Features

High Range
Range: ± 30 V, ± 500 mA (DC/pulse)
High Resolution
The minimum measurement resolution can reach 100 pA/60 μV
High Rampling Rate
Supports up to 500K ADC sampling rate
Threshold Trigger
Hardware high-speed IO, capable of threshold triggering, enabling efficient interaction between output measurement values and user systems

Functions and Advantages

I-V Output Capability

Voltage Source Specifications

Voltage Programming Accuracy	Range	Programming Resolution	Accuracy (1 year) ± (% reading+offset)^[1]	Typical Noise (RMS) 0.1 Hz-10 Hz
	± 30 V^[3]	1 mV	0.03%+4 mV	1000 μV
	± 6 V	200 μV	0.03%+1 mV	100 μV
Temperature Coefficient	± (0.15 x accuracy)/℃ (0 ℃ -18 ℃, 28 ℃ -50 ℃)
Channel^[2]	CH1 to CH8
Output Power	Ch1 Ch4: 3 W per channel and 6W total Ch5 Ch8: 3 W per channel and 6W total
Overshoot	< ± 0.1% (typical, normal, step is 10% to 90%, full range, resistive load)
Noise 10Hz-20MHz	6V voltage source, 0.5A resistive load,< 3 mVrms

[1] Accuracy calculation example: For testing the accuracy of a 6V range with a 1V output, the tolerance is

[2] All channel outputs are electrically isolated from ground, but the outputs of channels CH1-CH4 share a common ground (LO)

[3] This instrument has potentially dangerous high voltage (±31.5 V) output to the HI / Sense HI / Guard terminals. To prevent electric shock, relevant precautions must be taken before powering on. Safety precautions. Do not connect the Guard terminal to any output, including shorting it to chassis ground or output LO, as this will damage the instrument.

Current Source Specifications

Current Programming Accuracy	Range	Programming Resolution	Accuracy (1 year) ± (% reading+offset)	Typical Noise (RMS) 0.1 Hz-10 Hz
	± 500 mA^[4]	20 μA	0.05%+100 μA+ Vo * 25 μA	10 μA
	± 100 mA	4 μA	0.05%+10 μA+ Vo * 5 μA	1 μA
	± 10 mA	400 nA	0.05%+5 μA+ Vo * 500 nA	100 nA
	± 1 mA	40 nA	0.05%+500 μA+ Vo * 50 nA	10 nA
	± 100 μA	4 nA	0.05%+50 nA+ Vo * 5 nA	1 nA
	± 10 μA	400 pA	0.05%+20 nA+ Vo * 500 pA	150 pA
Temperature Coefficient	± (0.15 x accuracy)/℃ (0 ℃ -18 ℃, 28 ℃ -50 ℃)
Channel^[5]	CH1 to CH8
Output Power	Ch1 Ch4: 3W per channel and 6W total Ch5 Ch8: 3W per channel and 6W total
Overcharge	< ± 0.1% (typical, normal, step is 10% to 90%, full scale point, resistive load test)

[4] 500mA range is available only for 6V voltage range

[5] Channels are isolated from earth ground, but CH1 to CH4 share a common LO, and CH5 to CH8 share a common LO

Voltage Measurement Specificationgs

Voltage Measurement Accuracy	Range	Measurement Resolution	Accuracy (1 year) ± (% reading+offset)
	± 30 V	300 μV	0.03%+4 mV
	± 6 V	60 μV	0.03%+1 mV
Temperature Coefficient		± (0.15 x accuracy)/℃ (0 ℃ -18 ℃, 28 ℃ -50 ℃)

Current Measurement Specifications

Current Measurement Accuracy	Range	Measurement Resolution	Accuracy (1 year) ± (% reading+offset)
	± 500 mA^[6]	10 μA	0.05%+100 μA+ Vo * 25 μA
	± 100 mA	1 μA	0.05%+10 μA+ Vo * 5 μA
	± 10 mA	100 nA	0.05%+5 μA+ Vo * 500 nA
	± 1 mA	10 nA	0.05%+500 nA+ Vo * 50 nA
	± 100 μA	1 nA	0.05%+50 nA+ Vo * 5 nA
	± 10 μA	100 pA	0.05%+20 nA+ Vo * 500 pA
Temperature Coefficient		± (0.15 x accuracy)/℃ (0 ℃ -18 ℃, 28 ℃ -50 ℃)

[6] 500mA range is available only for 6V voltage range

Typical Output Setting Time

Source	Range	Output setting time^[7]			Condition
Source	Range	Fast^[8]	Normal	Slow	Condition
Voltage	30 V	< 400 μs	< 1.5ms	< 2.8 ms	Time required to reach within 0.1 % of final value at open load condition. Step is 10 % to 90 % range
Voltage	6 V	<250 μs	<780 μs	<2.8 ms
Current	± 500 mA	<50 μs	<330 μs	<2.5 ms	Time required to reach within 0.1 % of final value at short condition. Step is 10 % to 90 % range
	±100 mA	<50 μs	<270 μs	<2.5 ms
	±10 mA	<50 μs	<270 μs	<2.5 ms
	±1 mA	<100 μs	<290 μs	<2.5 ms
	±100 μA	<150 μs	<5 ms	<2.5 ms
	±10 μA	<250 μs	<3 ms	<2.5 ms

[7] Output transition rate: Three modes of Fast, Normal, and Slow are available, allowing users to adjust according to load characteristics to achieve appropriate setup time or stability. This feature only supports switching the output transition rate when OUTPUT is set to OFF

[8] The Fast mode may produce a large overshoot under different ranges or load conditions. For overshoot-sensitive devices, it is recommended to use normal or Slow mode. mode

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Voltage Source Specifications

Current Source Specifications

Voltage Measurement Specificationgs

Current Measurement Specifications

Typical Output Setting Time