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Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers Low Noise Current

Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers Low Noise Current

  • Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers Low Noise Current
  • Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers Low Noise Current
  • Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers Low Noise Current
Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers Low Noise Current
Product Details:
Place of Origin: United States
Brand Name: Keysight (Agilent)
Model Number: SR570
Payment & Shipping Terms:
Minimum Order Quantity: 1 set
Price: Negotiation
Payment Terms: T/T
Supply Ability: in stock
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Detailed Product Description
Product Name: Low Noise Current Preamplifier Input Noise: 120 Hz/1 KHz/1 MHz
Frequency: 0.03 Hz - 1 MHz Form Factor: Benchtop
Condition: Pre-Owned Functions: Tested, In Full Working Conditions
High Light:

Stanford Research Systems SR570 Amplifiers

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Tested SR570 Amplifiers

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Low Noise Current SR570 Amplifiers

Tested In Full Working Condutions Stanford Research Systems SR570 Amplifiers

 

Description of Stanford Research Systems SR570 Amplifiers

 

The SR570 is a low-noise current preamplifier capable of current gains as large as 1 pA/V. High gain and bandwidth, low noise, and many convenient features make the SR570 ideal for a variety of photonic, low temperature and other measurements.

Gain
The SR570 has sensitivity settings from 1 pA/V to 1 mA/V that can be selected in a 1-2-5 sequence. A vernier gain adjustment is also provided that lets you select any sensitivity in between.
Gain can be allocated to various stages of the amplifier to optimize the instruments performance. The low noise mode places gain in the front end of the amplifier for the best noise performance. The high bandwidth mode allocates gain to the later stages of the amplifier to improve the frequency response of the front end. In the low drift mode, the input amplifier is replaced with a very low input-current op amp, reducing the instrument’s DC drift by up to a factor 1000.

 

Filters

The SR570 contains two first-order RC filters whose cutoff frequency and type can be configured from the front panel. Together, the filters can be configured as a 6 or 12 dB/oct rolloff low-pass or high-pass filter, or as a 6 dB/oct rolloff band-pass filter. Cutoff frequencies are adjustable from 0.03 Hz to 1 MHz in a 1-3-10 sequence. A filter reset button is included to shorten the overload recovery time of the instrument when long filter time constants are used.

 

Input Offset and DC Bias

An input offset-current adjustment is provided to suppress any undesired DC background currents. Offset currents can be specified from ±1 pA to ±1 mA in roughly 0.1 % increments. The SR570 also has an adjustable input DC bias voltage (±5 V) that allows you to directly sink current into a virtual null (analog ground) or a selected DC bias.

 

Toggle and Blanking

 

Two rear-panel, opto-isolated TTL inputs provide additional control of the SR570. A blanking input lets you quickly turn off/on the instrument's gain which is useful in preventing front-end overloading. A toggle input inverts the sign of the gain in response to a TTL signal allowing you to perform synchronous detection with a chopped signal.

 

Battery Operation

 

Three rechargeable lead-acid batteries provide up to 15 hours of battery-powered operation. An internal battery charger automatically charges the batteries when the unit is connected to the line. The charger senses the battery state and adjusts the charging rate accordingly. Two rear-panel LEDs indicate the charge state of the batteries. When the batteries become discharged they are automatically disconnected from the amplifier circuit to avoid battery damage.

 

No Digital Noise

 

The microprocessor that runs the SR570 is "asleep" except during the brief interval it takes to change the instrument's setup. This ensures that no digital noise will contaminate low-level analog signals.

 
SR570 Specifications
Input
Inputs Virtual null or user-set bias (±5 V)
Input offset ±1 pA to ±1 mA adjustable DC offset current
Maximum input ±5 mA
Noise See table below
Sensitivity 1 pA/V to 1 mA/V in 1-2-5 sequence (vernier adj. in 0.5 % steps)
Frequency response ±0.5 dB to 1 MHz. Adjustable front-panel frequency response compensation for source capacitance.
Grounding Amplifier ground is fully floating. Amplifier and chassis ground are available at rear panel. Input ground can float up to ±40 V.
Filters
Signal filters 2 configurable (low-pass or high-pass) 6 dB/oct rolloff filters. -3 dB points are settable in a 1-3-10 sequence from 0.03 Hz to 1 MHz.
Gain allocation
Low noise Gain is allocated to the front end for best noise performance.
High bandwidth Front-end gain is reduced for optimum frequency response.
Low drift Low bias current amplifier is used for reduced drift at high sensitivity.
Filter reset Long time constant filters may be reset with front-panel button.
Output
Gain accuracy ±0.5 % of output + 10 mV
(25 °C)
DC drift See table below
Maximum output ±5 V into a high impedance load
General
External blanking TTL input sets gain to zero
External toggle TTL input inverts gain polarity
Rear panel biasing ±12 VDC @ 200 mA, referenced to amplifier ground
Computer interface RS-232, 9600 baud, receive only
Power 100/120/220/240 VAC, 6 watts charged, 30 watts while charging. Internal batteries provide 15 hours of operation between charges. Batteries are charged while connected to the line.
Dimensions 8.3" × 3.5" × 13.0" (WHL)
Weight 15 lbs. (batteries installed)
Warranty One year parts and labor on defects in materials and workmanship
       
Sensitivity
(A/V)
Bandwidth
(-3 dB)*
Noise/vHz** Temp. coefficient ± (%input + offset)/°C DC Input
Impedance
  High BW Low Noise High BW Low Noise Low Drift (11 to 28 °C) All Modes
10-3 1.0 MHz 1.0 MHz 150 pA 150 pA 0.01 % + 20 nA 1 Ω
10-4 1.0 MHz 500 kHz 100 pA 60 pA 0.01 % + 2 nA 1 Ω
10-5 800 kHz 200 kHz 60 pA 2 pA 0.01 % + 200 pA 100 Ω
10-6 200 kHz 20 kHz 2 pA 600 fA 0.01 % + 20 pA 100 Ω
10-7 20 kHz 2 kHz 600 fA 100 fA 0.01 % + 2 pA 10 kΩ
10-8 2 kHz 200 Hz 100 fA 60 fA 0.01 % + 400 fA 10 kΩ
10-9 200 Hz 15 Hz 60 fA 10 fA 0.025 % + 40 fA 1 MΩ
10-10 100 Hz 10 Hz 10 fA 5 fA 0.025 % + 20 fA 1 MΩ
10-11 20 Hz 10 Hz 10 fA 5 fA 0.040 % + 20 fA 1 MΩ
10-12 10 Hz 10 Hz 5 fA 5 fA 0.040 % + 20 fA 1 MΩ


* Frequency Compensation adjusted for flat frequency response
** Average noise in the frequency range below the 3 dB point but above the frequency where 1/f noise is significant
 
 
FAQ:

1.Can you ship order to Canada or Australia ?
Yes,we can .We send orders worldwide .
2. What delivery method do you use ? and delivery time ?
We can ship by EMS,DHL,FedEx,UPS,TNT with tracking number. Usual delivery time is 4-7 workdays.
3. What is your payment term?
100% T/T payment before shipment.
4. How can I ask any other question ?
You can contact us online or leave us messages below .

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