Te Ldm-1000 User manual

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

Page 1

OPERATION MANUAL

LDM-1000

LVDT/RVDT Signal Conditioning Module

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

Page 2

Table of Contents

1. Introduction ......................................................................................................................................................3

2. Product Specifications ....................................................................................................................................3

3. Product Description.........................................................................................................................................4

4. Initial Setup Procedure....................................................................................................................................4

4. 1. Supply Voltage .............................................................................................................................................5

4. 2. Internal Switches ..........................................................................................................................................6

4. 3. Oscillator Frequency: ...................................................................................................................................6

4. 4. Oscillator ‘Sync’ Mode..................................................................................................................................7

4. 5. Oscillator Drive Capability ............................................................................................................................7

4. 6. Setting the Amplifier Gain ............................................................................................................................7

5. Dimensions and Wiring Terminals .................................................................................................................8

6. Connection Diagrams......................................................................................................................................9

7. Calibration Procedure .................................................................................................................................. 10

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

Page 3

1. Introduction

The LDM-1000 is an extremely versatile LVDT/RVDT (Linear or Rotary Variable Differential Transformer) signal conditioning

module. The module supplies an AC sine wave excitation to the LVDT or RVDT, and demodulates, filters, and amplifies the

output. It is the perfect choice for industrial applications requiring the DIN standard rail mount.

2. Product Specifications

For complete specifications and ordering information, please refer to the datasheet at:

http://www.te.com/usa-en/product-CAT-PSI0003.html

ELECTRICAL SPECIFICATIONS

Supply voltage

18 to 30VDC or 10 to 18VDC (jumper selectable, 18 to 30VDC as shipped)

Supply current

65mA maximum

Output types and ranges

±5VDC, 0 to 5VDC, 0 to 10VDC, and 4~20mA (DIP switch selectable, ±5VDC as shipped)

Temp. coefficient of output

±0.02% of FSO per °F [±0.036% of FSO per °C] over the operating temperature range

Voltage output noise/ripple

5mV RMS maximum

Current output noise/ripple

25µA RMS maximum

Current loop resistance

700Ω maximum (with 18 to 30VDC supply voltage)

Frequency response

250 or 1000Hz @ -3 dB (3-pole Butterworth, DIP switch selectable, 250Hz as shipped)

Non-linearity

±0.02% of FSO

Input sensitivity range

0.05 to 2.50 VRMS

Transducer excitation

Voltage

1 or 3 VRMS (DIP switch selectable; 3VRMS as shipped, with 18 to 30VDC supply

voltage only)

Current

25mA RMS

Frequency

2.5, 5 or 10kHz (DIP switch selectable, 2.5kHz as shipped)

Transducer requirements

Transducer type

LVDT or RVDT with 4, 5 or 6 electrical connections

LVDT/RVDT input impedance

50Ω minimum @ 1 VRMS excitation ; 150Ω minimum @ 3 VRMS

LVDT/RVDT full scale output

0.05 to 2.50 VRMS

ENVIRONMENTAL AND MECHANICAL SPECIFICATIONS

Operating temperature range

-13°F to +185°F [-25°C to +85°C]

Storage temperature range

-67°F to +257°F [-55°C to +125°C]

Mounting

Standard DIN-3 rail mount

Size

3.90 [99.0] high x 0.89 [22.5] wide x 4.51 [114.5] Deep

Wire terminal size

24 to 12 AWG [0.2 to 2.5mm]

IEC 60529 rating

IP60

Notes:

All values are nominal unless otherwise noted; dimensions are in inch [mm]

FSO (Full Scale Output) is the largest absolute value of the outputs measured at the range ends.

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

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3. Product Description

DIP switches are provided to allow selection of three transducer excitation frequencies (2.5, 5 and 10 kHz), two signal bandwidths

(250 or 1,000 Hertz), and two excitation voltages (1 or 3 Volts RMS). Switches are also provided to select seven coarse gain

ranges, three DC output voltage ranges, two offsets, and master/slave operation. The 4 to 20mA output will operate regardless

of the DC output voltage dip switch settings.

Three multi-turn potentiometers located on the front panel allow precise gain (SPAN), offset (ZERO) and phase shift (PHASE)

adjustments.

An internal jumper allows changing the input voltage range from 18~30 VDC to 10~18 VDC.

A green LED on the front panel lights up when the LDM-1000 is powered on. A second green LED light indicates that the loop

current is flowing.

The LDM-1000 is designed to be mounted to a standard number 3 DIN rail. Input/output connections are made through plug-in

screw terminal barrier strips. These plug-in strips are keyed to prevent improper connections in the unlikely event that the LDM-

1000 should require field replacement.

The next few pages will take you, step by step, through the simple set-up and calibration process. This device may be set-up for

several different full scale analog outputs; some of the potential configurations are listed below:

±5 VDC output

0 to 5 VDC output

0 to 10 VDC output

4 to 20mA DC output

Standalone and Master/Slave operation

4. Initial Setup Procedure

To properly configure the LDM-1000 for the LVDT or RVDT you are using, you must access the internal dip switches. To open

the housing, depress the two latches with a screwdriver (see photos below); the housing will spring open. You can slide the front

panel and PC board assembly forward approximately 1.6 inch (4cm) to access the dip switches and input voltage jumper. A

spring stop prevents the PCB from being removed completely.

In order to begin the setup process, you must first know a few basic characteristics about the LVDT or RVDT you intend to use

with the LDM-1000. The information may be obtained from the transducer calibration sheet, catalog literature, or the TE web

site at: http://www.te.com/usa-en/products/sensors/position-sensors/linear-position-sensors-lvdt-lvit.html?tab=pgp-story

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

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The list below is the minimum information required to perform a successful calibration:

Recommended LVDT or RVDT excitation frequency (to set the oscillator frequency)

LVDT or RVDT Output sensitivity at the excitation frequency (to set the gain)

Primary (input) impedance at the excitation frequency (to set the oscillator output voltage)

The ± full scale linear or angular range over which you intend to perform the calibration

Analog output signal required by your application

4. 1. Supply Voltage

The LDM-1000 supply voltage range is 18~30 VDC with the JP1 jumper in the storage position (as shipped position). Only this

range (18~30VDC) can be used for 4-20mA output operation. The operating voltage may be changed to 10~18 VDC by installing

internal jumper JP1 across both pins. See the diagrams below for jumper settings.

CAUTION: Operating the unit at voltages above +18 volts with the jumper in the low voltage position will overheat

the internal voltage regulators and reduce the operational life of the LDM-1000.

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

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4. 2. Internal Switches

There are two internal DIP switch sets (SW1 and SW2) on the PC board assembly of the LDM-1000. The tables below explain

the switch positions and functions.

Switch Set SW1

Function:

Offset

Signal Bandwidth

Gain 2

Gain 1

Switch No:

Switch ON:

Positive

Negative

1 kHz

LOW

Switch position

Gain

Switch OFF:

None

250 HZ

HIGH

Note: Switches 3, 4 & 5 must be

in same position

OFF

x0.4

OFF

x1.2

Note: The 1 kHz bandwidth setting is not recommended for excitation frequencies other than

10 kHz, otherwise significant noise will be present on the output signal.

OFF

x3.63

x4.43

Switch Set SW2

Function:

Oscillator Frequency

Sync

Osc. V

Output Range VDC

Switch No:

Frequency

Switch Position

Switch ON:

INT

1 VRMS

0~5

±5

0~10

10 kHz

Switch OFF:

EXT

3 VRMS

Only one switch ON

5 kHz

OFF

4 to 20mA output works

with any setting

2.5 kHz

OFF

Notes: Default factory settings are noted in BLUE in the above tables. Switch No. 5 of SW2 is not used. 3VRMS excitation is

available only with the 18~30VDC supply voltage setting.

4. 3. Oscillator Frequency:

Once you have established the proper excitation frequency for your transducer, refer to the tables below to set the oscillator.

For 2.5 KHz excitation (default factory setting):

Switch Set SW2

Switch Set SW1

Function:

Oscillator Frequency

Function:

Signal Bandwidth

Switch No:

2.5kHz

OFF

250 HZ

OFF

For 5 KHz excitation:

Switch Set SW2

Switch Set SW1

Function:

Oscillator Frequency

Function:

Signal Bandwidth

Switch No:

5kHz

OFF

250 HZ

OFF

For 10 KHz excitation:

Switch Set SW2

Switch Set SW1

Function:

Oscillator Frequency

Function:

Signal Bandwidth

Switch No:

10 kHz

1 kHz

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

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4. 4. Oscillator ‘Sync’ Mode

The Oscillator ‘Sync’ mode setting will depend on the number of LDM-1000’s and transducers in your system, and their physical

locations. For a single LVDT or RVDT system you will be running the LDM-1000 in the Master (INT) mode. For systems with

multiple LDM-1000’s, especially when they are co-located, and/or the interconnect cables between the LDM-1000’s and the

transducers run identical paths, it is recommended to Master and Slave the LDM-1000 oscillators to prevent beat frequencies

and crosstalk between amplifiers and transducers. You will be selecting one LDM-1000 to serve as the Master oscillator (INT),

and the balance will be set-up in the Slave mode (EXT).

CAUTION: Attempting to synchronize two LDM-1000 set as masters (factory default setting) may damage one or both

units. Only one unit can be set to Master mode (INT, SW2 Switch 3 ON), otherwise damage to the electronics may result

(See connection diagrams). All other units must be in the Slave mode (EXT, SW2 Switch 3 OFF).

Connecting Pins 11 (Sync OUT) and 12 (Sync COM) of the barrier strip, from unit to unit, will complete the sync bus circuit (See

connection diagrams). The power common serves as the return line. Use the table below to configure your oscillator mode:

SW2-3

Mode

OFF

SLAVE

MASTER

4. 5. Oscillator Drive Capability

To ensure LVDT/RVDT compatibility with the LDM-1000 you must know the transducer current draw. The LDM-1000 is designed

with a robust sine wave oscillator; it is rated for a maximum drive current of 25mA RMS with a voltage amplitude of 1 or 3 VRMS.

Therefore, you will need to know the LVDT/RVDT transducer input impedance for the frequency at which you intend to operate

it. With the (factory default) 3 VRMS oscillator voltage, the transducer input impedance must be equal to or greater than 120

Ohms, which will result in current draw of 25mA or less. If the impedance of the transducer is lower, the 1 VRMS setting must

be selected; with this setting, the LDM-1000 will be able to operate with impedances as low as 40 Ohms. The input impedance

information is available on the datasheets for all MEAS LVDTs and RVDTs.

4. 6. Setting the Amplifier Gain

You will need to calculate the LVDT or RVDT full scale output, using the simple formula below:

LVDT/RVDT sensitivity (in V/V/inch or V/V/degree), at the selected frequency, multiplied with

the excitation voltage, (1 or 3 VRMS for the LDM-1000), multiplied with

the full scale of the LVDT in inches (or RVDT in degrees).

As an example, the calculation for a MEAS HR1000 LVDT (±1 inch range; 1 inch full scale), with a sensitivity of 0.39V/V/inch at

2.5KHZ, with 3 VRMS excitation would be done as follows:

0.39 x 3 x 1 = 1.17 VRMS full scale output or 1.17 VRMS at ± 1 inch

Using the table below, select the gain settings (switch numbers 6, 7 and 8 of SW1) for the range your full scale output falls into.

In our example, you would use x0.4 HIGH.

Gain 1

Gain 2

LVDT Full Scale

Output, VRMS

Gain

SW1-7

SW1-8

Gain Lo/Hi

SW1-6

x0.4

OFF

LOW

1.20 to 2.50

x0.4

OFF

HIGH

OFF

0.78 to 1.20

x1.2

OFF

LOW

0.40 to 0.78

x1.2

OFF

HIGH

OFF

0.26 to 0.40

x3.63

OFF

LOW

0.13 to 0.26

x3.63

OFF

HIGH

OFF

0.10 to 0.13

x4.43

HIGH

OFF

0.05 to 0.10

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

Page 8

5. Dimensions and Wiring Terminals

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

Page 9

6. Connection Diagrams

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

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7. Calibration Procedure

Using the P1 and P2 terminal blocks according to the “Connection Diagrams” section of this manual, connect the LVDT or RVDT,

a DC voltmeter, and a power supply (see “Supply Voltage” under the “Initial Setup Procedure” section of this manual) to the

LDM-1000. Turn the power on and allow a 15 minute warm-up. Follow the procedure below:

1. Disconnect the LVDT/RVDT primary wire from Terminal 1 of P1.

2. Adjust the ZERO potentiometer on the front panel until:

the DC voltage output between terminals 9 (SIGNAL COM) and 10 (SIGNAL OUT), or

the DC current between terminals 15 (CURRENT COM) and 16 (CURRENT OUT)

reads in the middle of the range (see “Internal Switches” under the “Initial Setup Procedure” section of this manual for

output DC voltage range selection).

Note: The middle of the range is as follows:

0.0 VDC mid-range reading for ± 5 VDC Output

2.5 VDC mid-range reading for 0 to +5 VDC output

5.0 VDC mid-range reading for 0 to +10 VDC output

12.0mA mid-range reading for 4 to 20mA output

2. Reconnect the LVDT/RVDT primary wire to Terminal 1 or P1. Insert the LVDT core into the middle of the bore, or rotate

the RVDT shaft to the approximate center of the mechanical range, until the output reads as close to the mid-range DC

voltage or current as possible (see mid-range readings in Step 2. above). If this adjustment is mechanically difficult or

impractical, approximate the correct position as closely as possible, and then adjust the ZERO potentiometer until the

output reads the middle of the range (see mid-range readings in Step 2. above).

Note: Changing course gain settings (DIP switches) after this step may result in a zero shift. Should you find it necessary

to change the gain, you should repeat steps 1 through 3.

3. Displace the core of the LVDT or rotate the RVDT shaft in a positive direction (increasing DC voltage between terminals

9 and 10 or increasing DC current between 15 and 16) to approximately 80% of the full scale position you used in your

calculation in “Setting the Amplifier Gain”.

4. Adjust the front panel PHASE potentiometer in the direction that increases the DC output signal until the maximum

output is reached; if the output does not peak and the PHASE potentiometer is at the end of its adjustment range, leave

it there and continue the calibration procedure.

Note: If during the phase adjustment the output exceeds the maximum limit of the selected range, reduce the output

back to a 70-80% level by adjusting the front panel SPAN potentiometer, then continue with the phase adjust operation.

5. Return the LVDT core or the RVDT shaft back to the original center position. If the exact same mid-range DC output

as in Step 2 above is not observed, slightly re-adjust of the ZERO potentiometer.

6. Using a precision positioning device, displace the LVDT core or rotate the RVDT shaft in a positive direction to the full

scale position used in your calculation.

Note: The calibration can be made over a percentage of full scale by moving the core xx% of full scale and adjusting

the output for the same percentage.

7. Adjust the front panel SPAN potentiometer for the required positive full scale DC output (usually the maximum output

limit of the selected range, in Step 2 above).

Note: If the required full-scale reading cannot be obtained by adjusting the SPAN potentiometer, the gain of the signal

conditioner can be reset by changing the internal switches (see the “Setting the Amplifier Gain” section): If the SPAN

potentiometer is fully counter clockwise, change to the next higher gain. If the SPAN potentiometer is fully clockwise,

change to the next lower gain.

8. Return the LVDT core or the RVDT shaft back to the original center position and re-check the output reading (should

be the same mid-range reading as in Step 2 above). If needed, use the ZERO potentiometer to make a small

adjustment.

9. Displace the LVDT core or rotate the RVDT shaft to the negative full scale position (lowest output DC voltage or current);

it should match the minimum reading for the range selected in Step 2 above. If needed, use the SPAN potentiometer

to make a small adjustment

Note: Due to symmetry errors of all LVDTs and RVDTs, the exact minimum and maximum output readings are rarely

obtained.

LDM-1000

LVDT/RVDT Signal Conditioning Module

TE CONNECTIVITY SENSORS /// LDM-1000 OPERATION MANUAL P/N 09290100-000 REV. C 05/2016

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