SBASAK2 Data sheet

SBASAK2C March 2022 – May 2025 AFE7903

PRODUCTION DATA

4.12.11 TX Typical Characteristics at 2.6 GHz

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

AFE7903 TX Full Scale vs RF
Frequency at 5898.24 MSPS

Including PCB and cable losses, A_out = -0.5 dBFS, DSA = 0, 2.6 GHz matching

Figure 4-374 TX Full Scale vs RF Frequency at 5898.24 MSPS

AFE7903 TX Full Scale vs RF
Frequency at 11796.48 MSPS

Including PCB and cable losses, A_out = -0.5 dBFS, DSA = 0, 2.6 GHz matching

Figure 4-376 TX Full Scale vs RF Frequency at 11796.48 MSPS

AFE7903 TX
Output Power vs DSA Setting and Channel at 2.6 GHz

f_DAC = 8847.36 MSPS, A_out = -0.5 dBFS, matching 2.6 GHz

Figure 4-378 TX Output Power vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX
Calibrated Differential Gain Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Differential Gain Error = P_OUT(DSA Setting – 1) – P_OUT(DSA Setting) + 1

Figure 4-380 TX Calibrated Differential Gain Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX
Calibrated Integrated Gain Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Integrated Gain Error = P_OUT(DSA Setting) – P_OUT(DSA Setting = 0) + (DSA Setting)

Figure 4-382 TX Calibrated Integrated Gain Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX Calibrated Differential Gain Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Differential Gain Error = P_OUT(DSA Setting – 1) – P_OUT(DSA Setting) + 1

Figure 4-384 TX Calibrated Differential Gain Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX Calibrated Integrated Gain Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Integrated Gain Error = P_OUT(DSA Setting) – P_OUT(DSA Setting = 0) + (DSA Setting)

Figure 4-386 TX Calibrated Integrated Gain Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX
Calibrated Differential Phase Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Differential Phase Error = Phase_OUT(DSA Setting – 1) – Phase_OUT(DSA Setting)
Phase DNL spike may occur at any DSA setting.

Figure 4-388 TX Calibrated Differential Phase Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX
Calibrated Integrated Phase Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 4-390 TX Calibrated Integrated Phase Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX Calibrated Differential Phase Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Differential Phase Error = Phase_OUT(DSA Setting – 1) – Phase_OUT(DSA Setting)

Figure 4-392 TX Calibrated Differential Phase Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX Calibrated Integrated Phase Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 4-394 TX Calibrated Integrated Phase Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX
IMD3 vs DSA Setting at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, f_CENTER = 2.6 GHz, matching at 2.6 GHz, –13 dBFS each tone

Figure 4-396 TX IMD3 vs DSA Setting at 2.6 GHz

AFE7903 TX IMD3 vs Tone Spacing and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, f_CENTER = 2.6 GHz, matching at 2.6 GHz, –13 dBFS each tone, worst channel, dither = 1.

Figure 4-398 TX IMD3 vs Tone Spacing and Temperature at 2.6 GHz

AFE7903 TX IMD3 vs Tone Spacing and Temperature

f_DAC = 8847.36 MSPS, straight mode, f_CENTER = 2.6 GHz, matching at 2.6 GHz, –13 dBFS each tone

Figure 4-400 TX IMD3 vs Tone Spacing and Temperature

AFE7903 TX
20-MHz LTE Output Spectrum at 2.6 GHz (Band 41)

TM1.1, P_{OUT_RMS} = –13 dBFS

Figure 4-402 TX 20-MHz LTE Output Spectrum at 2.6 GHz (Band 41)

AFE7903 TX
20-MHz LTE alt-ACPR vs Digital Level at 2.6 GHz

Matching at 2.6 GHz, single carrier 20-MHz BW TM1.1 LTE

Figure 4-404 TX 20-MHz LTE alt-ACPR vs Digital Level at 2.6 GHz

AFE7903 TX
100-MHz NR ACPR vs Digital Level at 2.6 GHz

Matching at 2.6 GHz, single carrier 100-MHz BW TM1.1 NR

Figure 4-406 TX 100-MHz NR ACPR vs Digital Level at 2.6 GHz

AFE7903 TX
20-MHz LTE ACPR vs DSA at 2.6 GHz

Matching at 2.6 GHz, single carrier 20-MHz BW TM1.1 LTE

Figure 4-408 TX 20-MHz LTE ACPR vs DSA at 2.6 GHz

AFE7903 TX
100-MHz NR ACPR vs DSA at 2.6 GHz

Matching at 2.6 GHz, single carrier 100-MHz BW TM1.1 NR

Figure 4-410 TX 100-MHz NR ACPR vs DSA at 2.6 GHz

AFE7903 TX
HD2 vs Digital Amplitude and Output Frequency at 2.6 GHz

Matching at 2.6 GHz, f_DAC = 11.79648GSPS, interleave mode, normalized to output power at harmonic frequency

Figure 4-412 TX HD2 vs Digital Amplitude and Output Frequency at 2.6 GHz

AFE7903 Two
Tone Inband SFDR vs Digital Amplitude at 2.6 GHz

Inband = 2600 MHz ± 600 MHz, f_DAC = 12 GSPS, not including F_S/3 and F_S/4, external clock mode, non-interleave mode

Figure 4-414 Two Tone Inband SFDR vs Digital Amplitude at 2.6 GHz

AFE7903 TX Single Tone (–12 dBFS) Output Spectrum at 2.6 GHz (0-fDAC)

f_DAC = 8847.36 MSPS, interleave mode, 2.6 GHz matching, includes PCB and cable losses. ILn = f_S/n ± f_OUT.

Figure 4-416 TX Single Tone (–12 dBFS) Output Spectrum at 2.6 GHz (0-f_DAC)

AFE7903 TX Single Tone (–6 dBFS) Output Spectrum at 2.6 GHz (0-fDAC)

f_DAC = 8847.36 MSPS, interleave mode, 2.6 GHz matching, includes PCB and cable losses. ILn = f_S/n ± f_OUT.

Figure 4-418 TX Single Tone (–6 dBFS) Output Spectrum at 2.6 GHz (0-f_DAC)

AFE7903 TX Single Tone (–1 dBFS) Output Spectrum at 2.6 GHz (0-fDAC)

f_DAC = 8847.36 MSPS, interleave mode, 2.6 GHz matching, includes PCB and cable losses. ILn = f_S/n ± f_OUT.

Figure 4-420 TX Single Tone (–1 dBFS) Output Spectrum at 2.6 GHz (0-f_DAC)

f_DAC = 8847.36 MSPS, straight mode, 2.6 GHz matching, includes PCB and cable losses. ILn = f_S/n ± f_OUT and is due to mixing with digital clocks.

Figure 4-422 TX Single Tone (–12 dBFS) Output Spectrum at 2.6 GHz (0-f_DAC)

f_DAC = 8847.36 MSPS, straight mode, 2.6 GHz matching, includes PCB and cable losses. ILn = f_S/n ± f_OUT and is due to mixing with digital clocks.

Figure 4-424 TX Single Tone (–6 dBFS) Output Spectrum at 2.6 GHz (0-f_DAC)

f_DAC = 8847.36 MSPS, straight mode, 2.6 GHz matching, includes PCB and cable losses. ILn = f_S/n ± f_OUT and is due to mixing with digital clocks.

Figure 4-426 TX Single Tone (–1 dBFS) Output Spectrum at 2.6 GHz (0-f_DAC)

AFE7903 TX
Dual Tone Output Spectrum at 2.6 GHz, -7 dBFS each (0 -
DAC)

f_DAC = 9000 MSPS, external clock mode, non-interleave mode

Figure 4-428 TX Dual Tone Output Spectrum at 2.6 GHz, -7 dBFS each (0 - _DAC)

AFE7903 TX
Dual Tone Output Spectrum at 2.6 GHz, -13 dBFS each (0 -
DAC)

f_DAC = 9000 MSPS, external clock mode, non-interleave mode

Figure 4-430 TX Dual Tone Output Spectrum at 2.6 GHz, -13 dBFS each (0 - _DAC)

AFE7903 TX
Dual Tone Output Spectrum at 2.6 GHz, -30 dBFS each (0 -
DAC)

f_DAC = 9000 MSPS, external clock mode, non-interleave mode

Figure 4-432 TX Dual Tone Output Spectrum at 2.6 GHz, -30 dBFS each (0 - _DAC)

AFE7903 TX Output Noise vs Supply Voltage at 2.6 GHz

f_DAC = 11796.48 MSPS, interleave mode, 2.6 GHz matching. 40-MHz offset from tone. Output Power = –1 dBFS. All supplies simultaneously at MIN, TYP, or MAX voltages.

Figure 4-434 TX Output Noise vs Supply Voltage at 2.6 GHz

AFE7903 IMD3
vs Tone Spacing and Channel at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode

Figure 4-436 IMD3 vs Tone Spacing and Channel at 2.6 GHz

AFE7903 IMD3
vs Digital Amplitude and Channel at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode

Figure 4-438 IMD3 vs Digital Amplitude and Channel at 2.6 GHz

AFE7903 IMD3
vs Digital Amplitude and Dither at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode

Figure 4-440 IMD3 vs Digital Amplitude and Dither at 2.6 GHz

AFE7903 NSD
vs Digital Amplitude and Temperature at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode, 50 MHz offset

Figure 4-442 NSD vs Digital Amplitude and Temperature at 2.6 GHz

AFE7903 TX Full Scale vs RF
Frequency at 8847.36 MSPS

Including PCB and cable losses, A_out = -0.5 dBFS, DSA = 0, 2.6 GHz matching

Figure 4-375 TX Full Scale vs RF Frequency at 8847.36 MSPS

AFE7903 TX
Output Fullscale vs Output Frequency and Channel

f_DAC = 8847.36 MSPS, interleave mode, including PCB and cable losses, A_out = -0.5 dBFS, DSA = 0, 2.6 GHz matching

Figure 4-377 TX Output Fullscale vs Output Frequency and Channel

AFE7903 TX
Uncalibrated Differential Gain Error vs DSA Setting and Channel at 2.6
GHz

f_DAC =8847.36 MSPS, straight mode, matching at 2.6 GHz
Differential Gain Error = P_OUT(DSA Setting – 1) – P_OUT(DSA Setting) + 1

Figure 4-379 TX Uncalibrated Differential Gain Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX
Uncalibrated Integrated Gain Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Integrated Gain Error = P_OUT(DSA Setting) – P_OUT(DSA Setting = 0) + (DSA Setting)

Figure 4-381 TX Uncalibrated Integrated Gain Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX Uncalibrated Differential Gain Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Differential Gain Error = P_OUT(DSA Setting – 1) – P_OUT(DSA Setting) + 1

Figure 4-383 TX Uncalibrated Differential Gain Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX Uncalibrated Integrated Gain Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Integrated Gain Error = P_OUT(DSA Setting) – P_OUT(DSA Setting = 0) + (DSA Setting)

Figure 4-385 TX Uncalibrated Integrated Gain Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX
Uncalibrated Differential Phase Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Differential Phase Error = Phase_OUT(DSA Setting – 1) – Phase_OUT(DSA Setting)

Figure 4-387 TX Uncalibrated Differential Phase Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX
Uncalibrated Integrated Phase Error vs DSA Setting and Channel at 2.6
GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz
Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 4-389 TX Uncalibrated Integrated Phase Error vs DSA Setting and Channel at 2.6 GHz

AFE7903 TX Uncalibrated Differential Phase Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the median variation over DSA setting at 25°C
Differential Phase Error = Phase_OUT(DSA Setting – 1) – Phase_OUT(DSA Setting)

Figure 4-391 TX Uncalibrated Differential Phase Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX Uncalibrated Integrated Phase Error vs DSA Setting and Temperature at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, channel with the medium variation over DSA setting at 25°C
Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 4-393 TX Uncalibrated Integrated Phase Error vs DSA Setting and Temperature at 2.6 GHz

AFE7903 TX
Output Noise vs Channel and Attenuation at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, matching at 2.6 GHz, P_OUT = –13 dBFS

Figure 4-395 TX Output Noise vs Channel and Attenuation at 2.6 GHz

AFE7903 TX
IMD3 vs Tone Spacing and Channel at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, f_CENTER = 2.6 GHz, matching at 2.6 GHz, –13 dBFS each tone

Figure 4-397 TX IMD3 vs Tone Spacing and Channel at 2.6 GHz

AFE7903 TX
IMD3 vs Digital Level at 2.6 GHz

f_DAC = 8847.36 MSPS, straight mode, f_CENTER = 2.6 GHz, f_SPACING = 20 MHz, dither = 1, matching at 2.6 GHz

Figure 4-399 TX IMD3 vs Digital Level at 2.6 GHz

AFE7903 TX Single Tone Output Noise vs Frequency and Amplitude at 2.6 GHz

Matching at 2.6 GHz, Single tone, f_DAC = 11.79648GSPS, interleave mode, 40-MHz offset

Figure 4-401 TX Single Tone Output Noise vs Frequency and Amplitude at 2.6 GHz

AFE7903 TX
20-MHz LTE ACPR vs Digital Level at 2.6 GHz

Matching at 2.6 GHz, single carrier 20-MHz BW TM1.1 LTE

Figure 4-403 TX 20-MHz LTE ACPR vs Digital Level at 2.6 GHz

AFE7903 TX
20-MHz LTE alt2-ACPR vs Digital Level at 2.6 GHz

Matching at 2.6 GHz, single carrier 20-MHz BW TM1.1 LTE

Figure 4-405 TX 20-MHz LTE alt2-ACPR vs Digital Level at 2.6 GHz

AFE7903 TX
100-MHz NR alt-ACPR vs Digital Level at 2.6 GHz

Matching at 2.6 GHz, single carrier 100-MHz BW TM1.1 NR

Figure 4-407 TX 100-MHz NR alt-ACPR vs Digital Level at 2.6 GHz

AFE7903 TX
20-MHz LTE alt-ACPR vs DSA at 2.6 GHz

Matching at 2.6 GHz, single carrier 20-MHz BW TM1.1 LTE

Figure 4-409 TX 20-MHz LTE alt-ACPR vs DSA at 2.6 GHz

AFE7903 TX
100-MHz NR alt-ACPR vs DSA at 2.6 GHz

Matching at 2.6 GHz, single carrier 100-MHz BW TM1.1 NR

Figure 4-411 TX 100-MHz NR alt-ACPR vs DSA at 2.6 GHz

AFE7903 TX
HD3 vs Digital Amplitude and Output Frequency at 2.6 GHz

Matching at 2.6 GHz, f_DAC = 11.79648GSPS, interleave mode, normalized to output power at harmonic frequency

Figure 4-413 TX HD3 vs Digital Amplitude and Output Frequency at 2.6 GHz

AFE7903 Two
Tone Inband Fixed Spurs vs Digital Amplitude at 2.6 GHz

Inband = 2600 MHz ± 600 MHz, f_DAC = 12 GSPS, external clock mode, non-interleave mode

Figure 4-415 Two Tone Inband Fixed Spurs vs Digital Amplitude at 2.6 GHz

AFE7903 TX Single Tone (–12 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

f_DAC = 8847.36 MSPS, interleave mode, 2.6 GHz matching, includes PCB and cable losses

Figure 4-417 TX Single Tone (–12 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

AFE7903 TX Single Tone (–6 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

f_DAC = 8847.36 MSPS, interleave mode, 2.6 GHz matching, includes PCB and cable losses

Figure 4-419 TX Single Tone (–6 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

AFE7903 TX Single Tone (–1 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

f_DAC = 8847.36 MSPS, interleave mode, 2.6 GHz matching, includes PCB and cable losses

Figure 4-421 TX Single Tone (–1 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

f_DAC = 8847.36 MSPS, straight mode, 2.6 GHz matching, includes PCB and cable losses

Figure 4-423 TX Single Tone (–12 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

f_DAC = 8847.36 MSPS, straight mode, 2.6 GHz matching, includes PCB and cable losses

Figure 4-425 TX Single Tone (–6 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

f_DAC = 8847.36 MSPS, straight mode, 2.6 GHz matching, includes PCB and cable losses

Figure 4-427 TX Single Tone (–1 dBFS) Output Spectrum at 2.6 GHz (±300 MHz)

AFE7903 TX
Dual Tone Output Spectrum at 2.6 GHz, -7 dBFS each (±600 MHz)

f_DAC = 9000 MSPS, external clock mode, non-interleave mode

Figure 4-429 TX Dual Tone Output Spectrum at 2.6 GHz, -7 dBFS each (±600 MHz)

AFE7903 TX
Dual Tone Output Spectrum at 2.6 GHz, -13 dBFS each (±600 MHz)

f_DAC = 9000 MSPS, external clock mode, non-interleave mode

Figure 4-431 TX Dual Tone Output Spectrum at 2.6 GHz, -13 dBFS each (±600 MHz)

AFE7903 TX Dual Tone Output Spectrum at 2.6 GHz, -30dBFS
each (±600 MHz)

f_DAC = 9000 MSPS, external clock mode, non-interleave mode

Figure 4-433 TX Dual Tone Output Spectrum at 2.6 GHz, -30dBFS each (±600 MHz)

AFE7903 TX IMD3 vs Supply Voltage at 2.6 GHz

f_DAC = 11796.48 MSPS, interleave mode, 2.6 GHz matching. 40-MHz offset from tone. Output Power = –13 dBFS. All supplies simultaneously at MIN, TYP, or MAX voltages.

Figure 4-435 TX IMD3 vs Supply Voltage at 2.6 GHz

AFE7903 IMD3
vs Tone Spacing and Amplitude at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode

Figure 4-437 IMD3 vs Tone Spacing and Amplitude at 2.6 GHz

AFE7903 IMD3
vs Digital Amplitude and Temperature at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode

Figure 4-439 IMD3 vs Digital Amplitude and Temperature at 2.6 GHz

AFE7903 NSD
vs Digital Amplitude and Channel at 2.6 GHz

f_DAC = 9000 MSPS, non-interleave mode, external clock mode, 50 MHz offset

Figure 4-441 NSD vs Digital Amplitude and Channel at 2.6 GHz

f_DAC = f_CLK = 9000 MSPS, non-interleave mode

Figure 4-443 External Clock Additive Phase Noise at 2.6 GHz