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Lock-in Tab

This tab is the main lock-in amplifier control panel. Users with instruments with MF-MD Multi-demodulator option installed are kindly referred to Lock-in Tab (MF-MD option)

Features

  • Functional block diagram with access to main input, output and demodulator controls
  • Parameter table with main input, output and demodulator controls
  • Control elements for 1 configurable demodulator
  • Auto ranging, scaling, arbitrary input units for both input channels
  • Control for 1 oscillator
  • Settings for main signal inputs and signal outputs
  • Flexible choice of reference source, trigger options and data transfer rates

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 Quick overview and access to all the settings and properties for signal generation and demodulation.

The default view of the Lock-in tab is the parameter table view. It is accessible under the side tab labeled All and provides controls for all demodulators in the instrument. Moreover, for each individual demodulator there is a functional block diagram available. It is accessible under the side tab labeled with the corresponding demodulator number.

Parameter Table

The parameter table (see Figure 1) consists of 4 sections: Signal Inputs, Oscillators, Demodulators and Signal Outputs. The Demodulator section consists of two rows where the upper row offers access to all the settings of the dual phase demodulator, the second row represents the phase detector for the PLL used for external reference. The user can obtain and change the filter settings but not transfer the data to the data server.

Figure 1: LabOne User Interface Lock-in tab - Parameter table (All)

The Signal Inputs section allows the user to define all relevant settings specific to the signal entered as for example input coupling, range, etc. Some of the available options like phase adjustment and the trigger functionality are collapsed by default. It takes one mouse click on the "+" icon in order to expand those controls. On the right-hand side of the Lock-in tab the Signal Outputs section allows defining signal amplitudes, offsets and range values.

The Scaling field below the Range field can be used to multiply the Signal Input data for instance to account for the gain of an external amplifier. In case there is a transimpedance gain of 10 V/A applied to the input signal externally, then the Scaling field can be set to 0.1 and the Units field can be set to A in order to show the actual current readings through the entire user interface. Below the Scaling field there is the AC/DC button and the 50 Ω/ 10 MΩ . 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. The 50 Ω/ 10 MΩ button toggles the input impedance between low (50 Ω) and high (approx. 10 MΩ ) input impedance. With 50 Ω input impedance, one will expect a reduction of a factor of 2 in the measured signal if the signal source also has an output impedance of 50 Ω.

Note

The Signal Inputs can be set to float which means that the BNC connector shield is no longer connected to the instrument ground. This setting affects both the current input and the voltage input. It is recommended to discharge the test device before connecting or to enable this setting only after the signal source has been connected to the Signal Input in grounded mode.

The Oscillator section indicates the frequency of the internal oscillator . Where the Mode indicator shows Manual, the user can define the oscillator frequency manually defined by typing a frequency value in the field. In case the oscillator is referenced to an external source, the Mode indicator will show ExtRef and the frequency field is set to read-only. External reference requires a PLL to do the frequency mapping onto an internal oscillator. Successful locking is indicated by a green light right next to the frequency field.

In the following, we discuss the Demodulators settings in more detail. 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 without MF-MD Multi-demodulator option.

The first line in the Demodulators section represents the demodulator available for measurements. The Mode column is read-only set to internal reference (Demod). The second line represents an additional Demodulator that is reserved for the exclusive use as a phase detector when the mode is switched to external reference (ExtRef). The user can select from a number of different inputs to be used as external reference signals and the filter settings provide the user with an idea of the PLL speed. However, this second demodulator does not produce any output data that could be used for measurements. In the Input Signal column one defines the signal that is taken as input for a given demodulator. A wide choice of signals can be selected: Signal Inputs, the Trigger Inputs, the Auxiliary Inputs and Auxiliary Outputs. This allows using the instrument for many different measurement topologies. For each demodulator an additional phase shift can be introduced to the associated oscillator by entering the phase offset in the Phase column. This phase is added both to the reference channel and to the output of the demodulator. Hence, when the frequency is generated and detected using the same demodulator, signal phase and reference phase change by the same amount and no change will be visible in the demodulation result. Demodulation of frequencies that are integer multiples of any of the oscillator frequencies is achieved by entering the desired factor in the Harm column. The result of the demodulation, i.e. the amplitude and phase can be read e.g. using the Numeric tab which is described in Numeric Tab.

In the middle of the Lock-in tab is the Low-Pass Filters section where the filter order can be selected in the drop-down list for each demodulator 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 by clicking on the column’s header. 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 demodulation frequency, the demodulator output may contain frequency components at the frequency of demodulation and its higher harmonics. In this case, the additional Sinc Filter should be enabled. It attenuates those unwanted harmonic components in the demodulator output. The Sinc Filter is useful when measuring at low frequencies, since it allows one to apply a Low-Pass Filter bandwidth closer to the demodulation frequency, thus speeding up the measurement time.

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

The Trigger section next to the Data Transfer allows for setting trigger conditions in order to control and initiate data transfer from the Instrument to the host PC by the application of logic signals (e.g. TTL) to either Trigger Input 1 or 2 on the instrument back panel.

In the Signal Outputs section the On buttons are used to activate the Signal Output. The Range drop-down list is used to select the proper output range setting. On the Signal Output an offset voltage (Offset) can be defined. The maximum output signal permitted is +- V.

Block Diagram

The block diagram view of the main instrument functions is also sometimes called the "Graphical Lock-in Tab". A set of indexed side tabs in the Lock-in Tab give access to a block diagram for each demodulator. The block diagrams are fully functional and provide the user with a visual feedback of what is going on inside the instrument. All control elements that are available in the Parameter Table detailed in the previous section are also present in the graphical representation.

The block diagram in Figure 3 shows the signal path through the instrument for the case when the internal oscillator is used as reference. The Signal Inputs and Reference/Internal Frequency are shown on the left-hand side. The actual demodulation, i.e. the mixing and low-pass filtering is represented in the center of the tab. On the bottom right the user can set Signal Output parameters. On the top right there are the settings related to the output of the measurement data, either by digital means (PC Data Transfer) or by analog means (Auxiliary Outputs 1 to 4).

Figure 3: LabOne User Interface Lock-in tab - Graphical Lock-in tab in Internal Reference mode

The block diagram in Figure 4 shows the signal path through the instrument for the case when an external reference is used. This setting is only available for demodulator 2. In order to map an external frequency to oscillator 1 go to the Reference section of demodulator 2 and change the mode to ExtRef. This demodulator will then be used as a phase detector within the phase locked loop. The software will choose the appropriate filter settings according to the frequency and properties of the reference signal. Once demodulator 2 is used to map an external frequency on to one of the internal oscillators, it is no longer available for other measurements.

Figure 4: LabOne User Interface Lock-in tab - Graphical Lock-in tab in External Reference mode

Functional Elements

Table 2: Lock-in tab
Control/Tool Option/Range Description
Range 3.0 mV, 10 mV, 30 mV, 100 mV, 300 mV, 1 V, 3.0 V 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.
On ON / OFF Enable Signal Input.
Auto Automatic adjustment of the Range to about two times the maximum signal input amplitude measured over about 100 ms.
Scaling numeric value Applies an arbitrary scale factor to the input signal.
Measurement Unit unit acronym Defines the physical unit of the input signal. Use *, / and ^ operators, e.g., m or m/s^2.

The value in this field modifies the readout of all measurement tools in the user interface. Typical uses of this field is to make measurements in the unit before the sensor/transducer, e.g. to take an transimpedance amplifier into account and to directly read results in Ampere instead of Volts.
Coupling OFF: DC coupling Defines the input coupling for the Signal Inputs. AC coupling inserts a high-pass filter.
ON: AC coupling
50 Ω OFF: 10 MΩ Switches between 50 Ω (ON) and 10 MΩ (OFF).
ON: 50 Ω
Diff ON: Differential voltage input Switches between single ended (OFF) and differential (ON) measurements.
OFF: Single ended voltage input
Float OFF: GND connected Switches between floating (ON) and connected grounds (OFF). This setting applies both to the voltage and the current input. It is recommended to discharge the test device before connecting or to enable this setting only after the signal source has been connected to the Signal Input in grounded mode.
ON: Floating
Range 10 mA Defines the gain of the current 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. Ranges marked with an asterisk (*) are only available on instruments with serial numbers MF-DEV3200 and higher.
1 nA (*)
10 nA
100 nA (*)
1 µA
10 µA (*)
100 µA
1 mA (*)
Auto Automatic adjustment of the Range to about two times the maximum current input amplitude measured over about 100 ms.
Scaling numeric value Applies an arbitrary scale factor to the current input.
Measurement Unit unit acronym Defines the physical unit of the current input. Use *, / and ^ operators, e.g., m or m/s^2

The value in this field modifies the readout of all measurement tools in the user interface.
Mode Indicates how the frequency of the corresponding oscillator is controlled (manual, external reference). Read only flag.
Manual The user setting defines the oscillator frequency.
ExtRef An external reference is mapped onto the oscillator frequency.
Frequency (Hz) 0 to 5 MHz 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.
ExtRef Low BW The demodulator is used for external reference mode and tracks the frequency of the selected reference input. The demodulator bandwidth is fixed at low value. Use when automatic bandwidth adjustment interferes with a stable lock at a fixed frequency.
ExtRef High BW The demodulator is used for external reference mode and tracks the frequency of the selected reference input. The demodulator bandwidth is fixed at a high value. Use when automatic bandwidth adjustment interferes with tracking a strongly fluctuating frequency.
PLL The demodulator is used in PLL mode for frequency tracking of the signal. This function requires the MF-PID option.
IA The demodulator is used by the impedance analyzer.
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.

If the demodulator is used as a phase detector in external reference mode (PLL), the effect is that the internal oscillator locks to the external frequency divided by the integer factor.
Harm 1 to 1023 Divides the demodulator's reference frequency by an integer factor in external reference mode.
Demod Freq (Hz) 0 to 5 MHz Indicates the frequency used for demodulation and for output generation.

The demodulation frequency is calculated with oscillator frequency times the harmonic factor. When the MF-MOD option is used linear combinations of oscillator frequencies including the harmonic factors define the demodulation frequencies.
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 1 Signal Input 1 is connected to the corresponding demodulator.
Curr In 1 Current Input 1 is connected to the corresponding demodulator.
Trigger 1 Trigger 1 is connected to the corresponding demodulator.
Trigger 2 Trigger 2 is connected to the corresponding demodulator.
Aux Out 1 Internal value of Auxiliary Output 1 is applied to the input of the corresponding demodulator.
Aux Out 2 Internal value of Auxiliary Output 2 is applied to the input of the corresponding demodulator.
Aux Out 3 Internal value of Auxiliary Output 3 is applied to the input of the corresponding demodulator.
Aux Out 4 Internal value of Auxiliary Output 4 is applied to the input of the corresponding demodulator.
Aux In 1 Auxiliary Input 1 is connected to the corresponding demodulator.
Aux In 2 Auxiliary Input 2 is connected to the corresponding demodulator.
Constant Demodulate a constant input. This results in a sine wave of the frequency specified by the demodulator's oscillator with an amplitude of 1 (at lower frequencies; higher frequencies will be attenuated). The maximum possible frequency is limited by the demodulator sampling rate and bandwidth; use demodulator order 1 for the least attenuation in demodulator output. This signal may be used with the auxiliary outputs, PID and Threshold Unit for advanced measurement and control tasks. When the demodulator output is written to an auxiliary output, the resulting signal can also be used as a second output channel (for low frequencies).
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
5 5th order filter 30 dB/oct
6 6th order filter 36 dB/oct
7 7th order filter 42 dB/oct
8 8th order filter 48 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) 0.056 Sa/s to 857 kSa/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.
Trigger Selects the acquisition mode of demodulated samples. Continuous trigger means data are streamed to the host computer at the Rate indicated.
Continuous Selects continuous data acquisition mode. The demodulated samples are streamed to the host computer at the Rate indicated on the left hand side. In continuous mode the numerical and plotter tools are continuously receiving and display new values.
Trigger 1 Selects external triggering by means of the Trigger 1 connector. Demodulated samples are sent to the host computer for each event defined in the Trig Mode field. When edge trigger is selected the rate field is greyed out and has no meaning.
Trigger 2 Selects external triggering by means of the Trigger 2 connector. Demodulated samples are sent to the host computer for each event defined in the Trig Mode field. When edge trigger is selected the rate field is greyed out and has no meaning.
Trigger 1\|2 Same functionality as above, but triggering is based on a logical OR function of Trigger 1 and Trigger 2.
Trigger Mode Defines the edge or level trigger mode for the selected Trigger input. Note: this field only appears when a non-continuous trigger is selected in the Trigger field.
Rising Selects triggered sample acquisition mode on rising edge of the selected Trigger input.
Falling Selects triggered sample acquisition mode on falling edge of the selected Trigger input.
Both Selects triggered sample acquisition mode on both edges of the selected Trigger input.
High Selects continuous sample acquisition mode on high level of the selected Trigger input. In this selection, the sample rate field determines the frequency in which demodulated samples are sent to the host computer.
Low Selects continuous sample acquisition mode on low level of the selected Trigger input. In this selection, the sample rate field determines the frequency in which demodulated samples are sent to the host computer.
Amplitude Unit Vpk, Vrms, dBm Select the unit of the displayed amplitude value. The dBm value is only valid for a system with 50 Ω termination.
Amplitude Mode Indicates the type or source of the waveform being generated. 'Sine' indicates a sinusoidal waveform from the internal oscillator.
Amplitude Enable ON / OFF Enables individual output signal amplitude.

When the MF-MD option is used, it is possible to generate signals being the linear combination of the available demodulator frequencies.
On ON / OFF Main switch for the Signal Output corresponding to the blue LED indicator on the instrument front panel.
50Ω ON / OFF Select the load impedance between 50Ω and HiZ. The impedance of the output is always 50Ω. For a load impedance of 50Ω the displayed voltage is half the output voltage to reflect the voltage seen at the load.
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.
10 mV Selects output range ±10 mV.
100 mV Selects output range ±100 mV.
1 V Selects output range ±1 V.
10 V Selects output range ±10 V.
Auto Range Selects the most suited output range automatically.
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.
Add ON / OFF The signal supplied to the Aux Input 1 is added to the signal output. For differential output the added signal is a common mode offset.
Diff ON / OFF Switch between single-ended output (OFF) and differential output (ON). In differential mode the signal swing is defined between Signal Output +V / -V.
Output -range to range Defines the output amplitude as rms or peak-to-peak value. A negative amplitude value is equivalent to a phase change of 180 degree.