米6体育平台手机版

ZHCSOT2C january 2022 – may 2023 AFE7906

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ABJ|400
- MCBG079C
ALK|400
- MPBGAU3B

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6.11.1 RX Typical Characteristics 30 MHz and 400 MHz

Typical values at T_A = +25°C. Default conditions at 30MHz: ADC Sampling Rate = 1500 MSPS, output sample rate = 62.5 MSPS (decimate by 24x), PLL clock mode with f_REF = 500 MHz, A_IN = –3 dBFS, DSA setting = 3 dB. Default conditions at 400 MHz: ADC Sampling Rate = 1500 MSPS, output sample rate = 125 MSPS (decimate by 12x), PLL clock mode with f_REF = 500 MHz, A_IN = –3 dBFS, DSA setting = 3 dB.

Normalized to 30 MHz

Figure 6-1 RX In-Band Gain Flatness, f_IN = 30 MHz

Differential Amplitude Error = P_IN(DSA Setting – 1) – P_IN(DSA Setting) + 1

Figure 6-3 RX Calibrated Differential Amplitude Error vs DSA Setting at 30 MHz

Integrated Amplitude Error = P_IN(DSA Setting) – P_IN(DSA Setting = 0) + (DSA Setting)

Figure 6-5 RX Calibrated Integrated Amplitude Error vs DSA Setting at 30 MHz

Differential Phase Error = Phase_IN(DSA Setting – 1) – Phase_IN(DSA Setting)

Figure 6-7 RX Calibrated Differential Phase Error vs DSA Setting at 30 MHz

With 0.8 GHz matching
Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 6-9 RX Calibrated Integrated Phase Error vs DSA Setting at 30 MHz

A_IN = -6 dBFS, f_ADC = 1500 MSPS, f_NCO = 32. , Decimate by 24x

Figure 6-11 RX Output FFT at 5 MHz

A_IN = -30 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-13 RX Output FFT at 5 MHz

A_IN = -3 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-15 RX Output FFT at 30 MHz

A_IN = -12 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-17 RX Output FFT at 30 MHz

A_IN = -60 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-19 RX Output FFT at 30 MHz

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-21 NSD vs Input Amplitude at 30 MHz with DSA = 12

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-23 IMD3 vs Input Amplitude at 30 MHz

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-25 HD2 vs Input Amplitude at 30 MHz

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-27 HD3 vs Input Amplitude at 30 MHz

Normalized to 4000 MHz

Figure 6-29 RX In-Band Gain Flatness, f_IN = 400 MHz

Differential Amplitude Error = P_IN(DSA Setting – 1) – P_IN(DSA Setting) + 1

Figure 6-31 RX Calibrated Differential Amplitude Error vs DSA Setting at 400 MHz

Integrated Amplitude Error = P_IN(DSA Setting) – P_IN(DSA Setting = 0) + (DSA Setting)

Figure 6-33 RX Calibrated Integrated Amplitude Error vs DSA Setting at 400 MHz

Differential Phase Error = Phase_IN(DSA Setting – 1) – Phase_IN(DSA Setting)

Figure 6-35 RX Calibrated Differential Phase Error vs DSA Setting at 400 MHz

Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 6-37 RX Calibrated Integrated Phase Error vs DSA Setting at 400 MHz

f_NCO = 400MHz

Figure 6-39 RX Output FFT at 405 MHz and -6dBFS

f_NCO = 400MHz

Figure 6-41 RX Output FFT at 405 MHz and -30dBFS

f_OFFSET = 50MHz

Figure 6-43 NSD vs Input Amplitude at 400MHz

Figure 6-45 IMD3 vs Input Amplitude at 400MHz

Figure 6-47 IMD3 vs Tone Spacing at 400MHz

Figure 6-49 HD3 vs DSA Setting at 400MHz

Differential Amplitude Error = P_IN(DSA Setting – 1) – P_IN(DSA Setting) + 1

Figure 6-2 RX Uncalibrated Differential Amplitude Error vs DSA Setting at 30 MHz

Integrated Amplitude Error = P_IN(DSA Setting) – P_IN(DSA Setting = 0) + (DSA Setting)

Figure 6-4 RX Uncalibrated Integrated Amplitude Error vs DSA Setting at 30 MHz

Differential Phase Error = Phase_IN(DSA Setting – 1) – Phase_IN(DSA Setting)

Figure 6-6 RX Uncalibrated Differential Phase Error vs DSA Setting at 30 MHz

Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 6-8 RX Uncalibrated Integrated Phase Error vs DSA Setting at 30 MHz

A_IN = -3 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-10 RX Output FFT at 5 MHz

A_IN = -12 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-12 RX Output FFT at 5 MHz

A_IN = -60 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-14 RX Output FFT at 5 MHz

A_IN = -6 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-16 RX Output FFT at 30 MHz

A_IN = -30 dBFS, f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-18 RX Output FFT at 30 MHz

f_ADC = 1500MSPS, f_NCO = 32.13MHz, Decimate by 24x

Figure 6-20 NSD vs Input Amplitude at 30 MHz with DSA = 0 and 3dB

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-22 NSD vs DSA Attenuation at 30 MHz

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-24 IMD3 vs DSA Setting at 30 MHz

f_ADC = 1500 MSPS, f_NCO = 32. , Decimate by 24x

Figure 6-26 HD2 vs DSA Setting at 30 MHz

f_ADC = 1500 MSPS, f_NCO = 32.13 MHz, Decimate by 24x

Figure 6-28 HD3 vs DSA Setting at 30 MHz

Differential Amplitude Error = P_IN(DSA Setting – 1) – P_IN(DSA Setting) + 1

Figure 6-30 RX Uncalibrated Differential Amplitude Error vs DSA Setting at 30 MHz

Integrated Amplitude Error = P_IN(DSA Setting) – P_IN(DSA Setting = 0) + (DSA Setting)

Figure 6-32 RX Uncalibrated Integrated Amplitude Error vs DSA Setting at 400 MHz

Differential Phase Error = Phase_IN(DSA Setting – 1) – Phase_IN(DSA Setting)

Figure 6-34 RX Uncalibrated Differential Phase Error vs DSA Setting at 400 MHz

Integrated Phase Error = Phase(DSA Setting) – Phase(DSA Setting = 0)

Figure 6-36 RX Uncalibrated Integrated Phase Error vs DSA Setting at 400 MHz

f_NCO = 400MHz

Figure 6-38 RX Output FFT at 405 MHz and -3dBFS

f_NCO = 400MHz

Figure 6-40 RX Output FFT at 405 MHz and -12dBFS

f_NCO = 400MHz

Figure 6-42 RX Output FFT at 405 MHz and -60dBFS

f_OFFSET = 50MHz

Figure 6-44 NSD vs DSA Setting at 400MHz

Figure 6-46 IMD3 vs DSA Setting at 400MHz

Figure 6-48 HD3 vs Input Amplitude at 400MHz