Introduction
Since their invention back in the 1960's, lock-in amplifiers have been used whenever the need arises to measure the amplitude and/or phase of a signal of known frequency in the presence of noise. Unlike other AC measuring instruments they have the ability to give accurate results even when the noise is much larger than the signal - in favorable conditions even up to a million times larger.

Early instruments used analog technology, with manual controls and switches, and with output readings being taken from large panel meters. Later, microprocessors were added to give more user-friendly operation, digital output displays, and to support computer control. More recently the analog phase sensitive detectors forming the heart of the instrument have been replaced by DSP (digital signal processing) designs, further improving performance.

But the addition of this digital technology has had one unfortunate side effect, which is that the instrument itself can act as a source of digital clock and switching noise, which is typically coupled back into the experiment via the signal or internal oscillator connectors. This noise is of course rejected by the lock-in and generally does not impair its performance, but the power it dissipates in the sample or device under test can cause serious problems. This is particularly the case in low temperature physics experiments.

SIGNAL RECOVERY is therefore proud to introduce the model 7124 precision lock-in amplifier, which is particularly suited to such work. It uses a unique analog fiber optic link to interconnect a remote connection unit (RCU), to which the experiment is connected, and a main instrument console. In normal operation there are no digital clock signals within the RCU, and so it can emit no switching noise.

This architecture gives an instrument with all the advantages of the latest DSP technology for signal detection, and a powerful processor for easy user operation, as well as the low noise performance that until now has only been available in instruments of all-analog design. 

Signal and Reference Connections
In normal use the 7124's signal and reference connections are made at the RCU. The signal input can be switched to operate in single ended or differential voltage mode, or in current mode with a choice of two transimpedance settings. It can also be used to switch between two single-ended voltage signals, for simple sequential measurement, under computer control, of two inputs. In cases where further preamplification is needed then one of the SIGNAL RECOVERY remote preamplifiers can be used, with its output connected to the 7124's single ended voltage input. This flexible choice of input modes allows the best possible connection to be made to the experiment. The RCU also has both general purpose analog and TTL logic reference inputs, as well as the output for a precision DDS oscillator that generates a sine wave signal of adjustable frequency and amplitude.

The RCU is connected to the main instrument console via a 16ft (5 m) fiber cable bundle that carries the applied signal and oscillator outputs in analog form, and control signals to the RCU and the reference signal from it, in digital format. However, the RCU contains no digital clocks or oscillators that are running continuously, and so unlike all other lock-in amplifiers that use any form of logic control, there is no digital switch noise present at the signal connectors.

Main Console
The 7124's main console is a compact, benchtop unit with a color display, and keys for operating the instrument controls, accessing different menus, and easy entry of numeric values. It receives signals from the RCU module and processes them using powerful DSP algorithms running in a dedicated field programmable gate array (FPGA), supported by a ColdFire processor. The operating frequency range is from 0.5 Hz to 150 kHz, with a main ADC sampling rate and analog output DAC update rate of 1 MHz, which is ideal for use with the available time constants, which go down to 10 µs.

Manual operation is straightforward and based on a similar menu structure to that used on the model 7280, using the color TFT display panel in conjunction with the keys grouped around it and the numeric keypad to adjust the instrument's controls, with the selected outputs being shown both on the display and being available as analog signals from four rear-panel connectors.

The Main Display is used in normal operation and shows four user-selected instrument controls on the left-hand side and four user-selected outputs, output offset status, and the present reference frequency, on the right. The output display selections include digital and bar-graph displays in a variety of formats. Error information, such as input and output overload, and reference unlock indication, is clearly shown along the top edge of the display, while soft keys along the bottom edge are used for selecting controls and to initiate numerical keypad data entry.

Extended Operating Modes
The instrument includes the extended operating modes made popular by other SIGNAL RECOVERY lock-in amplifiers, such as the models 7265 and 7280.

In normal Single Reference mode, harmonic analysis can be performed on harmonics up to 127 x F, while in Dual Harmonic mode the signals at two harmonics of the reference signal can be simultaneously measured. The instrument can therefore be used to measure a fundamental frequency and one harmonic of it at the same time.

Dual Reference mode permits measurement of two signals at two unrelated frequencies to be performed simultaneously. For example, in an optical experiment the signals passing through two different paths can be independently measured if they are modulated at two different modulation frequencies.

The Spectral Display allows the spectrum of the signals present at the input to be calculated and displayed, which can help when choosing the reference frequency

The instrument also includes a "tandem" demodulation mode which allows an amplitude-modulated signal to be first demodulated at a carrier frequency, with the output from this demodulation being processed by a second demodulator running at a lower frequency.

The Synchronous Oscillator output is an analog sinusoidal signal equivalent to that being used to drive the in-phase demodulator, and available in both internal and external reference modes. Hence, for example, if the instrument is set to 2F reference mode and a 1 kHz reference is applied, then this output will be a 2 kHz sine wave.

Inputs and Outputs
The 7124RCU unit has inputs to the signal and reference channel, and an oscillator output. It also has an 8-way digital output port for peripheral control. The main console provides another oscillator output, auxiliary signal channel input, four auxiliary ADC inputs, and four DAC outputs. The DAC outputs can be set to function as analog outputs for the signal measurement (e.g. X, Y, Magnitude, Phase) and/or general purpose programmable analog outputs.

Computer Control
External control of the unit is via USB, RS232 or Ethernet interfaces, using simple mnemonic-type ASCII commands.

Software support is available in the form of a LabVIEW driver supporting all instrument functions, and the Acquire™ data acquisition software. The driver and a demonstration version of the software, DemoAcquire, are available for download from this site.

Click here for detailed specifications

SIGNAL RECOVERY is part of Advanced Measurement Technology, Inc, a division of AMETEK, Inc.
 It includes the businesses formerly trading as EG&G Instruments (Signal Recovery),
EG&G Signal Recovery and PerkinElmer Instruments (Signal Recovery)

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