Scitec 441,430 User Manual

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

MODEL 441 ANALOG OEM

DUAL PHASE LOCK-IN AMPLIFIER

&

MODEL 430 ANALOG OEM

SINGLE PHASE LOCK-IN AMPLIFIER

USER MANUAL V1.2

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

CONTENTS

1 POWER SUPPLY

1.1 Power Connections

1.2 Earth Connections for High Voltage / E S D Protect ion

2 BOARD LAYOUT
3 OPERATION

3.1 Block Diagrams

3.2 Lock-in Amplifier Theory

4 INPUT STAGE

4.1 Jumper Settings Overview

4.2 Single Ended DC Coupled Input

4.3 Single Ended AC Coupled Input

4.4 Single Ended Current Input

4.5 Differential Input

4.6 Low Impedance Differential Input

5 FIRST STAGE AMPLIFICATION
6 LOW PASS FILTER TIME CONSTANT SETTINGS

6.1 First Time Constant Settings

6.2 Second Time Constant Settings

7 OUTPUT STAGE

7.1 Output Stage Amplification

7.2 Fine Gain Adjust

7.3 Offset Adjust

7.4 R Calculation

7.5 R Calculati on Time Constant

8 REFERENCE SECTION

8.1 Fine Phase Control

8.2 Coarse Phase Control and 1F/2F Operation

9 OVERALL SYSTEM GAIN AND DYNAMIC RESERVE

9.1 Dynamic Reserve

9.2 Maximum Signal Size Up To The Low Pass Filter

9.3 Maximum Signal Size From Low Pass Filter to Output

9.4 Example Gain Settings

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

1 POWER SUPPLY

1.1 Power Connections

A well regulated ±15V & +5V supply is required to power the lock-in amplifier board. 50mA
per supply is required for the 441 and 35mA per supply are required for the 430. Power is
supplied via a 64 pin type C DIN41612 connector as follows:

0V Pin 32A & Pin 32C

+5V Pin 31A & Pin 31C

+15V Pin 30C

-15V Pin 30A

No other pins on the DIN41612 connector are used.

Please note that the pin numbers are labelled on the back of the connector next to the solder
pins and as per Figure 1. Please also note that some connectors have P1~A on the front face.
Rather confusingly, this A is actually next to row C pins.

Figure 1 Power Connections

1.2 Earth Connections for High Voltage / ESD Protection

As lock-in amplifiers are often used in optics applications with lasers driven by high voltage
power supplies, it is sometimes important to protect equipment from high voltage discharges.
Electro-Static Discharge (ESD) protection is also important and is a requirement for CE
marking. All inputs and outputs to the 430 and 441 are protected by transient suppression
devices but for full protection a case earth connection is required directly to the PCB.

To give full protection to the board from high voltages, a thick earth wire should be bonded to
the board at one or other or both of the points shown in Figure 2 and connected to case or
chassis ground by as short a lead as possible. The two links also indicated should be added to
the board. Please note that these earth connections are not connected to signal ground on the
PCB.

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

Figure 2 Case Earth Connections

2 BOARD LAYOUT

The 441 board layout is shown in Figure 3.

L1 Input mode selection jumpers
L2 Input gain select jumpers
L3 Channel X output gain select and time constant jumpers
L4 Channel Y output gain select and time constant jumpers
L5 Reference channel mode select jumpers
VR1 Signal feed thro ugh t rim pot
VR2 Channel X offset adjust trim pot
VR3 Channel X gain adjust trim pot
VR4 Channel Y offset adjust trim pot
VR5 Channel Y gain adjust trim pot
VR6 0° - 150° fine phase adjust trim pot

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Figure 3 441 Board Layout

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

The 430 board layout is shown in Figure 4.

Figure 4 430 Board Layout

L1 Input mode selection jumpers
L2 Input gain select jumpers
L3 Channel X output gain select and time constant jumpers
L5 Reference channel mode select jumpers
VR1 Signal feed thro ugh t rim pot
VR2 Channel X offset adjust trim pot
VR3 Channel X gain adjust trim pot
VR6 0° - 150° fine phase adjust trim pot

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

3 OPERATION

3.1 Block Diagrams

Figure 5 441 Block Diagram

Figure 6 430 Block Diagram

3.2 Lock-in Amplifier Theory

For lock-in amplifier theory please visit a number of pages on the Internet produced by M.
Stachel of Faculty of Physics University of Konstanz Germany. It is available at

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

http://fp.physik.uni-konstanz.de/LockIn/indexx.shtml and includes theory, diagrams and a
virtual Java lock-in amplifier.

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

4 INPUT STAGE

The input stage amplifies the input signal to a level suitable for the demodulator section.

The input signal should be connected to the SMB signal input connector.

The input sensitivity is set by using the input sensitivity jumpers.

The input stage of the unit can operate in a number of ways. By default, the unit is factory set so
that the input stage acts as a single ended DC coupled input as this is the lowest noise method
of operation. It is also possible to operate the input stage in AC coupled mode, differential
mode and current mode. To operate the lock-in in these different modes requires jumpers on the
unit to be modified. This can be achieved as follows:

4.1 Jumper Settings Overview

A simplified input stage circuit diagram is shown in Figure 7. This shows all of the jumpers in
the input stage.

These jumpers are part of jumper block L1.

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com

Figure 7 Input Stage Jumper Options

Bartles Industrial Estate Tel: +44 (0)1209 314 608 scitec@scitec.uk.com
North Street, Redruth Fax: +44 (0)1209 314 609 www.scitec.uk.com
Cornwall TR15 1HR Fax2: +44 (0)870 1600 860

4.2 Single Ended DC Coupled Input

The default setting is for a single ended DC coupled input. This mode gives the best noise
performance. Although the input is DC coupled, the input will not saturate with up to the
following DC offsets on the input:

Input Gain Setting Maximum DC Input Offset Before

x0.001 to x3.3 ±10V

x10 to x100 ±1V

x330 ±300mV

The input impedance of the lock-in in this mode is 1012Ω ||1nF.

The jumper set tings for this mode is given in Figure 8. The equivalent ci rcuit is shown in Figure

9.

Saturation Occurs

Figure 8 Single Ended DC Coupled Input Settings

Figure 9 Single Ended DC Coupled Input Circuit

4.3 Single Ended AC Coupled Input

For applications where large amounts of DC offset are expected on the input, the input stage
can be AC coupled with an RC network. Please note that the high value resistor will add a large
amount of thermal noise to the input. (This mode of operation is common to a lot of other
manufacturer’s lock-in amplifiers. When measuring the input noise of their instruments, it is
standard practice to short the input which has the nice result of removing the thermal noise of
this resistor from their measurements. However, how often do you make measurements with the
input shorted in real life??)

(default setting)

Boston Electronics Corporation, 91 Boylston Street, Brookline MA 02445

(800)347-5445 or (617)566-3821 * fax (617)731-0935 * boselec@boselec.com * www.boselec.com