE2 RATIO
[fSerDes / fCLK
(Gbps / GSPS)]
Divide-by-4 1 4 2 1 1 20x 1 1 0 2.5
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 5
2 2 4 2 40x 2 0 0
Divide-by-6 1 4 2 1 1 20x 1 1 0 1.67
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 3.33
2 2 4 2 40x 2 0 0
Divide-by-8 1 2 2 2 1 20x 1 0 0 2.5
1 2 4 1 40x 2 0 0 5
Divide-by-9 1 2 2 2 1 20x 1 0 0 2.22
1 2 4 1 40x 2 0 0 4.44
Divide-by-10 1 2 2 2 1 20x 1 0 0 2
1 2 4 1 40x 2 0 0 4
Divide-by-12 1 2 2 2 1 20x 1 0 0 1.67
1 2 4 1 40x 2 0 0 3.33
Divide-by-16 1 2 2 2 1 20x 1 0 0 1.25
1 2 4 1 40x 2 0 0 2.5
Divide-by-18 1 2 2 2 1 20x 1 0 0 1.11
1 2 4 1 40x 2 0 0 2.22
Divide-by-20 1 2 2 2 1 20x 1 0 0 1
1 2 4 1 40x 2 0 0 2
Divide-by-24 1 1 2 4 1 20x 1 0 0 1.67
Divide-by-32 1 1 2 4 1 40x 2 0 0 1.25

Table 15. JESD Sample Lane Alignments: Single-Band Complex Output

OUTPUT LANE LMFS = 8411 LMFS = 8422 LMFS = 4421 20X LMFS = 4421 40X LMFS = 4442 LMFS = 2441
D0 AI0
[15:8]
AI0
[15:8]
AI0
[7:0]
AI0
[15:8]
AI0
[7:0]
D1 AI0
[7:0]
AI1
[15:8]
AI1
[7:0]
AQ0
[15:8]
AQ0
[7:0]
AI0
[15:8]
AI0
[7:0]
AI0
[15:8]
AI0
[7:0]
AI1
[15:8]
AI1
[7:0]
AI0
[15:8]
AI0
[7:0]
AQ0
[15:8]
AQ0
[7:0]
D2 AQ0
[15:8]
AQ0
[15:8]
AQ0
[7:0]
AQ0
[15:8]
AQ0
[7:0]
AQ0
[15:8]
AQ0
[7:0]
AQ1
[15:8]
AQ1
[7:0]
D3 AQ0
[7:0]
AQ1
[15:8]
AQ1
[7:0]

JESD204B Frame Assembly with Decimation (Single-Band DDC): Real Output

Table 16 lists the available JESD204B formats and valid ranges for the ADC31RF80 with decimation (single-band DDC) when using real output format. The ranges are limited by the SerDes line rate and the maximum ADC sample frequency. Table 17 shows the sample alignment on the different lanes.

Table 16. JESD Mode Options: Single-Band Real Output (Wide Bandwidth)

DECIMATION SETTING (Complex) NUMBER OF ACTIVE DDCS L M F S PLL MODE JESD MODE0 JESD MODE1 JESD MODE2 RATIO
[fSerDes / fCLK
(Gbps / GSPS)]
Divide-by-4
(Divide-by-2 real)
1 4 1 2 4 20x 1 0 0 2.5
2 1 4 4 40x 2 0 0 5
2 1 1 1 40x 0 0 1
Divide-by-6
(Divide-by-3 real)
1 4 1 2 4 20x 1 0 0 1.67
2 1 4 4 40x 2 0 0 3.33
2 1 1 1 40x 0 0 1

Table 17. JESD Sample Lane Alignment: Single-Band Real Output (Wide Bandwidth)

OUTPUT LANE LMFS = 8224 LMFS = 4244 LMFS = 4211
D0 A0[15:8] A0[7:0]
D1 A1[15:8] A1[7:0] A0[15:8] A0[7:0] A1[15:8] A1[7:0] A0[15:8]
D2 A2[15:8] A2[7:0] A2[15:8] A2[7:0] A3[15:8] A3[7:0] A0[7:0]
D3 A3[15:8] A3[7:0]

JESD204B Frame Assembly with Decimation (Single-Band DDC): Real Output

Table 18 lists the available JESD204B formats and valid ranges for the ADC31RF80 with decimation (dual-band DDC) when using a complex output format. Table 19 shows the sample alignment on the different lanes.

Table 18. JESD Mode Options: Single-Band Real Output

DECIMATION SETTING (Complex) NUMBER OF ACTIVE DDCS L M F S PLL MODE JESD MODE0 JESD MODE1 JESD MODE2 RATIO
[fSerDes / fCLK
(Gbps / GSPS)]
Divide-by-8
(Divide-by-4 real)
1 2 1 1 1 20x 1 1 0 2.5
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 5
1 1 4 2 40x 2 0 0
Divide-by-9
(Divide-by-4.5 real)
1 2 1 1 1 20x 1 1 0 2.22
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 4.44
1 1 4 2 40x 2 0 0
Divide-by-10
(Divide-by-5 real)
1 2 1 1 1 20x 1 1 0 2
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 4
1 1 4 2 40x 2 0 0
Divide-by-12
(Divide-by-6 real)
1 2 1 1 1 20x 1 1 0 1.67
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 3.33
1 1 4 2 40x 2 0 0
Divide-by-16
(Divide-by-8 real)
1 2 1 1 1 20x 1 1 0 1.25
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 2.5
1 1 4 2 40x 2 0 0
Divide-by-18
(Divide-by-9 real)
1 2 1 1 1 20x 1 1 0 1.11
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 2.22
1 1 4 2 40x 2 0 0
Divide-by-20
(Divide-by-10 real)
1 2 1 1 1 20x 1 1 0 1
2 1 2 2 20x 1 0 0
1 1 2 1 40x 0 0 1 2
1 1 4 2 40x 2 0 0
Divide-by-24
(Divide-by-12 real)
1 1 1 2 1 40x 0 0 1 1.67
1 1 4 2 40x 2 0 0
Divide-by-32
(Divide-by-16 real)
1 1 1 2 1 40x 0 0 1 1.25
1 1 4 2 40x 2 0 0

Table 19. JESD Sample Lane Assignment: Single-Band Real Output

OUTPUT LANE LMFS = 4211 LMFS = 4222 LMFS = 2221 LMFS = 2242
D0 A0[15:8] A0[15:8] A0[7:0]
D1 A0[7:0] A1[15:8] A1[7:0] A0 [15:8] A0[7:0] A0[15:8] A0[7:0] A1[15:8] A1[7:0]

JESD204B Frame Assembly with Decimation (Dual-Band DDC): Complex Output

Table 20 lists the available JESD204B formats and valid ranges for the ADC31RF80 with decimation (dual-band DDC) when using a complex output format. The ranges are limited by the SerDes line rate and the maximum ADC sample frequency. Table 21 shows the sample alignment on the different lanes.

Table 20. JESD Mode Options: Dual-Band Complex Output

DECIMATION SETTING (Complex) NUMBER OF ACTIVE DDCS L M F S PLL MODE JESD MODE0 JESD MODE1 JESD MODE2 RATIO
[fSerDes / fCLK
(Gbps / GSPS)]
Divide-by-8 2 4 4 2 1 20x 1 0 0 2.5
2 4 4 1 40x 2 0 0 5
Divide-by-9 2 4 4 2 1 20x 1 0 0 2.22
2 4 4 1 40x 2 0 0 4.44
Divide-by-10 2 4 4 2 1 20x 1 0 0 2
2 4 4 1 40x 2 0 0 4
Divide-by-12 2 4 4 2 1 20x 1 0 0 1.67
2 4 4 1 40x 2 0 0 3.33
Divide-by-16 2 4 4 2 1 20x 1 0 0 1.25
2 4 4 1 40x 2 0 0 2.5
Divide-by-18 2 4 4 2 1 20x 1 0 0 1.11
2 4 4 1 40x 2 0 0 2.22
Divide-by-20 2 4 4 2 1 20x 1 0 0 1
2 4 4 1 40x 2 0 0 2
Divide-by-24 2 2 4 4 1 40x 2 0 0 1.67
Divide-by-32 2 2 4 4 1 40x 2 0 0 1.25

Table 21. JESD Sample Lane Assignment: Dual-Band Complex Output(1)

OUTPUT LANE LMFS = 8821 LMFS = 4841
D0 A10[15:8] A10[7:0]
D1 A1Q0[15:8] A1Q0[7:0] A1I0[15:8] A1I0[7:0] A1Q0[15:8] A1Q0[7:0]
D2 A2I0[15:8] A2I0[7:0] A2I0[15:8] A2I0[7:0] A2Q0[15:8] A2Q0[7:0]
D3 A2Q0[15:8] A2Q0[7:0]
Blue and green shading indicates the output of the two DDC bands.

JESD204B Frame Assembly with Decimation (Dual-Band DDC): Real Output

Table 22 lists the available JESD204B formats and valid ranges for the ADC31RF80 with decimation (dual-band DDC) when using real output format. The ranges are limited by the SerDes line rate and the maximum ADC sample frequency. Table 23 shows the sample alignment on the different lanes.

Table 22. JESD Mode Options: Dual-Band Real Output

DECIMATION SETTING (Complex) NUMBER OF ACTIVE DDCS L M F S PLL MODE JESD MODE0 JESD MODE1 JESD MODE2 RATIO
[fSerDes / fCLK
(Gbps / GSPS)]
Divide-by-8
(Divide-by-4 real)
2 4 2 1 1 20x 1 1 0 2.5
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 5
2 2 4 2 40x 2 0 0
Divide-by-9
(Divide-by-4.5 real)
2 4 2 1 1 20x 1 1 0 2.22
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 4.44
2 2 4 2 40x 2 0 0
Divide-by-10
(Divide-by-5 real)
2 4 2 1 1 20x 1 1 0 2
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 4
2 2 4 2 40x 2 0 0
Divide-by-12
(Divide-by-6 real)
2 4 2 1 1 20x 1 1 0 1.67
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 3.33
2 2 4 2 40x 2 0 0
Divide-by-16
(Divide-by-8 real)
2 4 2 1 1 20x 1 1 0 1.25
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 2.5
2 2 4 2 40x 2 0 0
Divide-by-18
(Divide-by-9 real)
2 4 2 1 1 20x 1 1 0 1.11
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 2.22
2 2 4 2 40x 2 0 0
Divide-by-20
(Divide-by-10 real)
2 4 2 1 1 20x 1 1 0 1
4 2 2 2 20x 1 0 0
2 2 2 1 40x 0 0 1 2
2 2 4 2 40x 2 0 0
Divide-by-24
(Divide-by-12 real)
2 2 2 2 1 40x 0 0 1 1.67
2 2 4 2 40x 2 0 0
Divide-by-32
(Divide-by-16 real)
2 2 2 2 1 40x 0 0 1 1.25
2 2 4 2 40x 2 0 0

Table 23. JESD Sample Lane Assignment: Dual-Band Complex Output(1)

OUTPUT LANE LMFS = 8411 LMFS = 8422 LMFS = 4421 LMFS = 4442
D0 A10[15:8] A10[15:8] A10[7:0]
D1 A10[7:0] A11[15:8] A11[7:0] A10[15:8] A10[7:0] A10[15:8] A10[7:0] A11[15:8] A11[7:0]
D2 A20[15:8] A20[15:8] A20[7:0] A20[15:8] A20[7:0] A20[15:8] A20[7:0] A21[15:8] A21[7:0]
D3 A20[7:0] A21[15:8] A21[7:0]

Serial Interface

The ADC has a set of internal registers that can be accessed by the serial interface formed by the SEN (serial interface enable), SCLK (serial interface clock), and SDIN (serial interface data) pins. Serially shifting bits into the device is enabled when SEN is low. Figure 134 shows that SDIN serial data are latched at every SCLK rising edge when SEN is active (low). Table 24 also shows that the interface can function with SCLK frequencies from 20 MHz down to low speeds (of a few hertz) and also with a non-50% SCLK duty cycle.

The SPI access uses 24 bits consisting of eight register data bits, 12 register address bits, and four special bits to distinguish between read/write, page and register, and individual channel access, as described in Table 25.

ADC31RF80 serial_interface_dgm_sbas747.gif Figure 134. SPI Timing Diagram

Table 24. SPI Timing Information

MIN TYP MAX UNIT
fSCLK SCLK frequency (equal to 1 / tSCLK) 1 20 MHz
tSLOADS SEN to SCLK setup time 50 ns
tSLOADH SCLK to SEN hold time 50 ns
tDSU SDIN setup time 10 ns
tDH SDIN hold time 10 ns
tSDOUT Delay between SCLK falling edge to SDOUT 10 ns

Table 25. SPI Input Description

SPI BIT DESCRIPTION OPTIONS
R/W bit Read/write bit 0 = SPI write
1 = SPI read back
M bit SPI bank access 0 = Analog SPI bank (master)
1 = All digital SPI banks (main digital, interleaving, decimation filter, JESD digital, and so forth)
P bit JESD page selection bit 0 = Page access
1 = Register access
CH bit SPI access for a specific channel of the JESD SPI bank. Useful for the dual-channel device, ADC32RF80.
ADDR[11:0] SPI address bits
DATA[7:0] SPI data bits

Figure 135 shows the SDOUT timing when data are read back from a register. Data are placed on the SDOUT bus at the SCLK falling edge after a delay of tSDOUT (10 ns typical) so that the data can be latched at the SCLK rising edge by the external receiver.

ADC31RF80 sdout_tmg_sbas860.gif Figure 135. SDOUT Timing

Serial Register Write: Analog Bank

The internal register of the ADC31RF80 analog bank (Figure 136) can be programmed by:

  1. Driving the SEN pin low.
  2. Initiating a serial interface cycle selecting the page address of the register whose content must be written. To select the master page: write address 0012h with 04h. To select the ADC page: write address 0011h with FFh.
  3. Writing the register content. When a page is selected, multiple registers located in the same page can be programmed.

ADC31RF80 srl_rgstr_write_sbas747.gif Figure 136. SPI Write Timing Diagram for the Analog Bank

Serial Register Readout: Analog Bank

Contents of the registers located in the two pages of the analog bank (Figure 137) can be readback by:

  1. Driving the SEN pin low.
  2. Selecting the page address of the register whose content must be read. Master page: write address 0012h with 04h. ADC page: write address 0011h with FFh.
  3. Setting the R/W bit to 1 and writing the address to be read back.
  4. Reading back the register content on the SDOUT pin. When a page is selected, the contents of multiple registers located in same page can be readback.

ADC31RF80 srl_rgstr_read_sbas747.gif Figure 137. SPI Read Timing Diagram for the Analog Bank

Serial Register Write: Digital Bank

The digital bank contains four pages (the offset corrector page, digital gain page, main digital page, and JESD digital page). Figure 138 shows the timing for the individual page selection. The registers located in the pages of the digital bank can be programmed by:

  1. Driving the SEN pin low.
  2. Setting the M bit to 1 and specifying the page with with the desired register. There are seven pages in Digital Bank. These pages can be selected by appropriately programming register bits DIGITAL BANK PAGE SEL, located in addresses 002h, 003h, and 004h, using three consecutive SPI cycles. Addressing in a SPI cycle begins with 4xxx when selecting a page from digital bank because the M bit must be set to 1.
    • To select the offset corrector page: write address 4004h with 61h, 4003h with 00h, and 4002h with 00h.
    • To select the digital gain page: write address 4004h with 61h, 4003h with 00h, and 4002h with 05h.
    • To select the main digital page: write address 4004h with 68h, 4003h with 00h, and 4002h with 00h.
    • To select the JESD digital page: write address 4004h with 69h, 4003h with 00h, and 4002h with 00h.
  3. ADC31RF80 dgtl_bank_spi_pg_sbas747.gif Figure 138. SPI Write Timing Diagram for Digital Bank Page Selection
  4. Writing into the desired register by setting both the M bit and P bit to 1. Write register content. When a page is selected, multiple writes into the same page can be done. As shown in Figure 139, addressing in an SPI cycle begins with 6xxx when selecting a page from the digital bank because the M bit must be set to 1.
  5. Keep CH = 1 while programing registers in JESD digital page. Thus, an SPI cycle to program registers in JESD digital page begins with 7xxx.

    ADC31RF80 dgtal_bank_reg_write_sbas860.gif Figure 139. SPI Write Timing Diagram for Digital Bank Register Write

Serial Register Readout: Digital Bank

Readback of the register in one of the digital banks (as shown in Figure 140) can be accomplished by:

  1. Driving the SEN pin low.
  2. Selecting the page in the digital page: follow step 2 in the Serial Register Write: Digital Bank section.
  3. Set the R/W, M, P, and CH bits to 1, and write the address to be read back.
  4. Read back the register content on the SDOUT pin. When a page is selected, multiple read backs from the same page can be done.

ADC31RF80 digital_bank_serial_read_tim_sbas860.gif Figure 140. SPI Read Timing Diagram for the Digital Bank

Serial Register Write: Decimation Filter and Power Detector Pages

The decimation filter and power detector pages are special pages that accept direct addressing. The sampling clock and SYSREF signal are required to properly configure the decimation settings. Registers located in these pages can be programmed in one SPI cycle (Figure 141).

  1. Drive the SEN pin low.
  2. Directly write to the decimation filter or power detector pages. To program registers in these pages, set M = 1 and CH = 1. Additionally, address bit A[10] selects the decimation filter page (A[10] = 0) or the power detector page (A[10] = 1).
    • Decimation filter page: SPI cycle begins with 50xxh.
    • Power detector page: SPI cycle begins with 54xxh.
Example: Writing address 5001h with 02h selects the decimation filter page and programs a decimation factor of divide-by-8 (complex output).

ADC31RF80 dgtl_bank_srl_rgstr_write_timing_sbas747.gif Figure 141. SPI Write Timing Diagram for the Decimation and Power Detector Pages

Register Maps

The ADC31RF80 contains two main SPI banks. The analog SPI bank provides access to the ADC core and the digital SPI bank controls the digital blocks (including the serial JESD interface). Figure 142 and Figure 143 provide a conceptual view of the SPI registers inside the ADC31RF80. The analog SPI bank contains the master and ADC pages. The digital SPI bank is divided into multiple pages (the main digital, digital gain, decimation filter, JESD digital, and power detector pages).

ADC31RF80 serial_reg_2stepprog_sbas860.gif
In general, SPI writes are completed in two steps. The first step is to access the necessary page. The second step is to program the desired register in that page. When a page is accessed, the registers in that page can be programmed and read back multiple times.
Registers in the decimation filter page and the power detector page can be directly programmed in one SPI cycle.
The CH bit is a don't care bit and is recommended to be kept at 0.
Figure 142. SPI Registers, Two-Step Addressing
ADC31RF80 serial_reg_direct_prog_sbas860.gif
Registers in the decimation filter page and the power detector page can be directly programmed in one SPI cycle.
To program registers in the decimation filter page.
To program registers in power detector page.
Figure 143. SPI Registers: Direct Addressing

Table 26 lists the register map for the ADC31RF80.

Table 26. Register Map

REGISTER ADDRESS
A[11:0] (Hex)
REGISTER DATA
7 6 5 4 3 2 1 0
GENERAL REGISTERS
000 RESET 0 0 0 0 0 0 RESET
002 DIGITAL BANK PAGE SEL[7:0]
003 DIGITAL BANK PAGE SEL[15:8]
004 DIGITAL BANK PAGE SEL[23:16]
010 0 0 0 0 0 0 0 3 or 4 WIRE
011 ADC PAGE SEL
012 0 0 0 0 0 MASTER PAGE SEL 0 0
MASTER PAGE (M = 0)
020 0 0 0 PDN SYSREF 0 0 0 GLOBAL PDN
032 0 0 INCR CM IMPEDANCE 0 0 0 0 0
039 0 ALWAYS WRITE 1 0 ALWAYS WRITE 1 0 0 0 SYNC TERM DIS
03C 0 SYSREF DEL EN 0 0 0 0 SYSREF DEL[4:3]
03D 0 0 0 0 0 JESD OUTPUT SWING
05A SYSREF DEL[2:0] 0 0 0 0 0
057 0 0 0 SEL SYSREF REG ASSERT SYSREF REG 0 0 0
058 0 0 SYNCB POL 0 0 0 0 0
ADC PAGE (FFh, M = 0)
03F 0 0 0 0 0 SLOW SP EN1 0 0
042 0 0 0 SLOW SP EN2 0 0 1 1
Offset Corr Page (610000h, M = 1)
68 FREEZE OFFSET CORR ALWAYS WRITE 1 0 0 0 DIS OFFSET CORR ALWAYS WRITE 1 0
Digital Gain Page (610005, M = 1)
0A6 0 0 0 0 DIGITAL GAIN
Main Digital Page (680000h, M = 1)
000 0 0 0 0 0 0 0 DIG CORE RESET GBL
0A2 0 0 0 0 NQ ZONE EN NYQUIST ZONE
0A5 Sampling Frequency
0A9 0 0 0 0 Sampling Frequency Enable 0 1 1
0B0 Band1 Lower-Edge Frequency LSB Setting
0B1 0 0 0 Band1 Lower-Edge Frequency MSB Setting
0B2 Band1 Upper-Edge Frequency LSB Setting
0B3 0 0 Band1 Frequency Range Enable Band1 Upper-Edge Frequency MSB Setting
0B4 Band2 Lower-Edge Frequency LSB Setting
0B5 0 0 0 Band2 Lower-Edge Frequency MSB Setting
0B6 Band2 Upper-Edge Frequency LSB Setting
0B7 0 0 Band2 Frequency Range Enable Band2 Upper-Edge Frequency MSB Setting
0B8 Band3 Lower-Edge Frequency LSB Setting
0B9 0 0 0 Band3 Lower-Edge Frequency MSB Setting
0BA Band3 Upper-Edge Frequency LSB Setting
0BB 0 0 Band3 Frequency Range Enable Band3 Upper-Edge Frequency MSB Setting
JESD DIGITAL PAGE (690000h, M = 1)
001 CTRL K 0 0 TESTMODE EN 0 LANE ALIGN FRAME ALIGN TX LINK DIS
002 SYNC REG SYNC REG EN 0 0 12BIT MODE JESD MODE0
003 LINK LAYER TESTMODE LINK LAY RPAT LMFC MASK RESET JESD MODE1 JESD MODE2 RAMP 12BIT
004 0 0 0 0 0 0 REL ILA SEQ
006 SCRAMBLE EN 0 0 0 0 0 0 0
007 0 0 0 FRAMES PER MULTIFRAME (K)
016 0 40X MODE 0 0 0 0
017 0 0 0 0 LANE0
POL
LANE1
POL
LANE2
POL
LANE3
POL
032 SEL EMP LANE 0 0 0
033 SEL EMP LANE 1 0 0
034 SEL EMP LANE 2 0 0
035 SEL EMP LANE 3 0 0
036 0 CMOS SYNCB 0 0 0 0 0 0
037 0 0 0 0 0 0 PLL MODE
03C 0 0 0 0 0 0 0 EN CMOS SYNCB
03E 0 MASK CLKDIV SYSREF MASK NCO SYSREF 0 0 0 0 0
DECIMATION FILTER PAGE (Direct Addressing, 16-Bit Address, 5000h)
000 0 0 0 0 0 0 0 DDC EN
001 0 0 0 0 DECIM FACTOR
002 0 0 0 0 0 0 0 DUAL BAND EN
005 0 0 0 0 0 0 0 REAL OUT EN
007 DDC0 NCO1 LSB
008 DDC0 NCO1 MSB
009 DDC0 NCO2 LSB
00A DDC0 NCO2 MSB
00B DDC0 NCO3 LSB
00C DDC0 NCO3 MSB
00D DDC1 NCO4 LSB
00E DDC1 NCO4 MSB
00F 0 0 0 0 0 0 0 NCO SEL PIN
010 0 0 0 0 0 0 NCO SEL
011 0 0 0 0 0 0 LMFC RESET MODE
014 0 0 0 0 0 0 0 DDC0 6DB GAIN
016 0 0 0 0 0 0 0 DDC1 6DB GAIN
01E 0 DDC DET LAT 0 0 0 0
01F 0 0 0 0 0 0 0 WBF 6DB GAIN
033 CUSTOM PATTERN1[7:0]
034 CUSTOM PATTERN1[15:8]
035 CUSTOM PATTERN2[7:0]
036 CUSTOM PATTERN2[15:8]
037 TEST PATTERN DDC1 Q-DATA TEST PATTERN DDC1 I-DATA
038 TEST PATTERN DDC2 Q-DATA TEST PATTERN DDC2 I -DATA
039 0 0 0 0 0 0 0 USE COMMON TEST PATTERN
03A 0 0 0 0 0 0 TEST PAT RES TP RES EN
POWER DETECTOR PAGE (Direct Addressing, 16-Bit Address, 5400h)
000 0 0 0 0 0 0 0 PKDET EN
001 BLKPKDET [7:0]
002 BLKPKDET [15:8]
003 0 0 0 0 0 0 0 BLKPKDET [16]
007 BLKTHHH
008 BLKTHHL
009 BLKTHLH
00A BLKTHLL
00B DWELL[7:0]
00C DWELL[15:8]
00D 0 0 0 0 0 0 0 FILT0LPSEL
00E 0 0 0 0 TIMECONST
00F FIL0THH[7:0]
010 FIL0THH[15:8]
011 FIL0THL[7:0]
012 FIL0THL[15:8]
013 0 0 0 0 0 0 0 IIR0 2BIT EN
016 FIL1THH[7:0]
017 FIL1THH[15:8]
018 FIL1THL[7:0]
019 FIL1THL[15:8]
01A 0 0 0 0 0 0 0 IIR1 2BIT EN
01D DWELLIIR[7:0]
01E DWELLIIR[15:8]
020 0 0 0 0 0 0 0 IIR0 2BIT EN
021 0 0 0 PWRDETACCU
022 PWRDETH[7:0]
023 PWRDETH[15:8]
024 PWRDETL[7:0]
025 PWRDETL[15:8]
027 0 0 0 0 0 0 0 RMS 2BIT EN
02B 0 0 0 RESET AGC 0 0 0 0
032 OUTSEL GPIO4
033 OUTSEL GPIO1
034 OUTSEL GPIO3
035 OUTSEL GPIO2
037 0 0 0 0 IODIR GPIO2 IODIR GPIO3 IODIR GPIO1 IODIR GPIO4
038 0 0 INSEL1 0 0 INSEL0

Example Register Writes

This section provides three different example register writes. Table 27 describes a global power-down register write, Table 28 describes the register writes when the scrambler is enabled, and Table 29 describes the register writes for 8x decimation (complex output, 1 DDC mode) with the NCO set to 1.8 GHz (fS = 3 GSPS) and the JESD format configured to LMFS = 4421.

Table 27. Global Power-Down

ADDRESS DATA COMMENT
12h 04h Set the master page
20h 01h Set the global power-down

Table 28. Scrambler Enable

ADDRESS DATA COMMENT
4004h 69h Select the digital JESD page
4003h 00h
6006h 80h Scrambler enable

Table 29. 8x Decimation

ADDRESS DATA COMMENT
4004h 68h Select the main digital page
4003h 00h
6000h 01h Issue a digital reset
6000h 00h Clear the digital reset
4004h 69h Select the digital JESD page
4003h 00h
6002h 01h Set JESD MODE0 = 1
5000h 01h Enable the DDC
5001h 02h Set decimation to 8x complex
5007h 9Ah Set the LSB of DDC0, NCO1 to 9Ah (fNCO = 1.8 GHz, fS = 3 GSPS)
5008h 99h Set the MSB of DDC0, NCO1 to 99h (fNCO = 1.8 GHz, fS = 3 GSPS)
5014h 01h Enable the 6-dB digital gain of DDC0

Register Descriptions

Table 30 lists the access codes for the ADC31RF80 registers.

Table 30. ADC31RF80 Access Type Codes

Access Type Code Description
R R Read
R-W R/W Read or Write
W W Write
-n Value after reset or the default value

General Registers

Register 000h (address = 000h), General Registers

Figure 144. Register 000h
7 6 5 4 3 2 1 0
RESET 0 0 0 0 0 0 RESET
R/W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 31. Register 000h Field Descriptions

Bit Field Type Reset Description
7 RESET R/W 0h

0 = Normal operation


1 = Internal software reset, clears back to 0
6-1 0 W 0h Must write 0
0 RESET R/W 0h

0 = Normal operation(1)


1 = Internal software reset, clears back to 0
Both bits (7, 0) must be set simultaneously to perform a reset.

Register 002h (address = 002h), General Registers

Figure 145. Register 002h
7 6 5 4 3 2 1 0
DIGITAL BANK PAGE SEL[7:0]
R/W-0h

Table 32. Register 002h Field Descriptions

Bit Field Type Reset Description
7-0 DIGITAL BANK PAGE SEL[7:0] R/W 0h Program the JESD BANK PAGE SEL[23:0] bits to access the desired page in the JESD bank.
680000h = Main digital page
610000h = Digital function page
690000h = JESD digital page selected

Register 003h (address = 003h), General Registers

Figure 146. Register 003h
7 6 5 4 3 2 1 0
DIGITAL BANK PAGE SEL[15:8]
R/W-0h

Table 33. Register 003h Field Descriptions

Bit Field Type Reset Description
7-0 DIGITAL BANK PAGE SEL[15:8] R/W 0h Program the JESD BANK PAGE SEL[23:0] bits to access the desired page in the JESD bank.
680000h = Main digital page
610000h = Digital function page
690000h = JESD digital page selected

Register 004h (address = 004h), General Registers

Figure 147. Register 004h
7 6 5 4 3 2 1 0
DIGITAL BANK PAGE SEL[23:16]
R/W-0h

Table 34. Register 004h Field Descriptions

Bit Field Type Reset Description
7-0 DIGITAL BANK PAGE SEL[23:16] R/W 0h Program the JESD BANK PAGE SEL[23:0] bits to access the desired page in the JESD bank.
680000h = Main digital page
610000h = Digital function page
690000h = JESD digital page selected

Register 010h (address = 010h), General Registers

Figure 148. Register 010h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 3 or 4 WIRE
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 35. Register 010h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 3 or 4 WIRE R/W 0h 0 = 4-wire SPI (default)
1 = 3-wire SPI where SDIN become input or output

Register 011h (address = 011h), General Registers

Figure 149. Register 011h
7 6 5 4 3 2 1 0
ADC PAGE SEL
R/W-0h

Table 36. Register 011h Field Descriptions

Bit Field Type Reset Description
7-0 ADC PAGE SEL R/W 0h

00000000 = Normal operation, ADC page is not selected


11111111 = ADC page is selected; MASTER PAGE SEL must be set to 0

Register 012h (address = 012h), General Registers

Figure 150. Register 012h
7 6 5 4 3 2 1 0
0 0 0 0 0 MASTER PAGE SEL 0 0
W-0h W-0h W-0h W-0h W-0h R/W-0h W-0h W-0h

Table 37. Register 012h Field Descriptions

Bit Field Type Reset Description
7-3 0 W 0h Must write 0
2 MASTER PAGE SEL R/W 0h

0 = Normal operation


1 = Selects the master page address; ADC PAGE must be set to 0
1-0 0 W 0h Must write 0

Master Page (M = 0)

Register 020h (address = 020h), Master Page

Figure 151. Register 020h
7 6 5 4 3 2 1 0
0 0 0 PDN SYSREF 0 0 0 GLOBAL PDN
W-0h W-0h W-0h R/W-0h W-0h W-0h W-0h R/W-0h

Table 38. Register 020h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4 PDN SYSREF R/W 0h

This bit powers down the SYSREF input buffer.


0 = Normal operation
1 = SYSREF input capture buffer is powered down and further SYSREF input pulses are ignored
3-1 0 W 0h Must write 0
0 GLOBAL PDN R/W 0h This bit enables the global power-down.
0 = Normal operation
1 = Global power-down enabled

Register 032h (address = 032h), Master Page

Figure 152. Register 032h
7 6 5 4 3 2 1 0
0 0 INCR CM IMPEDANCE 0 0 0 0 0
W-0h W-0h R/W-0h W-0h W-0h W-0h W-0h W-0h

Table 39. Register 032h Field Descriptions

Bit Field Type Reset Description
7-6 0 W 0h Must write 0
5 INCR CM IMPEDANCE R/W 0h

Only use this bit when analog inputs are dc-coupled to the driver.


0 = VCM buffer directly drives the common point of biasing resistors.
1 = VCM buffer drives the common point of biasing resistors with > 5 kΩ
4-0 0 W 0h Must write 0

Register 039h (address = 039h), Master Page

Figure 153. Register 039h
7 6 5 4 3 2 1 0
0 ALWAYS WRITE 1 0 ALWAYS WRITE 1 0 0 0 SYNC TERM DIS
W-0h R/W-0h W-0h R/W-0h W-0h W-0h W-0h R/W-0h

Table 40. Register 039h Field Descriptions

Bit Field Type Reset Description
7 0 W 0h Must write 0
6 ALWAYS WRITE 1 R/W 0h Always set this bit to 1
5 0 W 0h Must write 0
4 ALWAYS WRITE 1 R/W 0h Always set this bit to 1
3-1 0 W 0h Must write 0
0 SYNC TERM DIS R/W 0h This bit disables the on-chip, 100-Ω termination resistors on the SYNCB input.
0 = On-chip, 100-Ω termination enabled
1 = On-chip, 100-Ω termination disabled

Register 03Ch (address = 03Ch), Master Page

Figure 154. Register 03Ch
7 6 5 4 3 2 1 0
0 SYSREF DEL EN 0 0 0 0 SYSREF DEL[4:3]
W-0h R/W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 41. Register 03Ch Field Descriptions

Bit Field Type Reset Description
7 0 W 0h Must write 0
6 SYSREF DEL EN R/W 0h This bit allows an internal delay to be added to the SYSREF input.
0 = SYSREF delay disabled
1 = SYSREF delay enabled through register settings [3Ch (bits 1-0), 5Ah (bits 7-5)]
5-2 0 W 0h Must write 0
1-0 SYSREF DEL[4:3] R/W 0h When the SYSREF delay feature is enabled (3Ch, bit 6) the delay can be adjusted in 25-ps steps; the first step is 175 ps. The PVT variation of each 25-ps step is ±10 ps. The 175-ps step is ±50 ps; see Table 43.

Register 05Ah (address = 05Ah), Master Page

Figure 155. Register 05Ah
7 6 5 4 3 2 1 0
SYSREF DEL[2:0] 0 0 0 0 0
R/W-0h W-0h W-0h W-0h W-0h W-0h

Table 42. Register 05Ah Field Descriptions

Bit Field Type Reset Description
7 SYSREF DEL2 R/W 0h When the SYSREF delay feature is enabled (3Ch, bit 6) the delay can be adjusted in 25-ps steps; the first step is 175 ps. The PVT variation of each 25-ps step is ±10 ps. The 175-ps step is ±50 ps; see Table 43.
6 SYSREF DEL1
5 SYSREF DEL0
4-0 0 W 0h Must write 0

Table 43. SYSREF DEL[2:0] Bit Settings

STEP SETTING STEP (NOM) TOTAL DELAY (NOM)
1 01000 175 ps 175 ps
2 00111 25 ps 200 ps
3 00110 25 ps 225 ps
4 00101 25 ps 250 ps
5 00100 25 ps 275 ps
6 00011 25 ps 300 ps

Register 03Dh (address = 3Dh), Master Page

Figure 156. Register 03Dh
7 6 5 4 3 2 1 0
0 0 0 0 0 JESD OUTPUT SWING
W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 44. Register 03Dh Field Descriptions

Bit Field Type Reset Description
7-3 0 W 0h Must write 0
2-0 JESD OUTPUT SWING R/W 0h These bits select the output amplitude, VOD (mVPP), of the JESD transmitter for all lanes.
0 = 860 mVPP
1= 810 mVPP
2 = 770 mVPP
3 = 745 mVPP
4 = 960 mVPP
5 = 930 mVPP
6 = 905 mVPP
7 = 880 mVPP

Register 057h (address = 057h), Master Page

Figure 157. Register 057h
7 6 5 4 3 2 1 0
0 0 0 SEL SYSREF REG ASSERT SYSREF REG 0 0 0
W-0h W-0h W-0h R/W-0h R/W-0h W-0h W-0h W-0h

Table 45. Register 057h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4 SEL SYSREF REG R/W 0h SYSREF can be asserted using this bit. Ensure that the SEL SYSREF REG register bit is set high before using this bit; see Using SYSREF .
0 = SYSREF is logic low
1 = SYSREF is logic high
3 ASSERT SYSREF REG R/W 0h Set this bit to use the SPI register to assert SYSREF.
0 = SYSREF is asserted by device pins
1 = SYSREF can be asserted by the ASSERT SYSREF REG register bit
Other bits = 0
2-0 0 W 0h Must write 0

Register 058h (address = 058h), Master Page

Figure 158. Register 058h
7 6 5 4 3 2 1 0
0 0 SYNCB POL 0 0 0 0 0
W-0h W-0h R/W-0h W-0h W-0h W-0h W-0h W-0h

Table 46. Register 058h Field Descriptions

Bit Field Type Reset Description
7-6 0 W 0h Must write 0
5 SYNCB POL R/W 0h This bit inverts the SYNCB polarity.
0 = Polarity is not inverted; this setting matches the timing diagrams in this document and is the proper setting to use
1 = Polarity is inverted
4-0 0 W 0h Must write 0

ADC Page (FFh, M = 0)

Register 03Fh (address = 03Fh), ADC Page

Figure 159. Register 03Fh
7 6 5 4 3 2 1 0
0 0 0 0 0 SLOW SP EN1 0 0
W-0h W-0h W-0h W-0h W-0h R/W-0h W-0h W-0h

Table 47. Register 03Fh Field Descriptions

Bit Field Type Reset Description
7-3 0 W 0h Must write 0
2 SLOW SP EN1 R/W 0h

This bit must be enabled for clock rates below 2.5 GSPS.


0 = ADC sampling rates are faster than 2.5 GSPS
1 = ADC sampling rates are slower than 2.5 GSPS
1-0 0 W 0h Must write 0

Register 042h (address = 042h), ADC Page

Figure 160. Register 042h
7 6 5 4 3 2 1 0
0 0 0 SLOW SP EN2 0 0 1 1
W-0h W-0h W-0h R/W-0h W-0h W-0h R/W-0h R/W-0h

Table 48. Register 042h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4 SLOW SP EN2 R/W 0h

This bit must be enabled for clock rates below 2.5 GSPS.


0 = ADC sampling rates are faster than 2.5 GSPS
1 = ADC sampling rates are slower than 2.5 GSPS
3-2 0 W 0h Must write 0
1-0 1 R/W 0h Must write 1

Digital Function Page (610000h, M = 1)

Register A6h (address = 0A6h), Digital Function Page

Figure 161. Register 0A6h
7 6 5 4 3 2 1 0
0 0 0 0 DIG GAIN
W-0h W-0h W-0h W-0h R/W-0h

Table 49. Register 0A6h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3-0 DIG GAIN R/W 0h These bits set the digital gain of the ADC output data prior to decimation up to 11 dB; see Table 50.

Table 50. DIG GAIN Bit Settings

SETTING DIGITAL GAIN
0000 0 dB
0001 1 dB
0010 2 dB
1010 10 dB
1011 11 dB

Offset Corr Page (610000h, M = 1)

Register 034h (address = 034h), Offset Corr Page

Figure 162. Register 034h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 SEL EXT EST
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 51. Register 034h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 SEL EXT EST R/W 0h This bit selects the external estimate for the offset correction block; see the Using DC Coupling in the ADC31RF80 section.

Register 068h (address = 068h), Offset Corr Page

Figure 163. Register 068h
7 6 5 4 3 2 1 0
FREEZE OFFSET CORR ALWAYS WRITE 1 0 0 0 DIS OFFSET CORR ALWAYS WRITE 1 0
R/W-0h R/W-0h W-0h W-0h W-0h R/W-0h R/W-0h W-0h

Table 52. Register 068h Field Descriptions

Bit Field Type Reset Description
7 FREEZE OFFSET CORR R/W 0h Use this bit and bits 5 and 1 to freeze the offset estimation process of the offset corrector; see the Using DC Coupling in the ADC31RF80 section.
011 = Apply this setting after powering up the device
111 = Offset corrector is frozen, does not estimate offset anymore, and applies the last computed value.
Others = Do not use
6 ALWAYS WRITE 1 R/W 0h Always write this bit as 1 for the offset correction block to work properly.
5-3 0 W 0h Must write 0
2 DIS OFFSET CORR R/W 0h 0 = Offset correction block works and removes fS / 8, fS / 4, 3fS / 8, and fS / 2 spurs
1 = Offset correction block is disabled
1 ALWAYS WRITE 1 R/W 0h Always write this bit as 1 for the offset correction block to work properly.
0 0 W 0h Must write 0

Digital Gain Page (610005h, M = 1)

Register 0A6h (address = 0A6h), Digital Gain Page

Figure 164. Register 0A6h
7 6 5 4 3 2 1 0
0 0 0 0 DIGITAL GAIN
W-0h W-0h W-0h W-0h R/W-0h

Table 53. Register 0A6h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3-0 DIGITAL GAIN R/W 0h These bits apply a digital gain to the ADC data (before the DDC) up to 11 dB.
0000 = Default
0001 = 1 dB
1011 = 11 dB
Others = Do not use

Main Digital Page (680000h, M = 1)

Register 000h (address = 000h), Main Digital Page

Figure 165. Register 000h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 DIG CORE RESET GBL
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 54. Register 000h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 DIG CORE RESET GBL R/W 0h Pulse this bit (0 →1 →0) to reset the digital core.
All Nyquist zone settings take effect when this bit is pulsed.

Register 0A2h (address = 0A2h), Main Digital Page

Figure 166. Register 0A2h
7 6 5 4 3 2 1 0
0 0 0 0 NQ ZONE EN NYQUIST ZONE
W-0h W-0h W-0h W-0h R/W-0h R/W-0h

Table 55. Register 0A2h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3 NQ ZONE EN R/W 0h This bit allows for specification of the operating Nyquist zone.
0 = Nyquist zone specification disabled
1 = Nyquist zone specification enabled
2-0 NYQUIST ZONE R/W 0h These bits specify the operating Nyquist zone for the analog correction loop.
Set the NQ ZONE EN bit before programming these bits.
For example, at s 3-GSPS chip clock, the first Nyquist zone is from dc to 1.5 GHz, the second Nyquist zone is from 1.5 GHz to 3 GHz, and so on.
000 = First Nyquist zone (dc – fS / 2)
001 = Second Nyquist zone (fS / 2 – fS)
010 = Third Nyquist zone
011 = Fourth Nyquist zone

Register 0A5h (address = 0A5h), Main Digital Page

Figure 167. Register 0A5h
7 6 5 4 3 2 1 0
Sampling Frequency
R/W-0h

Table 56. Register 0A5h Field Descriptions

Bit Field Type Reset Description
7-0 Sampling Frequency R/W 0h These bits specify the ADC sampling frequency .
Value = fS / 24; for example, if fS = 3000 MSPS, then value = round (3000 / 24) = 125.

Register 0A9h (address = 0A9h), Main Digital Page

Figure 168. Register 0A9h
7 6 5 4 3 2 1 0
0 0 0 0 Sampling Frequency Enable 0 1 1
W-0h W-0h W-0h W-0h R/W-0h W-0h R/W-0h R/W-0h

Table 57. Register 0A9h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3 Sampling Frequency Enable R/W 0h This bit allows for specification of operating sampling frequency.
0 = Sampling frequency specification disabled
1 = Sampling frequency specification enabled
2 0 W 0h Must write 0
1-0 1 R/W 0h Must write 0

Register 0B0h (address = 0B0h), Main Digital Page

Figure 169. Register 0B0h
7 6 5 4 3 2 1 0
Band1 Lower-Edge Frequency LSB Setting
R/W-0h

Table 58. Register 0B0h Field Descriptions

Bit Field Type Reset Description
7-0 Band1 Lower-Edge Frequency LSB Setting R/W 0h These bits specify the lower edge of the Band1 frequency (LSB 8-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz
The absolute frequency values should be entered here and not the aliased frequency values.

Register 0B1h (address = 0B1h), Main Digital Page

Figure 170. Register 0B1h
7 6 5 4 3 2 1 0
0 0 0 Band1 Lower-Edge Frequency MSB Setting
W-0h W-0h W-0h R/W-0h

Table 59. Register 0B1h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4-0 Band1 Lower-Edge Frequency MSB Setting R/W 0h These bits specify the lower edge of the Band1 frequency (MSB 5-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz

Register 0B2h (address = 0B2h), Main Digital Page

Figure 171. Register 0B2h
7 6 5 4 3 2 1 0
Band1 Upper-Edge Frequency LSB Setting
R/W-0h

Table 60. Register 0B2h Field Descriptions

Bit Field Type Reset Description
7-0 Band1 Upper-Edge Frequency LSB Setting R/W 0h These bits specify the upper edge of the Band1 frequency (LSB 8-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz
The absolute frequency values should be entered here and not the aliased frequency values.

Register 0B3h (address = 0B3h), Main Digital Page

Figure 172. Register 0B3h
7 6 5 4 3 2 1 0
0 0 Band1 Frequency Range Enable Band1 Upper-edge Frequency MSB setting
W-0h W-0h R/W-0h R/W-0h

Table 61. Register 0B3h Field Descriptions

Bit Field Type Reset Description
7-6 0 W 0h Must write 0
5 Band1 Frequency Range Enable R/W 0h This bit enables the Band1 frequency range settings.
The lower and upper frequency edge specifications for Band1 are used only if this bit is set to 1.
4-0 Band1 Upper-Edge Frequency MSB Setting R/W 0h These bits specify the upper edge of the Band1 frequency (MSB 5-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz

Register 0B4h (address = 0B4h), Main Digital Page

Figure 173. Register 0B4h
7 6 5 4 3 2 1 0
Band2 Lower-Edge Frequency LSB Setting
R/W-0h

Table 62. Register 0B4h Field Descriptions

Bit Field Type Reset Description
7-0 Band2 Lower-Edge Frequency LSB Setting R/W 0h These bits specify the lower edge of the Band2 frequency (LSB 8-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz
The absolute frequency values should be entered here and not the aliased frequency values.

Register 0B5h (address = 0B5h), Main Digital Page

Figure 174. Register 0B5h
7 6 5 4 3 2 1 0
0 0 0 Band2 Lower-Edge Frequency MSB Setting
W-0h W-0h W-0h R/W-0h

Table 63. Register 0B5h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4-0 Band2 Lower-Edge Frequency MSB Setting R/W 0h These bits specify the lower edge of the Band2 frequency (MSB 5-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz

Register 0B6h (address = 0B6h), Main Digital Page

Figure 175. Register 0B6h
7 6 5 4 3 2 1 0
Band2 Upper-Edge Frequency LSB Setting
R/W-0h

Table 64. Register 0B6h Field Descriptions

Bit Field Type Reset Description
7-0 Band2 Upper-Edge Frequency LSB Setting R/W 0h These bits specify the upper edge of the Band2 frequency (LSB 8-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz
The absolute frequency values should be entered here and not the aliased frequency values.

Register 0B7h (address = 0B7h), Main Digital Page

Figure 176. Register 0B7h
7 6 5 4 3 2 1 0
0 0 Band2 Frequency Range Enable Band2 Upper-Edge Frequency MSB Setting
W-0h W-0h R/W-0h R/W-0h

Table 65. Register 0B7h Field Descriptions

Bit Field Type Reset Description
7-6 0 W 0h Must write 0
5 Band2 Frequency Range Enable R/W 0h This bit enables the Band2 frequency range settings.
The lower and upper frequency edge specifications for Band2 are used only if this bit is set to 1.
4-0 Band2 Upper-Edge Frequency MSB Setting R/W 0h These bits specify the upper edge of the Band2 frequency (MSB 5-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz

Register 0B8h (address = 0B8h), Main Digital Page

Figure 177. Register 0B8h
7 6 5 4 3 2 1 0
Band3 Lower-Edge Frequency LSB Setting
R/W-0h

Table 66. Register 0B8h Field Descriptions

Bit Field Type Reset Description
7-0 Band3 Lower-Edge Frequency LSB Setting R/W 0h These bits specify the lower edge of the Band3 frequency (LSB 8-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz
The absolute frequency values should be entered here and not the aliased frequency values.

Register 0B9h (address = 0B9h), Main Digital Page

Figure 178. Register 0B9h
7 6 5 4 3 2 1 0
0 0 0 Band3 Lower-Edge Frequency MSB Setting
W-0h W-0h W-0h R/W-0h

Table 67. Register 0B9h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4-0 Band3 Lower-Edge Frequency MSB Setting R/W 0h These bits specify the lower edge of the Band3 frequency (MSB 5-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz

Register 0BAh (address = 0BAh), Main Digital Page

Figure 179. Register 0BAh
7 6 5 4 3 2 1 0
Band3 Upper-Edge Frequency LSB Setting
R/W-0h

Table 68. Register 0BAh Field Descriptions

Bit Field Type Reset Description
7-0 Band3 Upper-Edge Frequency LSB Setting R/W 0h These bits specify the upper edge of the Band3 frequency (LSB 8-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz
The absolute frequency values should be entered here and not the aliased frequency values.

Register 0BBh (address = 0BBh), Main Digital Page

Figure 180. Register 0BBh
7 6 5 4 3 2 1 0
0 0 Band3 Frequency Range Enable Band3 Upper-edge Frequency MSB setting
W-0h W-0h R/W-0h R/W-0h

Table 69. Register 0BBh Field Descriptions

Bit Field Type Reset Description
7-6 0 W 0h Must write 0
5 Band3 Frequency Range Enable R/W 0h This bit enables the Band3 frequency range settings.
The lower and upper frequency edge specifications for Band3 are used only if this bit is set to 1.
4-0 Band3 Upper-Edge Frequency MSB Setting R/W 0h These bits specify the upper edge of the Band3 frequency (MSB 5-bit settings).
1 LSB = 1 MHz
Range = 8191 MHz

JESD Digital Page (6900h, M = 1)

Register 001h (address = 001h), JESD Digital Page

Figure 181. Register 001h
7 6 5 4 3 2 1 0
CTRL K 0 0 TESTMODE EN 0 LANE ALIGN FRAME ALIGN TX LINK DIS
R/W-0h W-0h W-0h R/W-0h W-0h R/W-0h R/W-0h R/W-0h

Table 70. Register 001h Field Descriptions

Bit Field Type Reset Description
7 CTRL K R/W 0h This bit is the enable bit for the number of frames per multiframe.
0 = Default is five frames per multiframe
1 = Frames per multiframe can be set in register 07h
6-5 0 W 0h Must write 0
4 TESTMODE EN R/W 0h This bit generates a long transport layer test pattern mode according to section 5.1.6.3 of the JESD204B specification.
0 = Test mode disabled
1 = Test mode enabled
3 0 W 0h Must write 0
2 LANE ALIGN R/W 0h This bit inserts a lane alignment character (K28.3) for the receiver to align to the lane boundary per section 5.3.3.5 of the JESD204B specification.
0 = Normal operation
1 = Inserts lane alignment characters
1 FRAME ALIGN R/W 0h This bit inserts a frame alignment character (K28.7) for the receiver to align to the frame boundary per section 5.3.35 of the JESD204B specification.
0 = Normal operation
1 = Inserts frame alignment characters
0 TX LINK DIS R/W 0h This bit disables sending the initial link alignment (ILA) sequence when SYNC is deasserted.
0 = Normal operation
1 = ILA disabled

Register 002h (address = 002h ), JESD Digital Page

Figure 182. Register 002h
7 6 5 4 3 2 1 0
SYNC REG SYNC REG EN 0 0 12BIT MODE JESD MODE0
R/W-0h R/W-0h W-0h W-0h R/W-0h R/W-0h

Table 71. Register 002h Field Descriptions

Bit Field Type Reset Description
7 SYNC REG R/W 0h This bit provides SYNC control through the SPI.
0 = Normal operation
1 = ADC output data are replaced with K28.5 characters
6 SYNC REG EN R/W 0h This bit is the enable bit for SYNC control through the SPI.
0 = Normal operation
1 = SYNC control through the SPI is enabled (ignores the SYNCB input pins)
5-4 0 W 0h Must write 0
3-2 12BIT MODE R/W 0h This bit enables the 12-bit output mode for more efficient data packing.
00 = Normal operation, 14-bit output
01, 10 = Unused
11 = High-efficient data packing enabled
1-0 JESD MODE0 R/W 0h These bits select the configuration register to configure the correct LMFS frame assemblies for different decimation settings; see the JESD frame assembly tables in the JESD204B Frame Assembly section.
00 = 0
01 = 1
10 = 2
11 = 3

Register 003h (address = 003h), JESD Digital Page

Figure 183. Register 003h
7 6 5 4 3 2 1 0
LINK LAYER TESTMODE LINK LAY RPAT LMFC MASK RESET JESD MODE1 JESD MODE2 RAMP 12BIT
R/W-0h R/W-0h R/W-0h R/W-1h R/W-0h R/W-0h

Table 72. Register 003h Field Descriptions

Bit Field Type Reset Description
7-5 LINK LAYER TESTMODE R/W 0h These bits generate a pattern according to section 5.3.3.8.2 of the JESD204B document.
000 = Normal ADC data
001 = D21.5 (high-frequency jitter pattern)
010 = K28.5 (mixed-frequency jitter pattern)
011 = Repeat initial lane alignment (generates a K28.5 character and repeats lane alignment sequences continuously)
100 = 12-octet RPAT jitter pattern
4 LINK LAY RPAT R/W 0h This bit changes the running disparity in a modified RPAT pattern test mode (only when link layer test mode = 100).
0 = Normal operation
1 = Changes disparity
3 LMFC MASK RESET R/W 0h 0 = Normal operation
2 JESD MODE1 R/W 1h These bits select the configuration register to configure the correct LMFS frame assemblies for different decimation settings; see the JESD frame assembly tables in the JESD204B Frame Assembly section
1 JESD MODE2 R/W 0h These bits select the configuration register to configure the correct LMFS frame assemblies for different decimation settings; see the JESD frame assembly tables in the JESD204B Frame Assembly section
0 RAMP 12BIT R/W 0h 12-bit RAMP test pattern.
0 = Normal data output
1 = Digital output is the RAMP pattern

Register 004h (address = 004h), JESD Digital Page

Figure 184. Register 004h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 REL ILA SEQ
W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 73. Register 004h Field Descriptions

Bit Field Type Reset Description
7-2 0 W 0h Must write 0
1-0 REL ILA SEQ R/W 0h These bits delay the generation of the lane alignment sequence by 0, 1, 2, or 3 multiframes after the code group synchronization.
00 = 0 multiframe delays
01 = 1 multiframe delay
10 = 2 multiframe delays
11 = 3 multiframe delays

Register 006h (address = 006h), JESD Digital Page

Figure 185. Register 006h
7 6 5 4 3 2 1 0
SCRAMBLE EN 0 0 0 0 0 0 0
R/W-0h W-0h W-0h W-0h W-0h W-0h W-0h W-0h

Table 74. Register 006h Field Descriptions

Bit Field Type Reset Description
7 SCRAMBLE EN R/W 0h This bit is the scramble enable bit in the JESD204B interface.
0 = Scrambling disabled
1 = Scrambling enabled
6-0 0 W 0h Must write 0

Register 007h (address = 007h), JESD Digital Page

Figure 186. Register 007h
7 6 5 4 3 2 1 0
0 0 0 FRAMES PER MULTIFRAME (K)
W-0h W-0h W-0h R/W-0h

Table 75. Register 007h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4-0 FRAMES PER MULTIFRAME (K) R/W 0h These bits set the number of multiframes.
Actual K is the value in hex + 1 (that is, 0Fh is K = 16).

Register 016h (address = 016h), JESD Digital Page

Figure 187. Register 016h
7 6 5 4 3 2 1 0
0 40x MODE 0 0 0 0
W-0h R/W-0h W-0h W-0h W-0h W-0h

Table 76. Register 016h Field Descriptions

Bit Field Type Reset Description
7 0 W 0h Must write 0
6-4 40x MODE R/W 0h This register must be set for 40x mode operation.
000 = Register is set for 20x and 80x mode
111 = Register must be set for 40x mode
3-0 0 W 0h Must write 0

Register 017h (address = 017h), JESD Digital Page

Figure 188. Register 017h
7 6 5 4 3 2 1 0
0 0 0 0 Lane0
POL
Lane1
POL
Lane2
POL
Lane3
POL
W-0h W-0h W-0h W-0h R/W-0h R/W-0h R/W-0h R/W-0h

Table 77. Register 017h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3-0 Lane[3:0] POL R/W 0h These bits set the polarity of the individual JESD output lanes.
0 = Polarity as given in the pinout (noninverted)
1 = Inverts polarity (positive, P, or negative, M)

Register 032h-035h (address = 032h-035h), JESD Digital Page

Figure 189. Register 032h
7 6 5 4 3 2 1 0
SEL EMP LANE 0 0 0
R/W-0h W-0h W-0h
Figure 190. Register 033h
7 6 5 4 3 2 1 0
SEL EMP LANE 1 0 0
R/W-0h W-0h W-0h
Figure 191. Register 034h
7 6 5 4 3 2 1 0
SEL EMP LANE 2 0 0
R/W-0h W-0h W-0h
Figure 192. Register 035h
7 6 5 4 3 2 1 0
SEL EMP LANE 3 0 0
R/W-0h W-0h W-0h

Table 78. Register 032h-035h Field Descriptions

Bit Field Type Reset Description
7-2 SEL EMP LANE R/W 0h These bits select the amount of de-emphasis for the JESD output transmitter. The de-emphasis value in dB is measured as the ratio between the peak value after the signal transition to the settled value of the voltage in one bit period.
0 = 0 dB
1 = –1 dB
3 = –2 dB
7 = –4.1 dB
15 = –6.2 dB
31 = –8.2 dB
63 = –11.5 dB
1-0 0 W 0h Must write 0

Register 036h (address = 036h), JESD Digital Page

Figure 193. Register 036h
7 6 5 4 3 2 1 0
0 CMOS SYNCB 0 0 0 0 0 0
W-0h R/W-0h W-0h W-0h W-0h W-0h W-0h W-0h

Table 79. Register 036h Field Descriptions

Bit Field Type Reset Description
7 0 W 0h Must write 0
6 CMOS SYNCB R/W 0h This bit enables single-ended control of SYNCB using the GPIO4 pin (pin 63). The differential SYNCB input is ignored. Set the EN CMOS SYNCB bit and keep the CH bit high to make this bit effective.
0 = Differential SYNCB input
1 = Single-ended SYNCB input using pin 63
5-0 0 W 0h Must write 0

Register 037h (address = 037h), JESD Digital Page

Figure 194. Register 037h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 PLL MODE
W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 80. Register 037h Field Descriptions

Bit Field Type Reset Description
7-2 0 W 0h Must write 0
1-0 PLL MODE R/W 0h These bits select the PLL multiplication factor; see the JESD tables in the JESD204B Frame Assembly section for settings.
00 = 20x mode
01 = 16x mode
10 = 40x mode (the 40x MODE bit in register 16h must also be set)
11 = 80x mode

Register 03Ch (address = 03Ch), JESD Digital Page

Figure 195. Register 03Ch
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 EN CMOS SYNCB
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 81. Register 03Ch Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 EN CMOS SYNCB R/W 0h Set this bit and the CMOS SYNCB bit high to provide a single-ended SYNC input to the device instead of differential. Also, keep the CH bit high. Thus:
  1. Select the JESD digital page.
  2. Write address 7036h with value 40h.
  3. Write address 703Ch with value 01h.

Register 03Eh (address = 03Eh), JESD Digital Page

Figure 196. Register 03Eh
7 6 5 4 3 2 1 0
0 MASK CLKDIV SYSREF MASK NCO SYSREF 0 0 0 0 0
W-0h R/W-0h R/W-0h W-0h W-0h W-0h W-0h W-0h

Table 82. Register 03Eh Field Descriptions

Bit Field Type Reset Description
7 0 W 0h Must write 0
6 MASK CLKDIV SYSREF R/W 0h Use this bit to mask the SYSREF going to the input clock divider.
0 = Input clock divider is reset when SYSREF is asserted (that is, when SYSREF transitions from low to high)
1 = Input clock divider ignores SYSREF assertions
5 MASK NCO SYSREF R/W 0h Use this bit to mask the SYSREF going to the NCO in the DDC block and LMFC counter of the JESD interface.
0 = NCO phase and LMFC counter are reset when SYSREF is asserted (that is, when SYSREF transitions from low to high)
1 = NCO and LMFC counter ignore SYSREF assertions
4-0 0 W 0h Must write 0

Decimation Filter Page

Direct Addressing, 16-Bit Address, 5000h

Register 000h (address = 000h), Decimation Filter Page

Figure 197. Register 000h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 DDC EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 83. Register 000h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 DDC EN R/W 0h This bit enables the decimation filter.
0 = Do not use
1 = Decimation filter enabled

Register 001h (address = 001h), Decimation Filter Page

Figure 198. Register 001h
7 6 5 4 3 2 1 0
0 0 0 0 DECIM FACTOR
W-0h W-0h W-0h W-0h R/W-0h

Table 84. Register 001h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3-0 DECIM FACTOR R/W 0h These bits configure the decimation filter setting.
0000 = Divide-by-4 complex
0001 = Divide-by-6 complex
0010 = Divide-by-8 complex
0011 = Divide-by-9 complex
0100 = Divide-by-10 complex
0101 = Divide-by-12 complex
0110 = Not used
0111 = Divide-by-16 complex
1000 = Divide-by-18 complex
1001 = Divide-by-20 complex
1010 = Divide-by-24 complex
1011 = Not used
1100 = Divide-by-32 complex

Register 002h (address = 2h), Decimation Filter Page

Figure 199. Register 002h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 DUAL BAND EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 85. Register 002h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 DUAL BAND EN R/W 0h This bit enables the dual-band DDC filter for the corresponding channel.
0 = Single-band DDC; available in both ADC32RF80 and ADC32RF83
1 = Dual-band DDC; available in ADC32RF80 only

Register 005h (address = 005h), Decimation Filter Page

Figure 200. Register 005h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 REAL OUT EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 86. Register 005h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 REAL OUT EN R/W 0h This bit converts the complex output to real output at 2x the output rate.
0 = Complex output format
1 = Real output format

Register 007h (address = 007h), Decimation Filter Page

Figure 201. Register 007h
7 6 5 4 3 2 1 0
DDC0 NCO1 LSB
R/W-0h

Table 87. Register 007h Field Descriptions

Bit Field Type Reset Description
7-0 DDC0 NCO1 LSB R/W 0h These bits are the LSB of the NCO frequency word for NCO1 of DDC0 (band 1).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 008h (address = 008h), Decimation Filter Page

Figure 202. Register 008h
7 6 5 4 3 2 1 0
DDC0 NCO1 MSB
R/W-0h

Table 88. Register 008h Field Descriptions

Bit Field Type Reset Description
7-0 DDC0 NCO1 MSB R/W 0h These bits are the MSB of the NCO frequency word for NCO1 of DDC0 (band 1).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 009h (address = 009h), Decimation Filter Page

Figure 203. Register 009h
7 6 5 4 3 2 1 0
DDC0 NCO2 LSB
R/W-0h

Table 89. Register 009h Field Descriptions

Bit Field Type Reset Description
7-0 DDC0 NCO2 MSB R/W 0h These bits are the LSB of the NCO frequency word for NCO2 of DDC0 (band 1).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 00Ah (address = 00Ah), Decimation Filter Page

Figure 204. Register 00Ah
7 6 5 4 3 2 1 0
DDC0 NCO2 MSB
R/W-0h

Table 90. Register 00Ah Field Descriptions

Bit Field Type Reset Description
7-0 DDC0 NCO2 MSB R/W 0h These bits are the MSB of the NCO frequency word for NCO2 of DDC0 (band 1).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 00Bh (address = 00Bh), Decimation Filter Page

Figure 205. Register 00Bh
7 6 5 4 3 2 1 0
DDC0 NCO3 LSB
R/W-0h

Table 91. Register 00Bh Field Descriptions

Bit Field Type Reset Description
7-0 DDC0 NCO3 LSB R/W 0h These bits are the LSB of the NCO frequency word for NCO3 of DDC0 (band 1).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 00Ch (address = 00Ch), Decimation Filter Page

Figure 206. Register 00Ch
7 6 5 4 3 2 1 0
DDC0 NCO3 MSB
R/W-0h

Table 92. Register 00Ch Field Descriptions

Bit Field Type Reset Description
7-0 DDC0 NCO3 MSB R/W 0h These bits are the MSB of the NCO frequency word for NCO3 of DDC0 (band 1).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 00Dh (address = 00Dh), Decimation Filter Page

Figure 207. Register 00Dh
7 6 5 4 3 2 1 0
DDC1 NCO4 LSB
R/W-0h

Table 93. Register 00Dh Field Descriptions

Bit Field Type Reset Description
7-0 DDC1 NCO4 LSB R/W 0h These bits are the LSB of the NCO frequency word for NCO4 of DDC1 (band 2, only when dual-band mode is enabled).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 00Eh (address = 00Eh), Decimation Filter Page

Figure 208. Register 00Eh
7 6 5 4 3 2 1 0
DDC1 NCO4 MSB
R/W-0h

Table 94. Register 00Eh Field Descriptions

Bit Field Type Reset Description
7-0 DDC1 NCO4 MSB R/W 0h These bits are the MSB of the NCO frequency word for NCO4 of DDC1 (band 2, only when dual-band mode is enabled).
The LSB represents fS / (216), where fS is the ADC sampling frequency.

Register 00Fh (address = 00Fh), Decimation Filter Page

Figure 209. Register 00Fh
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 NCO SEL PIN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 95. Register 00Fh Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 NCO SEL PIN R/W 0h This bit enables NCO selection through the GPIO pins.
0 = NCO selection through SPI (see address 0h10)
1 = NCO selection through GPIO pins

Register 010h (address = 010h), Decimation Filter Page

Figure 210. Register 010h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 NCO SEL
W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 96. Register 010h Field Descriptions

Bit Field Type Reset Description
7-2 0 W 0h Must write 0
1-0 NCO SEL R/W 0h

These bits enable NCO selection through register setting.


00 = NCO1 selected for DDC 1
01 = NCO2 selected for DDC 1
10 = NCO3 selected for DDC 1

Register 011h (address = 011h), Decimation Filter Page

Figure 211. Register 011h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 LMFC RESET MODE
W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 97. Register 011h Field Descriptions

Bit Field Type Reset Description
7-2 0 W 0h Must write 0
1-0 LMFC RESET MODE R/W 0h

These bits reset the configuration for all DDCs and NCOs.


00 = All DDCs and NCOs are reset with every LMFC RESET
01 = Reset with first LMFC RESET after DDC start. Afterwards, reset only when analog clock dividers are resynchronized.
10 = Reset with first LMFC RESET after DDC start. Afterwards, whenever analog clock dividers are resynchronized, use two LMFC resets.
11 = Do not use an LMFC reset at all. Reset the DDCs only when a DDC start is asserted and afterwards continue normal operation. Deterministic latency is not ensured.

Register 014h (address = 014h), Decimation Filter Page

Figure 212. Register 014h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 DDC0 6DB GAIN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 98. Register 014h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 DDC0 6DB GAIN R/W 0h

This bit scales the output of DDC0 by 2 (6 dB) to compensate for real-to-complex conversion and image suppression. This scaling does not apply to the high-bandwidth filter path (divide-by-4 and -6); see register 1Fh.


0 = Normal operation
1 = 6-dB digital gain is added

Register 016h (address = 016h), Decimation Filter Page

Figure 213. Register 016h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 DDC1 6DB GAIN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 99. Register 016h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 DDC1 6DB GAIN R/W 0h

This bit scales the output of DDC1 by 2 (6 dB) to compensate for real-to-complex conversion and image suppression. This scaling does not apply to the high-bandwidth filter path (divide-by-4 and -6); see register 1Fh.


0 = Normal operation
1 = 6-dB digital gain is added

Register 01Eh (address = 01Eh), Decimation Filter Page

Figure 214. Register 01Eh
7 6 5 4 3 2 1 0
0 DDC DET LAT 0 0 0 0
W-0h R/W-0h W-0h W-0h W-0h W-0h

Table 100. Register 01Eh Field Descriptions

Bit Field Type Reset Description
7 0 W 0h Must write 0
6-4 DDC DET LAT R/W 0h These bits ensure deterministic latency depending on the decimation setting used; see Table 101.
3-0 0 W 0h Must write 0

Table 101. DDC DET LAT Bit Settings

SETTING COMPLEX DECIMATION SETTING
10h Divide-by-24, -32 complex
20h Divide-by-16, -18, -20 complex
40h Divide-by-by 6, -12 complex
50h Divide-by-4, -8, -9, -10 complex

Register 01Fh (address = 01Fh), Decimation Filter Page

Figure 215. Register 01Fh
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 WBF 6DB GAIN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 102. Register 01Fh Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 WBF 6DB GAIN R/W 0h

This bit scales the output of the wide bandwidth DDC filter by 2 (6 dB) to compensate for real-to-complex conversion and image suppression. This setting only applies to the high-bandwidth filter path (divide-by-4 and -6).


0 = Normal operation
1 = 6-dB digital gain is added

Register 033h-036h (address = 033h-036h), Decimation Filter Page

Figure 216. Register 033h
7 6 5 4 3 2 1 0
CUSTOM PATTERN1[7:0]
R/W-0h
Figure 217. Register 034h
7 6 5 4 3 2 1 0
CUSTOM PATTERN1[15:8]
R/W-0h
Figure 218. Register 035h
7 6 5 4 3 2 1 0
CUSTOM PATTERN2[7:0]
R/W-0h
Figure 219. Register 036h
7 6 5 4 3 2 1 0
CUSTOM PATTERN2[15:8]
R/W-0h

Table 103. Register 033h-036h Field Descriptions

Bit Field Type Reset Description
7-0 CUSTOM PATTERN R/W 0h These bits set the custom test pattern in address 33h, 34h, 35h, or 36h.

Register 037h (address = 037h), Decimation Filter Page

Figure 220. Register 037h
7 6 5 4 3 2 1 0
TEST PATTERN DDC1 Q-DATA TEST PATTERN DDC1 I-DATA
R/W-0h R/W-0h

Table 104. Register 037h Field Descriptions

Bit Field Type Reset Description
7-4 TEST PATTERN DDC1 Q-DATA W 0h These bits select the test patten for the Q stream of the DDC1.
0000 = Normal operation using ADC output data
0001 = Outputs all 0s
0010 = Outputs all 1s
0011 = Outputs toggle pattern: output data are an alternating sequence of 10101010101010 and 01010101010101
0100 = Output digital ramp: output data increment by one LSB every clock cycle from code 0 to 65535
0110 = Single pattern: output data are a custom pattern 1 (75h and 76h)
0111 Double pattern: output data alternate between custom pattern 1 and custom pattern 2
1000 = Deskew pattern: output data are AAAAh
1001 = SYNC pattern: output data are FFFFh
3-0 TEST PATTERN DDC1 I-DATA R/W 0h These bits select the test patten for the I stream of the DDC1.
0000 = Normal operation using ADC output data
0001 = Outputs all 0s
0010 = Outputs all 1s
0011 = Outputs toggle pattern: output data are an alternating sequence of 10101010101010 and 01010101010101
0100 = Output digital ramp: output data increment by one LSB every clock cycle from code 0 to 65535
0110 = Single pattern: output data are a custom pattern 1 (75h and 76h)
0111 Double pattern: output data alternate between custom pattern 1 and custom pattern 2
1000 = Deskew pattern: output data are AAAAh
1001 = SYNC pattern: output data are FFFFh

Register 038h (address = 038h), Decimation Filter Page

Figure 221. Register 038h
7 6 5 4 3 2 1 0
TEST PATTERN DDC2 Q-DATA TEST PATTERN DDC2 I -DATA
R/W-0h R/W-0h

Table 105. Register 038h Field Descriptions

Bit Field Type Reset Description
7-4 TEST PATTERN DDC2 Q-DATA R/W 0h These bits select the test patten for the Q stream of the DDC2.
0000 = Normal operation using ADC output data
0001 = Outputs all 0s
0010 = Outputs all 1s
0011 = Outputs toggle pattern: output data are an alternating sequence of 10101010101010 and 01010101010101
0100 = Output digital ramp: output data increment by one LSB every clock cycle from code 0 to 65535
0110 = Single pattern: output data are a custom pattern 1 (75h and 76h)
0111 Double pattern: output data alternate between custom pattern 1 and custom pattern 2
1000 = Deskew pattern: output data are AAAAh
1001 = SYNC pattern: output data are FFFFh
3-0 TEST PATTERN DDC2 I -DATA R/W 0h These bits select the test patten for the I stream of the DDC2.
0000 = Normal operation using ADC output data
0001 = Outputs all 0s
0010 = Outputs all 1s
0011 = Outputs toggle pattern: output data are an alternating sequence of 10101010101010 and 01010101010101
0100 = Output digital ramp: output data increment by one LSB every clock cycle from code 0 to 65535
0110 = Single pattern: output data are a custom pattern 1 (75h and 76h)
0111 Double pattern: output data alternate between custom pattern 1 and custom pattern 2
1000 = Deskew pattern: output data are AAAAh
1001 = SYNC pattern: output data are FFFFh

Register 039h (address = 039h), Decimation Filter Page

Figure 222. Register 039h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 USE COMMON TEST PATTERN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 106. Register 039h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 USE COMMON TEST PATTERN R/W 0h 0 = Each data stream sends test patterns programmed by bits[3:0] of register 37h.
1 = Test patterns are individually programmed for the I and Q stream of each DDC using the TEST PATTERN DDCx y-DATA register bits (where x = 1 or 2 and y = I or Q).

Register 03Ah (address = 03Ah), Decimation Filter Page

Figure 223. Register 03Ah
7 6 5 4 3 2 1 0
0 0 0 0 0 0 TEST PAT RES TP RES EN
W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h R/W-0h

Table 107. Register 03Ah Field Descriptions

Bit Field Type Reset Description
7-2 0 W 0h Must write 0
1 TEST PAT RES R/W 0h Pulsing this bit resets the test pattern. The test pattern reset must be enabled first (bit D0).
0 = Normal operation
1 = Reset the test pattern
0 TP RES EN R/W 0h This bit enables the test pattern reset.
0 = Reset disabled
1 = Reset enabled

Power Detector Page

Register 000h (address = 000h), Power Detector Page

Figure 224. Register 000h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 PKDET EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 108. Register 000h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 PKDET EN R/W 0h This bit enables the peak power and crossing detector.
0 = Power detector disabled
1 = Power detector enabled

Register 001h-002h (address = 001h-002h), Power Detector Page

Figure 225. Register 001h
7 6 5 4 3 2 1 0
BLKPKDET [7:0]
R/W-0h
Figure 226. Register 002h
7 6 5 4 3 2 1 0
BLKPKDET [15:8]
R/W-0h

Table 109. Register 001h-002h Field Descriptions

Bit Field Type Reset Description
7-0 BLKPKDET R/W 0h This register specifies the block length in terms of number of samples (S`) used for peak power computation. Each sample S` is a peak of 8 actual ADC samples. This parameter is a 17-bit value directly in linear scale. In decimation mode, the block length must be a multiple of a divide-by-4 or -6 complex: length = 5 × decimation factor.
The divide-by-8 to -32 complex: length = 10 × decimation factor.

Register 003h (address = 003h), Power Detector Page

Figure 227. Register 003h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 BLKPKDET[16]
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 110. Register 003h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 BLKPKDET[16] R/W 0h This register specifies the block length in terms of number of samples (S`) used for peak power computation. Each sample S` is a peak of 8 actual ADC samples. This parameter is a 17-bit value directly in linear scale. In decimation mode, the block length must be a multiple of a divide-by-4 or -6 complex: length = 5 × decimation factor.
The divide-by-8 to -32 complex: length = 10 × decimation factor.

Register 007h-00Ah (address = 007h-00Ah), Power Detector Page

Figure 228. Register 007h
7 6 5 4 3 2 1 0
BLKTHHH
R/W-0h
Figure 229. Register 008h
7 6 5 4 3 2 1 0
BLKTHHL
R/W-0h
Figure 230. Register 009h
7 6 5 4 3 2 1 0
BLKTHLH
R/W-0h
Figure 231. Register 00Ah
7 6 5 4 3 2 1 0
BLKTHLL
R/W-0h

Table 111. Register 007h-00Ah Field Descriptions

Bit Field Type Reset Description
7-0 BLKTHHH
BLKTHHL
BLKTHLH
BLKTHLL
R/W 0h These registers set the four different thresholds for the hysteresis function threshold values from 0 to 256 (2TH), where 256 is equivalent to the peak amplitude.
Example: BLKTHHH is set to –2 dBFS from peak: 10(-2 / 20) × 256 = 203, then set 5407h = CBh.

Register 00Bh-00Ch (address = 00Bh-00Ch), Power Detector Page

Figure 232. Register 00Bh
7 6 5 4 3 2 1 0
DWELL[7:0]
R/W-0h
Figure 233. Register 00Ch
7 6 5 4 3 2 1 0
DWELL[15:8]
R/W-0h

Table 112. Register 00Bh-00Ch Field Descriptions

Bit Field Type Reset Description
7-0 DWELL R/W 0h DWELL time counter.
When the computed block peak crosses the upper thresholds BLKTHHH or BLKTHLH, the peak detector output flags are set. In order to be reset, the computed block peak must remain continuously lower than the lower threshold (BLKTHHL or BLKTHLL) for the period specified by the DWELL value. This threshold is 16 bits, is specified in terms of fS / 8 clock cycles, and must be set to 0 for the crossing detector. Example: if fS = 3 GSPS, fS / 8 = 375 MHz, and DWELL = 0100h then the DWELL time = 29 / 375 MHz = 1.36 µs.

Register 00Dh (address = 00Dh), Power Detector Page

Figure 234. Register 00Dh
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 FILT0LPSEL
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 113. Register 00Dh Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 FILT0LPSEL R/W 0h This bit selects either the block detector output or 2-bit output as the input to the IIR filter.
0 = Use the output of the high comparators (HH and HL) as the input of the IIR filter
1 = Combine the output of the high (HH and HL) and low (LH and LL) comparators to generate a 3-level input to the IIR filter (–1, 0, 1)

Register 00Eh (address = 00Eh), Power Detector Page

Figure 235. Register 00Eh
7 6 5 4 3 2 1 0
0 0 0 0 TIMECONST
W-0h W-0h W-0h W-0h R/W-0h

Table 114. Register 00Eh Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3-0 TIMECONST R/W 0h These bits set the crossing detector time period for N = 0 to 15 as 2N × fS / 8 clock cycles. The maximum time period is 32768 × fS / 8 clock cycles (approximately 87 µs at 3 GSPS).

Register 00Fh, 010h-012h, and 016h-019h (address = 00Fh, 010h-012h, and 016h-019h), Power Detector Page

Figure 236. Register 00Fh
7 6 5 4 3 2 1 0
FIL0THH[7:0]
R/W-0h
Figure 237. Register 010h
7 6 5 4 3 2 1 0
FIL0THH[15:8]
R/W-0h
Figure 238. Register 011h
7 6 5 4 3 2 1 0
FIL0THL[7:0]
R/W-0h
Figure 239. Register 012h
7 6 5 4 3 2 1 0
FIL0THL[15:8]
R/W-0h
Figure 240. Register 016h
7 6 5 4 3 2 1 0
FIL1THH[7:0]
R/W-0h
Figure 241. Register 017h
7 6 5 4 3 2 1 0
FIL1THH[15:8]
R/W-0h
Figure 242. Register 018h
7 6 5 4 3 2 1 0
FIL1THL[7:0]
R/W-0h
Figure 243. Register 019h
7 6 5 4 3 2 1 0
FIL1THL[15:8]
R/W-0h

Table 115. Register 00Fh, 010h, 011h, 012h, 016h, 017h, 018h, and 019h Field Descriptions

Bit Field Type Reset Description
7-0 FIL0THH
FIL0THL
FIL1THH
FIL1THL
R/W 0h Comparison thresholds for the crossing detector counter. This threshold is 16 bits in 2.14 signed notation. A value of 1 (4000h) corresponds to 100% crossings, a value of 0.125 (0800h) corresponds to 12.5% crossings.

Register 013h-01Ah (address = 013h-01Ah), Power Detector Page

Figure 244. Register 013h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 IIR0 2BIT EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h
Figure 245. Register 01Ah
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 IIR1 2BIT EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 116. Register 013h and 01Ah Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 IIR0 2BIT EN
IIR1 2BIT EN
R/W 0h This bit enables 2-bit output format of the IIR0 and IIR1 output comparators.
0 = Selects 1-bit output format
1 = Selects 2-bit output format

Register 01Dh-01Eh (address = 01Dh-01Eh), Power Detector Page

Figure 246. Register 01Dh
7 6 5 4 3 2 1 0
DWELLIIR[7:0]
R/W-0h
Figure 247. Register 01Eh
7 6 5 4 3 2 1 0
DWELLIIR[15:8]
R/W-0h

Table 117. Register 01Dh-01Eh Field Descriptions

Bit Field Type Reset Description
7-0 DWELLIIR R/W 0h DWELL time counter for the IIR output comparators. When the IIR filter output crosses the upper thresholds FIL0THH or FIL1THH, the IIR peak detector output flags are set. In order to be reset, the output of the IIR filter must remain continuously lower than the lower threshold (FIL0THL or FIL1THL) for the period specified by the DWELLIIR value. This threshold is 16 bits and is specified in terms of fS / 8 clock cycles.
Example: if fS = 3 GSPS, fS / 8 = 375 MHz, and DWELLIIR = 0100h, then the DWELL time = 29 / 375 MHz = 1.36 µs.

Register 020h (address = 020h), Power Detector Page

Figure 248. Register 020h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 RMSDET EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 118. Register 020h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 RMSDET EN R/W 0h This bit enables the RMS power detector.
0 = Power detector disabled
1 = Power detector enabled

Register 021h (address = 021h), Power Detector Page

Figure 249. Register 021h
7 6 5 4 3 2 1 0
0 0 0 PWRDETACCU
W-0h W-0h W-0h R/W-0h

Table 119. Register 021h Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4-0 PWRDETACCU R/W 0h These bits program the block length to be used for RMS power computation.
The block length is defined in terms of fS / 8 clocks and can be programmed as 2M, where M = 0 to 16.

Register 022h-025h (address = 022h-025h), Power Detector Page

Figure 250. Register 022h
7 6 5 4 3 2 1 0
PWRDETH[7:0]
R/W-0h
Figure 251. Register 023h
7 6 5 4 3 2 1 0
PWRDETH[15:8]
R/W-0h
Figure 252. Register 024h
7 6 5 4 3 2 1 0
PWRDETL[7:0]
R/W-0h
Figure 253. Register 025h
7 6 5 4 3 2 1 0
PWRDETL[15:8]
R/W-0h

Table 120. Register 022h-025h Field Descriptions

Bit Field Type Reset Description
7-0 PWRDETH[15:0]
PWRDETL[15:0]
R/W 0h The computed average power is compared against these high and low thresholds. One LSB of the thresholds represents 1 / 216.
Example: if PWRDETH is set to –14 dBFS from peak, (10(–14 / 20))2 × 216 = 2609, then set 5422h, 5423h = 0A31h.

Register 027h (address = 027h), Power Detector Page

Figure 254. Register 027h
7 6 5 4 3 2 1 0
0 0 0 0 0 0 0 RMS 2BIT EN
W-0h W-0h W-0h W-0h W-0h W-0h W-0h R/W-0h

Table 121. Register 027h Field Descriptions

Bit Field Type Reset Description
7-1 0 W 0h Must write 0
0 RMS 2BIT EN R/W 0h This bit enables 2-bit output format on the RMS output comparators.
0 = Selects 1-bit output format
1 = Selects 2-bit output format

Register 02Bh (address = 02Bh), Power Detector Page

Figure 255. Register 02Bh
7 6 5 4 3 2 1 0
0 0 0 RESET AGC 0 0 0 0
W-0h W-0h W-0h R/W-0h W-0h W-0h W-0h W-0h

Table 122. Register 02Bh Field Descriptions

Bit Field Type Reset Description
7-5 0 W 0h Must write 0
4 RESET AGC R/W 0h After configuration, the AGC module must be reset and then brought out of reset to start operation.
0 = Clear AGC reset
1 = Set AGC reset
Example: set 542Bh to 10h and then to 00h.
3-0 0 W 0h Must write 0

Register 032h-035h (address = 032h-035h), Power Detector Page

Figure 256. Register 032h
7 6 5 4 3 2 1 0
OUTSEL GPIO4
R/W-0h
Figure 257. Register 033h
7 6 5 4 3 2 1 0
OUTSEL GPIO1
R/W-0h
Figure 258. Register 034h
7 6 5 4 3 2 1 0
OUTSEL GPIO3
R/W-0h
Figure 259. Register 035h
7 6 5 4 3 2 1 0
OUTSEL GPIO2
R/W-0h

Table 123. Register 032h-035h Field Descriptions

Bit Field Type Reset Description
7-0 OUTSEL GPIO1
OUTSEL GPIO2
OUTSEL GPIO3
OUTSEL GPIO4
R/W 0h These bits set the function or signal for each GPIO pin.
0 = IIR PK DET0[0]
1 = IIR PK DET0[1] (2-bit mode)
2 = IIR PK DET1[0]
3 = IIR PK DET1[1] (2-bit mode)
4 = BLKPKDETH
5 = BLKPKDETL
6 = PWR Det[0]
7 = PWR Det[1] (2-bit mode)
8 = FOVR
Others = Do not use

Register 037h (address = 037h), Power Detector Page

Figure 260. Register 037h
7 6 5 4 3 2 1 0
0 0 0 0 IODIR GPIO2 IODIR GPIO3 IODIR GPIO1 IODIR GPIO4
W-0h W-0h W-0h W-0h R/W-0h R/W-0h R/W-0h R/W-0h

Table 124. Register 037h Field Descriptions

Bit Field Type Reset Description
7-4 0 W 0h Must write 0
3-0 IODIRGPIO[4:1] R/W 0h These bits select the output direction for the GPIO[4:1] pins.
0 = Input (for the NCO control)
1 = Output (for the AGC alarm function)

Register 038h (address = 038h), Power Detector Page

Figure 261. Register 038h
7 6 5 4 3 2 1 0
0 0 INSEL1 0 0 INSEL0
W-0h W-0h R/W-0h W-0h W-0h R/W-0h

Table 125. Register 038h Field Descriptions

Bit Field Type Reset Description
7-6 0 W 0h Must write 0
5-4 INSEL1 R/W 0h These bits select which GPIO pin is used for the INSEL1 bit.
00 = GPIO4
01 = GPIO1
10 = GPIO3
11 = GPIO2
Table 126 lists the NCO selection, based on the bit settings of the INSEL pins; see the section NCO Switching for details.
3-2 0 W 0h Must write 0
1-0 INSEL0 R/W 0h These bits select which GPIO pin is used for the INSEL0 bit.
00 = GPIO4
01 = GPIO1
10 = GPIO3
11 = GPIO2
Table 126 lists the NCO selection, based on the bit settings of the INSEL pins; see the section NCO Switching for details.

Table 126. INSEL Bit Settings

INSELx[1:0] (Where x = 0 or 1) NCO SELECTED
00 NCO1
01 NCO2
10 NCO3
11 n/a