SRS Labs SR530, Lock-In Amplifier manual Auto Phase

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possible. If R is less than 0.5% of full scale, the phase output defaults to zero degrees.

The Phase Output may not be expanded and the OFFSET keys do not offset the Phase Output. However, the Phase Output can be offset using the Reference Phase shift.

The Reference Phase shift, which may be adjusted via the phase controls in the reference section, rotates the lock-in's internal coordinate axes relative to the reference input. The Phase Output is the phase difference between the signal and the lock-in's coordinate system. For example, if a signal exactly in phase with the reference input is being measured and the Reference Phase shift is zero, the Phase Output will be zero also. This is because the lock-in coordinate system is in phase with the reference input and signal. If the Reference Phase shift is set to +45 degrees, then the lock-in coordinate system rotates to +45 degrees from the reference input. Thus, the reference input is now at -45 degrees from the lock-in coordinate axes. Since the reference and signal are in phase, the signal is now at -45 degrees with respect to the lock-in coordinates and the Phase Output will be -45 degrees.

The sum of the Reference Phase shift and the Phase Output is the absolute phase difference between the signal and the reference input.

Therefore, the Phase Output may be offset to zero by adjusting the Reference Phase shift. This is sometimes necessary when the Phase Output is near 180 degrees and varies between +180 and - 180 degrees.

Output Channel 2

The CHANNEL 2 output is available at the right hand OUTPUT BNC connector. The output parameter is selected by the DISPLAY setting and can be Y, Y OFST, Ø (phase), Ø (phase), Y NOISE, or X6 (ext D/A). All outputs are ±10V full scale when the EXPAND is off. With the EXPAND on, the output is multipled by 10, effectively increasing the full scale sensitivity by 10. (Ø and X6 may not be expanded). The Ø (phase) output is 50 mV/deg (20 deg per Volt) up to ±9 V (±180 deg). The output impedance is <1Ω and the output current is limited to 20 mA.

The right hand analog meter always displays the CHANNEL 2 OUTPUT voltage. Accuracy is 2% of full scale.

The CHANNEL 2 LCD display provides a read-out of the displayed parameter in real units. The scale of the displayed quantity is indicated by the four scale LED's to the right of the display. This read- out auto ranges and will reflect the sensitivity added when the EXPAND function is on. When displaying X6, the scale LED's are off and the units are volts.

Rel Channel 2

Every time the REL key is pressed, the displayed parameter is offset to zero. This is done by loading the displayed parameter's offset with minus one times the present output. If the output is greater than 1.024 times full scale, the REL function will not be able to zero the output. In this case, the OFFSET ON LED will blink and the offset value will be set to its maximum value.

The REL function and the manual OFFSET are both ways to enter the offset value. After using the REL key, the offset may be adjusted using the manual OFFSET.

When the DISPLAY is Y, Y OFST, or Y NOISE, the REL key sets the Y OFFSET (which affects the Y (RSINØ) output). If Y NOISE is being displayed, the REL function zeroes Y and the noise output will require a few seconds to settle again.

The REL key zeroes the X6 output when the DISPLAY is D/A.

Auto Phase

When the DISPLAY is Ø (phase), the REL key sets the Reference Phase Shift to the absolute phase difference between the signal and the reference. This is done by setting the Reference Phase Shift to the sum of the Reference Phase Shift and the present Phase Output. After auto- phase is performed, the Ø output will be 0 deg, R will be unchanged, X will be maximized, and Y will be minimized.

Offset Channel 2

The OFFSET section controls the manual offset. The offset is turned ON and OFF using the upper key in the OFFSET section. When the offset is ON, the lower two keys are used to set the amount of offset. A single key press will advance the offset by 0.025% of full scale. If the key is held

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Contents Model SR530 Page Table of Contents Appendix C Gpib NON-OPERATING OperatingPage SR530 Specification Summary Gpib DemodulatorFront Panel Summary Enbw Abridged Command List Status Byte Definition Configuration SwitchesSignal Filters Signal InputsSR510 Guide to Operation Front Panel SensitivityStatus Dynamic ReserveDisplay Select Channel 1 DisplayOutput Channel OutputRel Channel Offset ChannelChannel 2 Display Expand ChannelRcosø Output Auto Phase Trigger Level Rsinø OutputReference Input Phase Controls Reference ModeReference Display Time ConstantLocal and Remote PowerDefaults SR530 Guide to Operation Rear Panel Page SR530 Guide to Programming Command SyntaxCommunicating with the SR530 Front Panel Status LEDsTry-Out with an Ascii Terminal RS232 Echo and No Echo OperationLOW Norm High SR530 Command ListN1,n2,n3,n4 Page Bit ErrorsStatus Byte Trouble-Shooting Interface Problems ResetCommon Hardware Problems include Common Software Problems includeSR530 with the Gpib Interface SR530 with the RS232 InterfaceSR530 with Both Interfaces Serial Polls and Service RequestsGpib with RS232 Echo Mode Measurement Example Lock-in TechniqueShielding and Ground Loops Understanding the SpecificationsPage Page SR530 Block Diagram Phase Sensitive Detectors Signal ChannelReference Channel DC Amplifiers and System GainCircuit Description Demodulator and Low Pass Amplifier Reference OscillatorExpand Analog Output and ControlFront Panel Microprocessor ControlGpib Interface Power SuppliesRS232 Interface Calibration and Repair Multiplier AdjustmentsAmplifier and Filter Adjustments Replacing the Front-End Transistors Notch FiltersNon-Essential Noise Sources Appendix a Noise Sources and CuresPage Page Appendix B Introduction to the RS232 Case 1 The Simplest ConfigurationBaud Rate Case 2 RS232 with Control LinesParity Stop BitsVoltage Levels Final TipBus Description Appendix C Introduction to the GpibProgram Example IBM PC, Basic, via RS232 Appendix D Program ExamplesProgram Example IBM PC, Microsoft Fortran v3.3, via RS232 Page #include stdio.h Program Example IBM PC, Microsoft C v3.0, via RS232Page Program Example 4 IBM PC,Microsoft Basic, via Gpib ′INCREMENT X6 Output by 2.5 MV Program Example HP85 via Gpib Documentation PC1 Oscillator Board Parts ListSW1 DpdtBR1 Main Board Parts ListBR2 BT1SR530 Component Parts List SR530 Component Parts List PIN D 22U MINGpib Shielded CX1MPSA18 CY1FU1 SR530 Component Parts List SR530 Component Parts List SR530 Component Parts List SR530 Component Parts List SR530 Component Parts List SR513 Assy SPSTX84PDT SR530 Component Parts List Static RAM, I.C Z80A-CPUTranscover TIE AnchorMica #4 FlatFront Panel Board Parts List RED LD3 LD1LD2 Quad Board Parts List SR530 Component Parts List PC1 SR530 Component Parts List Miscellaneous Parts List SR530 Component Parts List

SR530, Lock-In Amplifier specifications

The SRS Labs Lock-In Amplifier, model SR530, is a powerful tool designed for high-precision measurements in the realm of scientific research and industrial applications. This state-of-the-art instrument excels in extracting small signals from noisy environments, making it an invaluable asset for experiments in fields such as physics, engineering, and materials science.

One of the main features of the SR530 is its ability to perform synchronous detection, which is key to improving signal-to-noise ratios. By utilizing a reference signal, the device correlates the incoming signal with the reference to effectively filter out noise, allowing for the accurate measurement of weak signals that might otherwise be obscured. This process of phase-sensitive detection is fundamental to the operation of the Lock-In Amplifier.

The SR530 offers a wide frequency range, covering from 0.1 Hz to 100 kHz. This broad frequency response allows it to handle a diverse array of signals, making it suitable for various applications including optical detection, capacitance measurements, and in many cases, voltammetry. The device is also equipped with multiple inputs and outputs, facilitating the integration with other laboratory equipment and enabling complex experimental setups.

Precision is further enhanced with its adjustable time constant, which allows users to optimize the response time based on experimental needs. The user can choose time constants from 10 microseconds to 10 seconds, accommodating fast dynamic measurements as well as those requiring stability over longer durations.

Another remarkable characteristic of the SR530 is its digital processing capabilities. The device features a highly accurate digital voltage measurement system, minimizing drift and ensuring long-term stability. Additionally, the use of microprocessors enhances data handling and allows for features such as programmable settings, facilitating automated measurements.

Moreover, the SR530 includes a range of output options, including analog outputs, which can be used for direct signal processing, as well as digital interfaces for integration with computers. This ensures that users can not only capture high-fidelity data but also analyze and display it efficiently.

In conclusion, the SRS Labs SR530 Lock-In Amplifier stands out due to its sophisticated technology, versatile features, and robust performance. Its precision, flexibility, and ease of use make it an ideal choice for researchers and engineers looking to unlock the potential of weak signal measurement in complex environments.
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