RF-ADC Electrical Characteristics

Table 1. RF-ADC Electrical Characteristics for ZU2xDR Devices
Parameter	Comments/Conditions¹	Min	Typ²	Max	Units
Analog Inputs
Resolution		12	–	–	Bits
Sample Rate	Devices using quad ADC tile channel	0.5	–	2.058	GS/s
Sample Rate	Devices using dual ADC tile channel	1	–	4.096	GS/s
Full-scale Input	Input 100Ω on-die termination³	–	1	–	V_PPD
Full-scale Input	Input 100Ω on-die termination³	–	1	–	dBm
Analog Input Bandwidth	Full-power bandwidth (–3 dB)³	–	4	–	GHz
Common mode voltage⁴	AC coupling mode with internal bias	–	1.25	–	V
Crosstalk isolation between channels⁵	F_IN = 240 MHz	–	–70	–	dBc
	F_IN = 1.9 GHz	–	–70	–	dBc
	F_IN = 2.4 GHz	–	–70	–	dBc
	F_IN = 3.5 GHz	–	–70	–	dBc
Analog inputs at –1 dBFS, unless otherwise noted in the test conditions. Typical values are specified at nominal voltage, T_j = 25°C. Consult S parameter I/O files for further details on input characteristics. When using DC coupling mode, use the VCM output pin to bias the input to the RF-ADC. Values represent two channel crosstalk worst-case values for any combination of channel selections.

Table 2. RF-ADC Electrical Characteristics for ZU39DR Devices
Parameter	Comments/Conditions¹	Min	Typ²	Max	Units
Analog Inputs
Resolution		12	–	–	Bits
Sample Rate	Devices using quad ADC tile channel	0.5	–	2.220	GS/s
Full-scale Input	Input 100Ω on-die termination	–	1	–	V_PPD
Full-scale Input	Input 100Ω on-die termination	–	1	–	dBm
Analog Input Bandwidth	Full-power bandwidth (–3 dB)	–	5	–	GHz
Return Loss (R_L)³	Up to 4 GHz	–	–10	–	dB
Return Loss (R_L)³	Up to 5 GHz	–	–8	–	dB
Common mode voltage⁴	AC coupling mode with internal bias	–	1.25	–	V
Crosstalk isolation between channels⁵	F_IN = 240 MHz	–	–70	–	dBc
	F_IN = 1.9 GHz	–	–70	–	dBc
	F_IN = 2.4 GHz	–	–70	–	dBc
	F_IN = 3.5 GHz	–	–70	–	dBc
	F_IN = 4.2 GHz	–	–69	–	dBc
	F_IN = 4.9 GHz	–	–67	–	dBc
Analog inputs at –1 dBFS, unless otherwise noted in the test conditions. Typical values are specified at nominal voltage, T_j = 25°C. This is the return loss of the worst case channel quoted from DC to a specified frequency point. Consult the S parameter I/O files for further details as input characteristics depend on differential I/O selection. The RL reference plan is closed to the BGA footprint, keeping two times the BGA pitch distance from ball contact to avoid micro-probing electromagnetic disturbance. When using DC coupling mode, use the VCM output pin to bias the input to the RF-ADC. Values represent two channel crosstalk worst-case values for any combination of channel selections.

Table 3. RF-ADC Electrical Characteristics for ZU4xDR Devices
Parameter	Comments/Conditions¹	Min	Typ²	Max	Units
Analog inputs
Resolution		14	–	–	Bits
Sample Rate	Devices using quad ADC tile channel	0.5	–	2.5	GS/s
Sample Rate	Devices using dual ADC tile channel	1	–	5	GS/s
Full-scale input³	Input 100Ω on-die termination when DSA attenuation = 0 dB	–	1	–	V_PPD
Full-scale input³	Input 100Ω on-die termination when DSA attenuation = 0 dB	–	1	–	dBm
Maximum allowed input power	Input 100Ω on-die termination when DSA attenuation ≥ 15 dB	–	4.8	–	V_PPD
Maximum allowed input power	Input 100Ω on-die termination when DSA attenuation ≥ 15 dB	–	14.6	–	dBm
Digital Attenuation Range		0	–	27	dB
Attenuator step size		–	1	–	dB
Auto attenuation	Automatically set when amplitude over-voltage is asserted	–	15	–	dB
Analog input bandwidth⁴	Full-power bandwidth (–3 dB)	–	6	–	GHz
Return loss (R_L)⁵	Up to 4 GHz	–	–12	–	dB
Return loss (R_L)⁵	Up to 6 GHz	–	–10	–	dB
Optimized common mode voltage range	Performance optimized range. AC and DC coupling modes⁶	0.68	0.7	0.72	V
Maximum common mode voltage range	Available range before triggering over-voltage protection. AC and DC coupling modes⁶	0.4	0.7	1	V
Crosstalk isolation between channels⁷	F_IN = 0–4 GHz	–	–75	–	dBc
Crosstalk isolation between channels⁷	F_IN = 0–6 GHz	–	–70	–	dBc
Analog inputs at –1 dBFS, unless otherwise noted in the test conditions. Typical values are specified at nominal voltage, T_j = 40°C. Full scale range is defined as the approximate input power required to drive the ADC to full scale output for a 5 MHz input tone. The full scale range can vary from dual to quad ADCs. It is also subject to variation across process, voltage, and temperature and from package types. The typical average value is provided. ADC bandwidth is defined as the RF input bandwidth, or where the input amplitude response drops 3 dB relative to a low-frequency reference point of 100 MHz. This is the return loss of the worst case channel quoted from DC to a specified frequency point. Consult the S parameter I/O files for further details because input characteristics depend on channel and package selection. The RL reference plan is close to the BGA footprint, keeping two times the BGA pitch distance from ball contact to avoid micro-probing electromagnetic disturbance. When using DC coupling mode, use the VCM output pin to bias the input to the RF-ADC. Values represent two channel crosstalk worst-case values for any combination of channel selections. This specification is only characterized on the XCZU46DR-H1760.

Table 4. RF-ADC Electrical Characteristics for ZU6xDR Devices
Parameter	Comments/Conditions¹	Min	Typ²	Max	Units
Analog inputs
Resolution		14	–	–	Bits
Sample Rate	Quad ADC tile when ADC_AVCC = 1.01V and -2I, -2LI	0.5	–	2.95	GS/s
	Quad ADC tile when ADC_AVCC = 1.01V and -1I, -1LI, -1M	0.5	–	2.7	GS/s
	Dual ADC tile when ADC_AVCC = 1.01V and -2I, -2LI	1	–	5.9	GS/s
	Dual ADC tile when ADC_AVCC = 1.01V and -1I, -1LI, -1M	1	–	5.4	GS/s
Full-scale input³	Input 100Ω on-die termination when DSA attenuation = 0 dB	–	1.12	–	V_PPD
Full-scale input³	Input 100Ω on-die termination when DSA attenuation = 0 dB	–	2	–	dBm
Maximum allowed input power	Input 100Ω on-die termination when DSA attenuation ≥ 15 dB	–	4.8	–	V_PPD
Maximum allowed input power	Input 100Ω on-die termination when DSA attenuation ≥ 15 dB	–	14.6	–	dBm
Digital Attenuation Range		0	–	27	dB
Attenuator step size		–	1	–	dB
Auto attenuation	Automatically set when amplitude over-voltage is asserted	–	15	–	dB
Analog input bandwidth⁴	Full-power bandwidth (–3 dB)	–	7.125	–	GHz
Return loss (R_L)⁵	Up to 4 GHz	–	–12	–	dB
Return loss (R_L)⁵	Up to 7.125 GHz	–	–10	–	dB
Optimized common mode voltage range	Performance optimized range. AC and DC coupling modes⁶	0.68	0.7	0.72	V
Maximum common mode voltage range	Available range before triggering over-voltage protection. AC and DC coupling modes⁶	0.4	0.7	1	V
Crosstalk isolation between channels⁷	F_IN = 0–4 GHz	–	–69	–	dBc
Crosstalk isolation between channels⁷	F_IN = 0–7.125 GHz	–	–63	–	dBc
Analog inputs at –1 dBFS, unless otherwise noted in the test conditions. Typical values are specified at nominal voltage, T_j = 40°C. Full scale range is defined as the approximate input power required to drive the ADC to full scale output for a 5 MHz input tone. The full scale range can vary from dual to quad ADCs. It is also subject to variation across process, voltage, and temperature and from package types. The typical average value is provided. ADC bandwidth is defined as the RF input bandwidth, or where the input amplitude response drops 3 dB relative to a low-frequency reference point of 100 MHz. This is the return loss of the worst case channel quoted from DC to a specified frequency point. Consult the S parameter I/O files for further details because input characteristics depend on channel and package selection. The RL reference plan is close to the BGA footprint, keeping two times the BGA pitch distance from ball contact to avoid micro-probing electromagnetic disturbance. When using DC coupling mode, use the VCM output pin to bias the input to the RF-ADC. Values represent two channel crosstalk worst-case values for any combination of channel selections. This specification is only characterized on the XCZU67DR-E1156.