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Lock-in Tab (GHF-MF option)

This tab is the main lock-in amplifier control panel for GHFLI Instruments with the GHF-MF Multi-frequency option installed. Users with instruments without this option installed are kindly referred to Lock-in Tab.

Features

  • Parameter table with main input, output and demodulator controls
  • Controls for 8 individually configurable demodulators
  • Control for 8 oscillators
  • Settings for main signal inputs and signal outputs

Description

The Lock-in tab is the main control center of the instrument and open after start up by default. Whenever the tab is closed or an additional one of the same type is needed, clicking the following icon will open a new instance of the tab.

Table 1: App icon and short description
Control/Tool Option/Range Description
Lock-in MF Quick overview and access to all the settings and properties for signal generation and demodulation.

The lock-in tab provides controls for all demodulators in the instrument.

The lock-in tab for Multi-frequency GHFLI instruments`` (see Figure 1) consists of 5 vertical sections: Signal Inputs, Oscillators, Demodulators, Output 1 and Output 2. The Demodulator section contains 8 rows, each of them providing access to the settings of one dual phase demodulator. Every demodulator can be connected to any of the possible inputs, outputs and oscillators. Signal Input 1 and 2 are identical in all aspects, but each can be set to a different center frequency; the same holds for Signal Outputs 1 and 2. Each input and output pair constitutes a signal channel with a specific center frequency.

Figure 1: LabOne User Interface Lock-in tab with GHFLI-MF Multi-frequency option.

The Signal Inputs section allows the user to define all relevant settings specific to the signal at the input such as input coupling, amplitude range, etc. On the right-hand side of the Lock-in tab the two Output sections allow to define the individual tones amplitudes and the output range value.

The "Freq Range" button toggles the input between baseband, in which no analog mixing occurs and the signal is digitized directly, and RF, in which the analog up- and down-mixing path is selected. The AC/DC button sets the coupling type: AC coupling has a high-pass cutoff frequency that can be used to block large DC signal components to prevent input signal saturation during amplification. This button is only active when in baseband (BB) mode, because RF mode is AC coupled by design.

The Oscillator section controls the frequencies of all 8 internal oscillators. Where the Mode indicator shows Manual the user can define the oscillator frequency manually defined by typing a frequency value in the field.

The next section contains the Demodulators settings. The block diagram displayed in Figure 2 indicates the main demodulator components and their interconnection. The understanding of the wiring is essential for successfully operating the instrument.

Figure 2: Demodulator block diagram with GHFLI-MF Multi-frequency option.

Every line in the Demodulators section represents one demodulator. It is possible to demodulate the input signals with up to 8 demodulators simultaneously at up to 8 independent frequencies and using different filter settings.

In the Input Signal column one defines the signal that is taken as input for the demodulator. Currently Input 1 and Input 2 can be selected, but in the future more sources will be made available, such as Auxiliary Inputs and Outputs.

Demodulation of frequencies that are at integer multiples of any of the oscillator frequencies is achieved by entering the desired factor in the "n" column; the demodulation frequency is then the oscillator frequency times the factor n plus the channel center frequency. The result of the demodulation, the amplitude and phase can be read, for instance, using the Numeric tab which is described in Numeric Tab.

In the center of the Lock-in tab is the Low-Pass Filters section where the filter order for each demodulator can be selected in the drop-down list and the filter bandwidth (BW 3dB) can be chosen by typing a numerical value. Alternatively the time constant of the filter (TC) or the noise equivalent power filter bandwidth (BW NEP) can be chosen from the drop-down menu in the column’s header. Each unit of the filter order correspond to a 6 dB/oct increase in the filter steepness; for example, setting the filter order to 4 corresponds to a roll off of 24 dB/oct or 80 dB/dec i.e. an attenuation of 104 for a tenfold frequency increase. If the Low-Pass Filter bandwidth is comparable to or larger than the oscillator frequency (not the full demodulator frequency), the demodulator output may contain frequency components at the frequency of demodulation and its higher harmonics, when operating in baseband, or the component at the center of the measurement window (i.e. oscillator frequency =0). In this case, a smaller low-pass filter bandwidth is recommended, and the additional Sinc Filter should be enabled. The Sinc Filter is useful when measuring at low oscillator frequencies, since it allows one to apply a Low-Pass Filter bandwidth closer to the oscillator frequency, thus speeding up the measurement time

The data transfer of demodulator outputs is activated by the Enable button in the Data Transfer section where also the sampling rate (Rate) for each demodulator can be defined.

The 2 Output sections are only available on Instruments with the GHFLI-MF option installed. They allow for the flexible adjustment of output amplitudes of different demodulators and their summation on either Signal Output 1 or Signal Output 2. In order to avoid signal clipping the sum of the amplitudes of each signal output needs to be smaller than the range defined in the the corresponding Output section. At the top of each Output section one can select the format in which amplitudes are displayed in that section between root mean square values or peak-to-peak values.

In the top right-hand-side corner of each Output section the On button turns on or off the corresponding physical output. Even when the Output panel is collapsed, the On button remains available. The Range drop down list is used to select the proper output range setting for each channel.

Functional Elements

Note

Please note that some elements will be implemented in a future LabOne release. This is reflected in the description of these elements in the table below and also in the LabOne tooltips.

Table 2: Lock-in MF tab
Control/Tool Option/Range Description
Frequency Range Switch between RF and Baseband frequency range.
Center Frequency Center frequency of the detection band at the input/output of the instrument.
Range Defines the gain of the analog input amplifier. The range should exceed the incoming signal by roughly a factor two including a potential DC offset.

The instrument selects the next higher available range relative to a value inserted by the user. A suitable choice of this setting optimizes the accuracy and signal-to-noise ratio by ensuring that the full dynamic range of the input ADC is used.
Auto Automatic adjustment of the Range to about two times the maximum signal input amplitude measured over about 100 ms. It will be implemented in a future release.
Coupling OFF: DC coupling Defines the input coupling for the Signal Inputs. AC coupling inserts a high-pass filter.
ON: AC coupling
Mode Indicates how the frequency of the corresponding oscillator is controlled (manual, external reference, PLL, PID). Read only flag.
Manual The user setting defines the oscillator frequency.
ExtRef An external reference is mapped onto the oscillator frequency.
Frequency (Hz) Frequency control for each oscillator.
Locked ON / OFF Oscillator locked to external reference when turned on.
Mode Select the reference mode (manual or external reference) or indicate the unit that uses the demodulator (e.g. PLL).
Manual Default lock-in operating mode with manually set reference frequency.
ExtRef The demodulator is used for external reference mode and tracks the frequency of the selected reference input. The demodulator bandwidth is set automatically to adapt to the signal properties.
Osc oscillator index Connects the selected oscillator with the demodulator corresponding to this line. Number of available oscillators depends on the installed options.
Harm 1 to 1023 Multiplies the demodulator's reference frequency with the integer factor defined by this field.
Demod Freq (Hz) Indicates the frequency used for demodulation and for output generation.
Phase (deg) -180° to 180° Phase shift applied to the reference input of the demodulator.
Zero Adjust the phase of the demodulator reference automatically in order to read zero degrees at the demodulator output.

This action maximizes the X output, zeros the Y output, zeros the Θ output, and leaves the R output unchanged.
Signal Selects the signal source to be associated to the demodulator.
Sig In 2 Signal Input 2 is connected to the corresponding demodulator.
Sig In 1 Signal Input 1 is connected to the corresponding demodulator.
Order Selects the filter roll off between 6 dB/oct and 48 dB/oct.
1 1st order filter 6 dB/oct
2 2nd order filter 12 dB/oct
3 3rd order filter 18 dB/oct
4 4th order filter 24 dB/oct
TC/BW Select Defines the display unit of the low-pass filters: time constant (TC) in seconds, noise equivalent power bandwidth (BW NEP) in Hz, 3 dB bandwidth (BW 3 dB) in Hz.
TC Defines the low-pass filter characteristic using time constant (s) of the filter.
BW NEP Defines the low-pass filter characteristic using the noise equivalent power bandwidth (Hz) of the filter.
BW 3 dB Defines the low-pass filter characteristic using the 3 dB cut-off frequency (Hz) of the filter.
TC/BW Value numeric value Defines the low-pass filter characteristic in the unit defined above.
Sinc ON / OFF Enables the sinc filter.

When the filter bandwidth is comparable to or larger than the demodulation frequency, the demodulator output may contain frequency components at the frequency of demodulation and its higher harmonics. The sinc is an additional filter that attenuates these unwanted components in the demodulator output.
Filter Lock Makes all demodulator filter settings equal (order, time constant, bandwidth).

Enabling the lock copies the settings from demodulator 1 to all other demodulators. With locked filters, any modification to a filter setting is applied to all other filters, too. Releasing the lock does not change any setting.
Enable Streaming ON / OFF Enables the data acquisition and streaming of demodulated samples to the host computer for the corresponding demodulator. The streaming rate is defined in the field on the right hand side. Enabling a stream activates a corresponding element in the numeric tab and allows for demodulated samples to be visualized and analyzed in any of the LabOne measurement tools. Note: increasing number of active demodulators increases load on physical connection to the host computer.
Rate (Sa/s) Defines the demodulator sampling rate, the number of samples that are sent to the host computer per second. A rate of about 7-10 higher as compared to the filter bandwidth usually provides sufficient aliasing suppression.

This is also the rate of data received by LabOne Data Server and saved to the computer hard disk. This setting has no impact on the sample rate on the auxiliary outputs connectors. Note: the value inserted by the user may be approximated to the nearest value supported by the instrument.
Demodulator Sampling Rate Lock Makes all demodulator sampling rates equal.

Enabling the lock copies the settings from demodulator 1 to all other demodulators. With locked sampling rates, any modification to a sampling rate is applied to all other sampling rate fields, too. Releasing the lock does not change any setting.
Amplitude Unit Vpk, Vrms Select the unit of the displayed amplitude value.
Amplitude Enable ON / OFF Enables individual output signal amplitude.
Amplitude (V) -range to range Defines the output amplitude for each demodulator frequency as rms or peak-to-peak value.

A negative amplitude value is equivalent to a phase change of 180 degree. Linear combination of multiple amplitude settings on the same output are clipped to the range setting. Note: the value inserted by the user may be approximated to the nearest value supported by the Instrument.
Auto Range Selects the most suited output range automatically. It will be implemented in a future release.
Output Clipping grey/red Indicates that the specified output amplitude(s) exceeds the range setting. Signal clipping occurs and the output signal quality is degraded. Adjustment of the range or the output amplitudes is required.
Offset -range to range Defines the DC voltage that is added to the dynamic part of the output signal.
On ON / OFF Main switch for the Signal Output corresponding to the blue LED indicator on the instrument front panel.
Range Defines the maximum output voltage that is generated by the corresponding Signal Output. This includes the potential multiple Signal Amplitudes and Offsets summed up. Select the smallest range possible to optimize signal quality.

This setting ensures that no levels or peaks above the setting are generated, and therefore it limits the values that can be entered as output amplitudes. Therefore selected output amplitudes are clipped to the defined range and the clipping indicator turns on. If 50 Ω target source or differential output is enabled the possible maximal output range will be half.