SBASAK2B march   2022  – june 2023 AFE7903

PRODUCTION DATA  

  1.   1
  2. 1Features
  3. 2Applications
  4. 3Description
  5. 4Description (continued)
  6. 5Revision History
  7. 6Specifications
    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  Transmitter Electrical Characteristics
    6. 6.6  RF ADC Electrical Characteristics
    7. 6.7  PLL/VCO/Clock Electrical Characteristics
    8. 6.8  Digital Electrical Characteristics
    9. 6.9  Power Supply Electrical Characteristics
    10. 6.10 Timing Requirements
    11. 6.11 Switching Characteristics
    12. 6.12 Typical Characteristics
      1. 6.12.1  RX Typical Characteristics 30 MHz and 400 MHz
      2. 6.12.2  RX Typical Characteristics at 800 MHz
      3. 6.12.3  RX Typical Characteristics 1.75 GHz to 1.9 GHz
      4. 6.12.4  RX Typical Characteristics 2.6 GHz
      5. 6.12.5  RX Typical Characteristics 3.5 GHz
      6. 6.12.6  RX Typical Characteristics 4.9 GHz
      7. 6.12.7  RX Typical Characteristics 6.8 GHz
      8. 6.12.8  TX Typical Characteristics at 30 MHz and 600 MHz
      9. 6.12.9  TX Typical Characteristics at 800 MHz
      10. 6.12.10 TX Typical Characteristics at 1.8 GHz
      11. 6.12.11 TX Typical Characteristics at 2.6 GHz
      12. 6.12.12 TX Typical Characteristics at 3.5 GHz
      13. 6.12.13 TX Typical Characteristics at 4.9 GHz
      14. 6.12.14 TX Typical Characteristics at 7.1 GHz
      15. 6.12.15 PLL and Clock Typical Characteristics
  8. 7Device and Documentation Support
    1. 7.1 Receiving Notification of Documentation Updates
    2. 7.2 Support Resources
    3. 7.3 Trademarks
    4. 7.4 Electrostatic Discharge Caution
    5. 7.5 Glossary
  9. 9Mechanical, Packaging, and Orderable Information

Package Options

Mechanical Data (Package|Pins)
Thermal pad, mechanical data (Package|Pins)
Orderable Information

TX Typical Characteristics at 800 MHz

Typical values at TA = +25°C with nominal supplies. Unless otherwise noted, TX input data rate = 491.52 MSPS, fDAC = 11796.48 MSPS, interleave mode, AOUT = –1 dBFS, 1st Nyquist zone output, Internal PLL, fREF = 491.52 MSPS, 24x Interpolation, DSA = 0 dB, Sin(x)/x enabled, DSA calibrated

GUID-20211122-SS0I-DNBP-Z4VH-WFNZTDMX2ZPV-low.svg
Including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHz matching
Figure 6-293 TX Full Scale vs RF Frequency and Channel at 5898.24 MSPS, Straight Mode
GUID-20211122-SS0I-S5BF-NN4Z-NZWZCLWNPQPB-low.svg
Including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHz matching
Figure 6-295 TX Full Scale vs RF Frequency and Channel at 5898.24 MSPS, Interleave Mode
GUID-20211122-SS0I-J3GJ-108W-TBXVFZZJB5FX-low.svg
Including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHz matching
Figure 6-297 TX Full Scale vs RF Frequency and Channel at 11796.48 MSPS, Interleave Mode
GUID-A19949CE-60F2-4281-BCA6-8BC6A538EBC4-low.gif
including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHz matching
Figure 6-299 TX Output Fullscale vs Temperature
GUID-20211122-SS0I-B1HZ-SPF3-Z3QTLKJ8SPLL-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Gain Error = POUT(DSA Setting – 1) – POUT(DSA Setting) + 1
Figure 6-301 TX Uncalibrated Differential Gain Error vs DSA Setting and Channel at 0.85 GHz
GUID-20211122-SS0I-5ZNM-66QT-XDSZ7P8S07PT-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Gain Error = POUT(DSA Setting ) – POUT(DSA Setting = 0) + DSA Settings
Figure 6-303 TX Uncalibrated Integrated Gain Error vs DSA Setting and Channel at 0.85 GHz
GUID-6C2AFDF1-7DE5-45B2-B161-E09753220C0B-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Gain Error = POUT(DSA Setting – 1) – POUT(DSA Setting) + 1
Figure 6-305 TX Uncalibrated Differential Gain Error vs DSA Setting and Temperature at 0.85 GHz
GUID-FE3A3916-4E4F-4DFE-84D0-2E4055480EBF-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Gain Error = POUT(DSA Setting ) – POUT(DSA Setting = 0) + DSA Setting
Figure 6-307 TX Uncalibrated Integrated Gain Error vs DSA Setting and Temperature at 0.85 GHz
GUID-20211122-SS0I-JQFS-N0FM-5JJTVMJ8ZPQB-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Phase Error = PhaseOUT(DSA Setting – 1) – PhaseOUT(DSA Setting)
Figure 6-309 TX Uncalibrated Differential Phase Error vs DSA Setting and Channel at 0.85 GHz
GUID-20211122-SS0I-FGTQ-DMH0-4FD7RD1H4JMV-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Phase Error = PhaseOUT(DSA Setting) – PhaseOUT(DSA Setting = 0)
Figure 6-311 TX Uncalibrated Integrated Phase Error vs DSA Setting and Channel at 0.85 GHz
GUID-EA0DD7D8-B305-4736-85E8-5808BC16D1F8-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Phase Error = PhaseOUT(DSA Setting – 1) – PhaseOUT(DSA Setting) + 1
Figure 6-313 TX Uncalibrated Differential Phase Error vs DSA Setting and Temperature at 0.85 GHz
GUID-4BDF704F-AA2E-4918-8BF2-47DC365331C1-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Phase Error = PhaseOUT(DSA Setting) – PhaseOUT(DSA Setting = 0)
Figure 6-315 TX Uncalibrated Integrated Phase Error vs DSA Setting and Temperature at 0.85 GHz
GUID-20211122-SS0I-KTVH-BZ47-SL6K8BZKXXNB-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz, POUT = –13 dBFS
Figure 6-317 TX Output Noise vs Channel and Attenuation at 0.85 GHz
GUID-20211122-SS0I-WP7W-ZQJP-16149FRDVBR3-low.svg
fDAC = 5898.24 MSPS, straight mode, fCENTER = 0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone
Figure 6-319 TX IMD3 vs Tone Spacing and Channel at 0.85 GHz
GUID-20211122-SS0I-RLSZ-6RB2-BWWZS0J6GPZ5-low.svg
fDAC = 11796.48 MSPS, interleave mode, fCENTER = 0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone
Figure 6-321 TX IMD3 vs Tone Spacing and Channel at 0.85 GHz
GUID-D928C372-04F7-4413-8908-B2315DE76EAF-low.gif
fDAC = 8847.36 MSPS, straight mode, fCENTER = 0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone, worst channel
Figure 6-323 TX IMD3 vs Tone Spacing and Temperature at 0.85 GHz
GUID-20211122-SS0I-5J9R-L8H0-6C7QD0SVVJND-low.svg
fDAC = 5898.24 MSPS, straight mode, fCENTER = 0.85 GHz, fSPACING = 20 MHz, matching at 0.8 GHz
Figure 6-325 TX IMD3 vs Digital Level at 0.85 GHz
GUID-20211122-SS0I-MK4Q-5H0D-MMCWKVPWWQKP-low.svg
fDAC = 11796.48 MSPS, interleave mode, fCENTER = 0.85 GHz, fSPACING = 20 MHz, matching at 0.8 GHz
Figure 6-327 TX IMD3 vs Digital Level at 0.85 GHz
GUID-DC02F8C6-A825-487E-BE1B-B59443DD23E0-low.gif
TM1.1, POUT_RMS = –13 dBFS
Figure 6-329 TX 20-MHz LTE Output Spectrum at 0.85 GHz
GUID-20211122-SS0I-JJVC-5BXF-FRMHQCBSWCLH-low.svg
Matching at 0.8 GHz, single carrier 20-MHz BW TM1.1 LTE
Figure 6-331 TX 20-MHz LTE alt-ACPR vs Digital Level at 0.85 GHz
GUID-20211122-SS0I-DZGM-RCGG-T7NG4NWRRBV6-low.svg
Matching at 0.8 GHz, single carrier 20-MHz BW TM1.1 LTE
Figure 6-333 TX 20-MHz LTE ACPR vs DSA at 0.85 GHz
GUID-20211122-SS0I-PJQT-B42Z-PK8CJGXBVTJT-low.svg
Matching at 0.8 GHz, single carrier 100-MHz BW TM1.1 NR
Figure 6-335 TX 100-MHz NR ACPR vs DSA at 0.85 GHz
GUID-20211122-SS0I-WR0S-H9PF-2WXBJZ4X6P2H-low.svg
Matching at 0.8 GHz, fDAC = 5898.24 GSPS, straight mode
Figure 6-337 TX HD2 vs Digital Amplitude and Output Frequency at 0.85 GHz
GUID-20211122-SS0I-VKGB-P1GK-LTBPTTSM4MS6-low.svg
Matching at 0.8 GHz, fDAC = 5898.24 MSPS, straight mode, normalized to output power at harmonic frequency
Figure 6-339 TX HD3 vs Digital Amplitude and Output Frequency at 0.85 GHz
GUID-700809DA-8343-41BC-9A8E-CD1E50BF9802-low.gif
fDAC = 5898.24 MSPS, interleave mode, 0.8 GHz matching, includes PCB and cable losses. ILn = fS/n ± fOUT.
Figure 6-341 TX Single Tone (–12 dBFS) Output Spectrum at 0.85 GHz (0-fDAC)
GUID-92A1C74B-35FE-4AB0-8F33-1FD096406D6D-low.gif
fDAC = 5898.24 MSPS, interleave mode, 0.8 GHz matching, includes PCB and cable losses. ILn = fS/n ± fOUT.
Figure 6-343 TX Single Tone (–6 dBFS) Output Spectrum at 0.85 GHz (0-fDAC)
GUID-D88EB4A4-6745-43F6-A1ED-5431A53A31BC-low.gif
fDAC = 5898.24MSPS, interleave mode, 0.8 GHz matching, includes PCB and cable losses. ILn = fS/n ± fOUT.
Figure 6-345 TX Single Tone (–1 dBFS) Output Spectrum at 0.85 GHz (0-fDAC)
GUID-1942DA41-4A95-44F2-8B68-9874331DF70E-low.gif
fDAC = 5898.24MSPS, straight mode, 0.8 GHz matching, includes PCB and cable losses. ILn = fS/n ± fOUT and is due to mixing with digital clocks.
Figure 6-347 TX Single Tone (–12 dBFS) Output Spectrum at 0.85 GHz (0-fDAC)
GUID-2D821757-4DD7-4255-A0D4-433B7283C2F7-low.gif
fDAC = 5898.24MSPS, straight mode, 0.8 GHz matching, includes PCB and cable losses. ILn = fS/n ± fOUT and is due to mixing with digital clocks.
Figure 6-349 TX Single Tone (–6 dBFS) Output Spectrum at 0.85 GHz (0-fDAC)
GUID-9385E35D-7FD2-4278-B9DC-03369D02549A-low.gif
fDAC = 5898.24 MSPS, straight mode, 0.8 GHz matching, includes PCB and cable losses. ILn = fS/n ± fOUT and is due to mixing with digital clocks.
Figure 6-351 TX Single Tone (–1 dBFS) Output Spectrum at 0.85 GHz (0-fDAC)
GUID-20211122-SS0I-4WQN-JKZ2-9FBZFTPJG0WL-low.svg
Including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHzmatching
Figure 6-294 TX Full Scale vs RF Frequency and Channel at 8847.36 MSPS, Straight Mode
GUID-20211122-SS0I-XMN6-PLGM-TTS6C7FG9S4F-low.svg
Including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHz matching
Figure 6-296 TX Full Scale vs RF Frequency and Channel at 8847.36 MSPS, Interleave Mode
GUID-2FBEE87F-D85A-4BD0-A248-223CCD66F880-low.gif
including PCB and cable losses, Aout = -0.5 dFBS, DSA = 0, 0.8 GHz matching
Figure 6-298 TX Output Fullscale vs Output Frequency
GUID-20211122-SS0I-XNRT-SZ11-H5FMSX4VM1NC-low.svg
fDAC = 11796.48 MSPS, interleave mode, Aout = -0.5 dFBS, matching 0.8 GHz
Figure 6-300 TX Output Power vs DSA Setting and Channel at 0.85 GHz
GUID-20211122-SS0I-1QS3-H71P-QCMX7Z7CJNLK-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Gain Error = POUT(DSA Setting – 1) – POUT(DSA Setting) + 1
Figure 6-302 TX Calibrated Differential Gain Error vs DSA Setting and Channel at 0.85 GHz
GUID-20211122-SS0I-1SF7-RS9N-XBGJCQQCGS4P-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Gain Error = POUT(DSA Setting ) – POUT(DSA Setting = 0) + DSA Setting
Figure 6-304 TX Calibrated Integrated Gain Error vs DSA Setting and Channel at 0.85 GHz
GUID-FD3E5CF0-A88C-40D8-90D1-BA1D610AF492-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Gain Error = POUT(DSA Setting – 1) – POUT(DSA Setting) + 1
Figure 6-306 TX Calibrated Differential Gain Error vs DSA Setting and Temperature at 0.85 GHz
GUID-D74C66ED-18B3-4751-9F7C-B79C45836639-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Gain Error = POUT(DSA Setting ) – POUT(DSA Setting = 0) + DSA Setting
Figure 6-308 TX Calibrated Integrated Gain Error vs DSA Setting and Temperature at 0.85 GHz
GUID-20211122-SS0I-LLDP-BZZW-W1KSWLST7TLC-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Differential Phase Error = PhaseOUT(DSA Setting – 1) – PhaseOUT(DSA Setting)
Phase DNL spike may occur at any DSA setting.
Figure 6-310 TX Calibrated Differential Phase Error vs DSA Setting and Channel at 0.85 GHz
GUID-20211122-SS0I-NLTM-2D8Z-PVRJKQWQH35M-low.svg
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Phase Error = PhaseOUT(DSA Setting) – PhaseOUT(DSA Setting = 0)
Figure 6-312 TX Calibrated Integrated Phase Error vs DSA Setting and Channel at 0.85 GHz
GUID-BB89A362-A3EA-4D1F-88FC-64DF09B8269C-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz, channel with the median variation over DSA setting at 25°C
Differential Phase Error = PhaseOUT(DSA Setting – 1) – PhaseOUT(DSA Setting) + 1
Figure 6-314 TX Calibrated Differential Phase Error vs DSA Setting and Temperature at 0.85 GHz
GUID-FE215174-07C3-42DE-8827-1B4FC0AA623A-low.gif
fDAC = 5898.24 MSPS, interleave mode, matching at 0.8 GHz
Integrated Phase Error = PhaseOUT(DSA Setting) – PhaseOUT(DSA Setting = 0)
Figure 6-316 TX Calibrated Integrated Phase Error vs DSA Setting and Temperature at 0.85 GHz
GUID-20211122-SS0I-4QBM-ZWMZ-FBBKXC0QR6SK-low.svg
fDAC = 11796.48 MSPS, interleave mode, fCENTER = 0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone
Figure 6-318 TX IMD3 vs DSA Setting at 0.85 GHz
GUID-20211122-SS0I-SBH4-FCN7-C2SRF0CN75KD-low.svg
fDAC = 8847.36 MSPS, straight mode, fCENTER = 0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone
Figure 6-320 TX IMD3 vs Tone Spacing and Channel at 0.85 GHz
GUID-88BB5553-B5D9-41BE-BC81-0C6FDD6E49F9-low.gif
fDAC = 5898.24 MSPS, straight mode, fCENTER =0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone, worst channel
Figure 6-322 TX IMD3 vs Tone Spacing and Temperature at 0.85 GHz
GUID-0D323C57-C2D2-456C-8D37-D99FE3BF8E15-low.gif
fDAC = 11796.48 MSPS, straight mode, fCENTER = 0.85 GHz, matching at 0.8 GHz, –13 dBFS each tone, worst channel
Figure 6-324 TX IMD3 vs Tone Spacing and Temperature at 0.85 GHz
GUID-20211122-SS0I-GNGP-NBVS-X8QDSTN3Q3M3-low.svg
fDAC = 8847.36 MSPS, straight mode, fCENTER = 0.85 GHz, fSPACING = 20 MHz, matching at 0.8 GHz
Figure 6-326 TX IMD3 vs Digital Level at 0.85 GHz
GUID-5B664E32-4154-4E63-B206-15FAE6F0B788-low.gif
Matching at 0.8 GHz, Single tone, fDAC = 11.79648 GSPS, interleave mode, 40-MHz offset, DSA = 0dB
Figure 6-328 TX Single Tone Output Noise vs Frequency and Amplitude at 0.85 GHz
GUID-20211122-SS0I-KT8Z-RXHB-SZ9SWQC4CXP8-low.svg
Matching at 0.8 GHz, single carrier 20-MHz BW TM1.1 LTE
Figure 6-330 TX 20-MHz LTE ACPR vs Digital Level at 0.85 GHz
GUID-20211122-SS0I-DJRQ-SGLS-CMGZDHGPCBDH-low.svg
Matching at 0.8 GHz, single carrier 20-MHz BW TM1.1 LTE
Figure 6-332 TX 20-MHz LTE alt2-ACPR vs Digital Level at 0.85 GHz
GUID-20211122-SS0I-XPR7-KWMS-FGFHVMZJ6RRQ-low.svg
Matching at 0.8 GHz, single carrier 20-MHz BW TM1.1 LTE
Figure 6-334 TX 20-MHz LTE alt-ACPR vs DSA at 0.85 GHz
GUID-20211122-SS0I-JGHQ-ZQJT-LJPWSRSGLFNR-low.svg
Matching at 0.8 GHz, single carrier 100-MHz BW TM1.1 NR
Figure 6-336 TX 100-MHz NR alt-ACPR vs DSA at 0.85 GHz
GUID-20211122-SS0I-7HPT-V8FN-M8VZPBF8K7ZN-low.svg
Matching at 0.8 GHz, fDAC = 8847.36 GSPS, straight mode
Figure 6-338 TX HD2 vs Digital Amplitude and Output Frequency at 0.85 GHz
GUID-20211122-SS0I-HTRX-GWSC-XMQLNR67FDV6-low.svg
Matching at 0.8 GHz, fDAC = 8847.36 MSPS, straight mode, normalized to output power at harmonic frequency
Figure 6-340 TX HD3 vs Digital Amplitude and Output Frequency at 0.85 GHz
GUID-637E513A-E6DF-4DF7-BE24-7981CC8BA4FA-low.gif
fDAC = 5898.24 MSPS, interleave mode, 0.8 GHz matching, includes PCB and cable losses
Figure 6-342 TX Single Tone (–12 dBFS) Output Spectrum at 0.85 GHz (±300 MHz)
GUID-5CCE8A6C-54BF-4226-B891-05AFCF2AE101-low.gif
fDAC = 5898.24MSPS, interleave mode, 0.8 GHz matching, includes PCB and cable losses
Figure 6-344 TX Single Tone (–6 dBFS) Output Spectrum at 0.85 GHz (±300 MHz)
GUID-91C14DA1-083D-4125-B3A3-005D1B982276-low.gif
fDAC = 5898.24MSPS, interleave mode, 0.8 GHz matching, includes PCB and cable losses
Figure 6-346 TX Single Tone (–1 dBFS) Output Spectrum at 0.85 GHz (±300 MHz)
GUID-27EA1ADC-4F4B-4912-8CB2-1A3466D85566-low.gif
fDAC = 5898.24 MSPS, straight mode, 0.8 GHz matching, includes PCB and cable losses
Figure 6-348 TX Single Tone (–12 dBFS) Output Spectrum at 0.85 GHz (±300 MHz)
GUID-870BD815-D715-479D-A638-D438BD0874C2-low.gif
fDAC = 5898.24 MSPS, straight mode, 0.8 GHz matching, includes PCB and cable losses
Figure 6-350 TX Single Tone (–6 dBFS) Output Spectrum at 0.85 GHz (±300 MHz)
GUID-0AB9A5D5-C82D-4779-8D44-EC7E020A6D95-low.gif
fDAC = 5898.24MSPS, straight mode, 0.8 GHz matching, includes PCB and cable losses
Figure 6-352 TX Single Tone (–1 dBFS) Output Spectrum at 0.85 GHz (±300 MHz)