SBAS869 September   2017 ADC32RF82

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 = 2457.6 MSPS
    7. 6.7  AC Performance Characteristics: fS = 2211.84 MSPS
    8. 6.8  AC Performance Characteristics: fS = 1966.08 MSPS
    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 Digital Multiplexer (MUX)
        5. 8.3.4.5 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 for Channel A and 610100h, M = 1 for Channel B)
        1. 8.5.5.1 Register A6h (address = 0A6h), Digital Function Page
      6. 8.5.6  Offset Corr Page Channel A (610000h, M = 1)
        1. 8.5.6.1 Register 034h (address = 034h), Offset Corr Page Channel A
        2. 8.5.6.2 Register 068h (address = 068h), Offset Corr Page Channel A
      7. 8.5.7  Offset Corr Page Channel B (610000h, M = 1)
        1. 8.5.7.1 Register 068h (address = 068h), Offset Corr Page Channel B
      8. 8.5.8  Digital Gain Page (610005h, M = 1 for Channel A and 610105h, M = 1 for Channel B)
        1. 8.5.8.1 Register 0A6h (address = 0A6h), Digital Gain Page
      9. 8.5.9  Main Digital Page Channel A (680000h, M = 1)
        1. 8.5.9.1 Register 000h (address = 000h), Main Digital Page Channel A
        2. 8.5.9.2 Register 0A2h (address = 0A2h), Main Digital Page Channel A
      10. 8.5.10 Register 0A5h (address = 0A5h) Main Digital Page Channel A
      11. 8.5.11 Register 0A9h (address = 0A9h) Main Digital Page Channel A
      12. 8.5.12 Register 0B0h (address = 0B0h) Main Digital Page Channel A
      13. 8.5.13 Register 0B1h (address = 0B1h) Main Digital Page Channel A
      14. 8.5.14 Register 0B2h (address = 0B2h) Main Digital Page Channel A
      15. 8.5.15 Register 0B3h (address = 0B3h) Main Digital Page Channel A
      16. 8.5.16 Register 0B4h (address = 0B4h) Main Digital Page Channel A
      17. 8.5.17 Register 0B5h (address = 0B5h) Main Digital Page Channel A
      18. 8.5.18 Register 0B6h (address = 0B6h) Main Digital Page Channel A
      19. 8.5.19 Register 0B7h (address = 0B7h) Main Digital Page Channel A
      20. 8.5.20 Register 0B8h (address = 0B8h) Main Digital Page Channel A
      21. 8.5.21 Register 0B9h (address = 0B9h) Main Digital Page Channel A
      22. 8.5.22 Register 0BAh (address = 0BAh) Main Digital Page Channel A
      23. 8.5.23 Register 0BBh (address = 0BBh) Main Digital Page Channel A
      24. 8.5.24 Main Digital Page Channel B (680001h, M = 1)
        1. 8.5.24.1  Register 000h (address = 000h), Main Digital Page Channel B
        2. 8.5.24.2  Register 0A2h (address = 0A2h), Main Digital Page Channel B
        3. 8.5.24.3  Register 0B0h (address = 0B0h) Main Digital Page Channel B
        4. 8.5.24.4  Register 0B1h (address = 0B1h) Main Digital Page Channel B
        5. 8.5.24.5  Register 0B2h (address = 0B2h) Main Digital Page Channel B
        6. 8.5.24.6  Register 0B3h (address = 0B3h) Main Digital Page Channel B
        7. 8.5.24.7  Register 0B4h (address = 0B4h) Main Digital Page Channel B
        8. 8.5.24.8  Register 0B5h (address = 0B5h) Main Digital Page Channel B
        9. 8.5.24.9  Register 0B6h (address = 0B6h) Main Digital Page Channel B
        10. 8.5.24.10 Register 0B7h (address = 0B7h) Main Digital Page Channel B
        11. 8.5.24.11 Register 0B8h (address = 0B8h) Main Digital Page Channel B
        12. 8.5.24.12 Register 0B9h (address = 0B9h) Main Digital Page Channel B
        13. 8.5.24.13 Register 0BAh (address = 0BAh) Main Digital Page Channel B
        14. 8.5.24.14 Register 0BBh (address = 0BBh) Main Digital Page Channel B
      25. 8.5.25 JESD Digital Page (6900h, M = 1)
        1. 8.5.25.1  Register 001h (address = 001h), JESD Digital Page
        2. 8.5.25.2  Register 002h (address = 002h ), JESD Digital Page
        3. 8.5.25.3  Register 003h (address = 003h), JESD Digital Page
        4. 8.5.25.4  Register 004h (address = 004h), JESD Digital Page
        5. 8.5.25.5  Register 006h (address = 006h), JESD Digital Page
        6. 8.5.25.6  Register 007h (address = 007h), JESD Digital Page
        7. 8.5.25.7  Register 016h (address = 016h), JESD Digital Page
        8. 8.5.25.8  Register 017h (address = 017h), JESD Digital Page
        9. 8.5.25.9  Register 032h-035h (address = 032h-035h), JESD Digital Page
        10. 8.5.25.10 Register 036h (address = 036h), JESD Digital Page
        11. 8.5.25.11 Register 037h (address = 037h), JESD Digital Page
        12. 8.5.25.12 Register 03Ch (address = 03Ch), JESD Digital Page
        13. 8.5.25.13 Register 03Eh (address = 03Eh), JESD Digital Page
      26. 8.5.26 Decimation Filter Page
        1. 8.5.26.1  Register 000h (address = 000h), Decimation Filter Page
        2. 8.5.26.2  Register 001h (address = 001h), Decimation Filter Page
        3. 8.5.26.3  Register 002h (address = 2h), Decimation Filter Page
        4. 8.5.26.4  Register 005h (address = 005h), Decimation Filter Page
        5. 8.5.26.5  Register 006h (address = 006h), Decimation Filter Page
        6. 8.5.26.6  Register 007h (address = 007h), Decimation Filter Page
        7. 8.5.26.7  Register 008h (address = 008h), Decimation Filter Page
        8. 8.5.26.8  Register 009h (address = 009h), Decimation Filter Page
        9. 8.5.26.9  Register 00Ah (address = 00Ah), Decimation Filter Page
        10. 8.5.26.10 Register 00Bh (address = 00Bh), Decimation Filter Page
        11. 8.5.26.11 Register 00Ch (address = 00Ch), Decimation Filter Page
        12. 8.5.26.12 Register 00Dh (address = 00Dh), Decimation Filter Page
        13. 8.5.26.13 Register 00Eh (address = 00Eh), Decimation Filter Page
        14. 8.5.26.14 Register 00Fh (address = 00Fh), Decimation Filter Page
        15. 8.5.26.15 Register 010h (address = 010h), Decimation Filter Page
        16. 8.5.26.16 Register 011h (address = 011h), Decimation Filter Page
        17. 8.5.26.17 Register 014h (address = 014h), Decimation Filter Page
        18. 8.5.26.18 Register 016h (address = 016h), Decimation Filter Page
        19. 8.5.26.19 Register 01Eh (address = 01Eh), Decimation Filter Page
        20. 8.5.26.20 Register 01Fh (address = 01Fh), Decimation Filter Page
        21. 8.5.26.21 Register 033h-036h (address = 033h-036h), Decimation Filter Page
        22. 8.5.26.22 Register 037h (address = 037h), Decimation Filter Page
        23. 8.5.26.23 Register 038h (address = 038h), Decimation Filter Page
        24. 8.5.26.24 Register 039h (address = 039h), Decimation Filter Page
        25. 8.5.26.25 Register 03Ah (address = 03Ah), Decimation Filter Page
      27. 8.5.27 Power Detector Page
        1. 8.5.27.1  Register 000h (address = 000h), Power Detector Page
        2. 8.5.27.2  Register 001h-002h (address = 001h-002h), Power Detector Page
        3. 8.5.27.3  Register 003h (address = 003h), Power Detector Page
        4. 8.5.27.4  Register 007h-00Ah (address = 007h-00Ah), Power Detector Page
        5. 8.5.27.5  Register 00Bh-00Ch (address = 00Bh-00Ch), Power Detector Page
        6. 8.5.27.6  Register 00Dh (address = 00Dh), Power Detector Page
        7. 8.5.27.7  Register 00Eh (address = 00Eh), Power Detector Page
        8. 8.5.27.8  Register 00Fh, 010h-012h, and 016h-019h (address = 00Fh, 010h-012h, and 016h-019h), Power Detector Page
        9. 8.5.27.9  Register 013h-01Ah (address = 013h-01Ah), Power Detector Page
        10. 8.5.27.10 Register 01Dh-01Eh (address = 01Dh-01Eh), Power Detector Page
        11. 8.5.27.11 Register 020h (address = 020h), Power Detector Page
        12. 8.5.27.12 Register 021h (address = 021h), Power Detector Page
        13. 8.5.27.13 Register 022h-025h (address = 022h-025h), Power Detector Page
        14. 8.5.27.14 Register 027h (address = 027h), Power Detector Page
        15. 8.5.27.15 Register 02Bh (address = 02Bh), Power Detector Page
        16. 8.5.27.16 Register 032h-035h (address = 032h-035h), Power Detector Page
        17. 8.5.27.17 Register 037h (address = 037h), Power Detector Page
        18. 8.5.27.18 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 ADC32RF82
        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

9 Application and Implementation

NOTE

Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.

9.1 Application Information

9.1.1 Start-Up Sequence

The steps in Table 143 are recommended as the power-up sequence when the ADC32RF82 is in the decimation-by-4 complex output mode.

Table 143. Initialization Sequence

STEP DESCRIPTION PAGE, REGISTER ADDRESS AND DATA COMMENT
1 Supply all supply voltages. Refer the power supply sequencing mentioned in the Power Supply Recommendations section.
2 Provide the SYSREF signal.
3 Pulse a hardware reset (low-to-high-to-low) on pins 33 and 34.
4 Write the register addresses described in the PowerUpConfig file. See the files located in SBAA226 The Power-up config file contains analog trim registers that are required for best performance of the ADC. Write these registers every time after power up.
5 Write the register addresses mentioned in the ILConfigNyqX_ChA file, where X is the Nyquist zone. See the files located in SBAA226 Based on the signal band of interest, provide the Nyquist zone information to the device.
6 Write the register addresses mentioned in the ILConfigNyqX_ChB file, where X is the Nyquist zone. See the files located in SBAA226 This step optimizes device’ performance by reducing interleaving mismatch errors.
6.1 Wait for 50 ms for the device to estimate the interleaving errors.
7 Depending upon the Nyquist band of operation, choose and write the registers from the appropriate file, NLConfigNyqX_ChA, where X is the Nyquist zone. See the files located in SBAA226 Third-order nonlinearity of the device is optimized by this step for channel A.
7.1 Depending upon the Nyquist band of operation, choose and write the registers from the appropriate file, NLConfigNyqX_ChB, where X is the Nyquist zone. See the files located in SBAA226 Third-order nonlinearity of the device is optimized by this step for channel B.
8 Configure the JESD interface and DDC block by writing the registers mentioned in the DDC Config file. See the files located in SBAA226 Determine the DDC and JESD interface LMFS options. Program these options in this step.

9.1.2 Hardware Reset

Figure 264 and Table 144 show the timing information for the hardware reset.

ADC32RF82 hardware_reset_sbas747.gif Figure 264. Hardware Reset Timing Diagram

Table 144. Hardware Reset Timing Information

MIN TYP MAX UNIT
t1 Power-on delay from power-up to active high RESET pulse 1 ms
t2 Reset pulse duration: active high RESET pulse duration 1 µs
t3 Register write delay from RESET disable to SEN active 100 ns

9.1.3 SNR and Clock Jitter

The signal-to-noise ratio (SNR) of the ADC is limited by three different factors, as shown in Equation 5: quantization noise, thermal noise, and jitter. The quantization noise is typically not noticeable in pipeline converters and is 84 dB for a 14-bit ADC. The thermal noise limits the SNR at low input frequencies and the clock jitter sets the SNR for higher input frequencies.

Equation 5. ADC32RF82 snr_adc_eq_sbas747.gif

Equation 6 calculates the SNR limitation resulting from sample clock jitter:

Equation 6. ADC32RF82 snr_jitter_eq_sbas747.gif

The total clock jitter (TJitter) has two components: the internal aperture jitter (90 fS) is set by the noise of the clock input buffer and the external clock jitter. Equation 7 calculates TJitter:

Equation 7. ADC32RF82 total_clck_jitter_sbas747.gif

External clock jitter can be minimized by using high-quality clock sources and jitter cleaners as well as band-pass filters at the clock input. A faster clock slew rate also improves the ADC aperture jitter.

The ADC32RF82 has a thermal noise of approximately 63 dBFS and an internal aperture jitter of 90 fS. The SNR, is shown in Figure 265, depending on the amount of external jitter for different input frequencies.

ADC32RF82 D048_ADC32RF45.gif Figure 265. ADC SNR vs Input Frequency and External Clock Jitter

9.1.3.1 External Clock Phase Noise Consideration

External clock jitter can be calculated as shown in Figure 266 by integrating the phase noise of the clock source out to approximately two times of the ADC sampling rate (2 × fS). In order to maximize the ADC SNR, an external band-pass filter is recommended to be used on the clock input. This filter reduces the jitter contribution from the broadband clock phase noise floor by effectively reducing the integration bandwidth to the pass band of the band-pass filter. This method is suitable when estimating the overall ADC SNR resulting from clock jitter at a certain input frequency.

ADC32RF82 adc_snr_sbas747.gif Figure 266. Integration Bandwidth for Extracting Jitter from Clock Phase Noise

However, when estimating the affect of a nearby blocker (such as a strong in-band interferer to the sensitivity, the phase noise information shown in Figure 267 can be used directly to estimate the noise budget contribution at a certain offset frequency.

ADC32RF82 phase_noise_info_sbas747.gif Figure 267. Small Wanted Signal in Presence of Interferer

At the sampling instant, the phase noise profile of the clock source convolves with the input signal (for example, the small wanted signal and the strong interferer merge together). If the power of the clock phase noise in the signal band of interest is too large, the wanted signal cannot not be recovered.

The resulting equivalent phase noise at the ADC input is also dependent on the sampling rate of the ADC and frequency of the input signal. Equation 8 shows the ADC sampling rate scales the clock phase noise.

Equation 8. ADC32RF82 adc_nsd_eq_sbas747.gif

Using this information, the noise contribution resulting from the phase noise profile of the ADC sampling clock can be calculated.

9.1.4 Power Consumption in Different Modes

The ADC32RF82 consumes approximately 6 W of power when both channels are active with a divide-by-4 complex output. When different DDC options are used, the power consumption on the DVDD supply changes by a small amount but remains unaffected on other supplies. In the applications requiring just one channel to be active, channel A must be chosen as the active channel and channel B can be powered down. Power consumption reduces to approximately 4 W in single-channel operation with a divide-by-3.4 option at a 2457.6-MSPS device clock rate.

Table 145, Table 146, and Table 147 show power consumption in different DDC modes for dual-channel and single-channel operation.

Table 145. Power Consumption in Different DDC Modes (Sampling Clock Frequency, fS = 2457.6 MSPS)

DECIMATION OPTION ACTIVE
CHANNEL		 ACTIVE DDC AVDD1P9 (mA) AVDD1P2 (mA) DVDD1P2 (mA) TOTAL POWER (mW)
Divide-by-4 Channels A, B Single 1729 850 1500 5988
Divide-by-8 Channels A, B Dual 1729 853 1640 6152
Divide-by-8 Channels A, B Single 1729 851 1445 5926
Divide-by-16 Channels A, B Dual 1729 858 1645 6164
Divide-by-16 Channels A, B Single 1729 856 1440 5926
Divide-by-24 Channels A, B Dual 1724 856 1624 6128
Divide-by-24 Channels A, B Single 1725 854 1380 5847
Divide-by-32 Channels A, B Dual 1723 855 1528 6014
Divide-by-32 Channels A, B Single 1723 853 1315 5767
Divide-by-4 Channel A Single 935 501 910 3399
Divide-by-8 Channel A Dual 935 499 996 3496
Divide-by-8 Channel A Single 935 490 890 3364
Divide-by-16 Channel A Dual 935 499 1005 3506
Divide-by-16 Channel A Single 935 490 887 3360
Divide-by-24 Channel A Dual 933 499 988 3483
Divide-by-24 Channel A Single 933 490 867 3333
Divide-by-32 Channel A Dual 932 499 945 3431
Divide-by-32 Channel A Single 932 490 833 3292

Table 146. Power Consumption in Different DDC Modes (Sampling Clock Frequency, fS = 1966.08 MSPS)

DECIMATION OPTION ACTIVE
CHANNEL		 ACTIVE DDC AVDD1P9 (mA) AVDD1P2 (mA) DVDD1P2 (mA) TOTAL POWER (mW)
Divide-by-4 Channels A, B Single 1644 827 1332 5606
Divide-by-8 Channels A, B Dual 1643 833 1449 5746
Divide-by-8 Channels A, B Single 1643 825 1252 5510
Divide-by-16 Channels A, B Dual 1643 836 1462 5764
Divide-by-16 Channels A, B Single 1643 832 1286 5557
Divide-by-24 Channels A, B Dual 1639 835 1427 5715
Divide-by-24 Channels A, B Single 1639 830 1237 5491
Divide-by-32 Channels A, B Dual 1638 826 1331 5593
Divide-by-32 Channels A, B Single 1638 824 1174 5410
Divide-by-4 Channel A Single 904 469 828 3209
Divide-by-8 Channel A Dual 905 470 891 3285
Divide-by-8 Channel A Single 905 461 805 3175
Divide-by-16 Channel A Dual 904 470 904 3298
Divide-by-16 Channel A Single 904 461 808 3177
Divide-by-24 Channel A Dual 903 470 875 3262
Divide-by-24 Channel A Single 903 470 768 3129
Divide-by-32 Channel A Dual 902 470 838 3218
Divide-by-32 Channel A Single 902 461 750 3106

Table 147. Power Consumption in Different DDC Modes (Sampling Clock Frequency, fS = 2211.84 MSPS)

DECIMATION OPTION ACTIVE
CHANNEL		 ACTIVE DDC AVDD1P9 (mA) AVDD1P2 (mA) DVDD1P2 (mA) TOTAL POWER (mW)
Divide-by-4 Channels A, B Single 1666 884 1450 5850
Divide-by-8 Channels A, B Dual 1666 884 1550 5965
Divide-by-8 Channels A, B Single 1666 881 1380 5766
Divide-by-16 Channels A, B Dual 1664 882 1528 5933
Divide-by-16 Channels A, B Single 1664 879 1346 5720
Divide-by-24 Channels A, B Dual 1665 875 1508 5904
Divide-by-24 Channels A, B Single 1665 865 1298 5651
Divide-by-32 Channels A, B Dual 1664 873 1413 5791
Divide-by-32 Channels A, B Single 1664 864 1247 5589
Divide-by-4 Channel A Single 919 470 987 3422
Divide-by-8 Channel A Dual 918 469 945 3370
Divide-by-8 Channel A Single 918 461 859 3262
Divide-by-16 Channel A Dual 918 469 957 3384
Divide-by-16 Channel A Single 918 461 855 3258
Divide-by-24 Channel A Dual 917 469 950 3374
Divide-by-24 Channel A Single 904 461 846 3221
Divide-by-32 Channel A Dual 916 469 899 3314
Divide-by-32 Channel A Single 903 461 801 3167

9.1.5 Using DC Coupling in the ADC32RF82

The ADC32RF82 can be used in dc-coupling applications. However, the following points must be considered when designing the system:

  1. Ensure that the correct common-mode voltage is used at the ADC analog inputs.

    2. The analog inputs are internally self-biased to VCM through approximately a 33-Ω resistor. The internal biasing resistors also function as a termination resistor. However, if a different termination is required, the external resistor RTERM can be differentially placed between the analog inputs, as shown in Figure 268. The amplifier VOCM pin is recommended to be driven from the CM pin of the ADC to help the amplifier output common-mode voltage track the required common-mode voltage of the ADC.

    ADC32RF82 dc_coupling_app_sbas869.gif
    1. Set the INCR CM IMPEDANCE bit to increase the RCM from 0 Ω to > 5000 Ω.
    2. RDC is approximately 65 Ω.
    Figure 268. The ADC32RF82 in a DC-Coupling Application
  2. Ensure that the correct SPI settings are written to the ADC.

    3. As shown in Figure 269, the ADC32RF82 has a digital block that estimates and corrects the offset mismatch among four interleaving ADC cores for a given channel.

    ADC32RF82 offset_corr_lck_sbas747.gif Figure 269. Offset Corrector in the ADC32RF82

    The offset corrector block nullifies dc, fS / 8, fS / 4, 3 fS / 8, and fS / 2. The resulting spectrum becomes free from static spurs at these frequencies. The corrector continuously processes the data coming from the interleaving ADC cores and cannot distinguish if the tone at these frequencies is part of signal or if the tone originated from a mismatch among the interleaving ADC cores. Thus, in applications where the signal is present at these frequencies, the offset corrector block can be bypassed.

9.1.5.1 Bypassing the Offset Corrector Block

When the offset corrector is bypassed, offset mismatch among interleaving ADC cores appears in the ADC output spectrum. To correct the effects of mismatch, place the ADC in an idle channel state (no signal at the ADC inputs) and the corrector must be allowed to run for some time to estimate the mismatch, then the corrector is frozen so that the last estimated value is held. Required register writes are provided in Table 148.

Table 148. Freezing and Bypassing the Offset Corrector Block

STEP REGISTER WRITE COMMENT
STEPS FOR FREEZING THE CORRECTOR BLOCK
1 Signal source is turned off. The device detects an idle channel at its input.
2 Wait for at least 0.4 ms for the corrector to estimate the internal offset
3 Address 4001h, value 00h Select Offset Corr Page Channel A
Address 4002h, value 00h
Address 4003h, value 00h
Address 4004h, value 61h
Address 6068h, value C2h Freeze the corrector for channel A
Address 4003h, value 01h Select Offset Corr Page Channel B
Address 6068h, value C2h Freeze the corrector for channel B
4 Signal source can now be turned on
STEPS FOR BYPASSING THE CORRECTOR BLOCK
1 Address 4001h, value 00h
Address 4002h, value 00h
Address 4003h, value 00h
Address 4004h, value 61h Select Offset Corr Page Channel A
Address 6068h, value 46h Disable the corrector for channel A
Address 4003h, value 01h Select Offset Corr Page Channel B
Address 6068h, value 46h Disable the corrector for channel B

9.1.5.1.1 Effect of Temperature

Figure 270 and Figure 271 show the behavior of nfS / 8 tones with respect to temperature when the offset corrector block is frozen or disabled.

ADC32RF82 D058_SBAS747.gif Figure 270. Offset Corrector Block Frozen at Room Temperature
ADC32RF82 D060_SBAS747.gif Figure 271. Offset Corrector Block Disabled

9.2 Typical Application

The ADC32RF82 is designed for wideband receiver applications demanding high dynamic range over a large input frequency range. A typical schematic for an ac-coupled receiver is shown in Figure 272.

Decoupling capacitors with low ESL are recommended to be placed as close as possible at the pins indicated in Figure 272. Additional capacitors can be placed on the remaining power pins.

ADC32RF82 ac_cpld_rcvr_sbas869.gif Figure 272. Typical Application Implementation Diagram

9.2.1 Design Requirements

9.2.1.1 Transformer-Coupled Circuits

Typical applications involving transformer-coupled circuits are discussed in this section. To ensure good amplitude and phase balance at the analog inputs, transformers (such as TC1-1-13 and TC1-1-43) can be used from the dc to 1000-MHz range and from the 1000-MHz to 4-GHz range of input frequencies, respectively. When designing the driving circuits, the ADC input impedance (or SDD11) must be considered.

By using the simple drive circuit of Figure 273, uniform performance can be obtained over a wide frequency range. The buffers present at the analog inputs of the device help isolate the external drive source from the switching currents of the sampling circuit.

ADC32RF82 ai_input_drive_cir_sbas747.gif Figure 273. Input Drive Circuit

9.2.2 Detailed Design Procedure

For optimum performance, the analog inputs must be driven differentially. This architecture improves common-mode noise immunity and even-order harmonic rejection. A small resistor (5 Ω to 10 Ω) in series with each input pin is recommended to damp out ringing caused by package parasitics, as shown in Figure 273.

9.2.3 Application Curves

Figure 274 and Figure 275 show the typical performance at 100 MHz and 1850 MHz, respectively.

ADC32RF82 D001_SBAS869.gif
SNR = 62,4 dBFS; SFDR = 71 dBc;
HD2 = –71 dBc; HD3 = –83 dBc; non HD2, HD3 = 82 dBc;
IL spur = 80 dBc; fIN = 100 MHz
Figure 274. FFT for 100-MHz Input Frequency
ADC32RF82 D007_SBAS869.gif
SNR = 58 dBFS; SFDR = 69 dBc;
HD2 = –69 dBc; HD3 = –75 dBc; non HD2, HD3 = 74 dBc;
IL spur = 78 dBc; fIN = 1850 MHz
Figure 275. FFT for 1850-MHz Input Frequency