Pico Technology

Introduction

1. Brief description:
A plastic optical fibre is attached to a (cantilever) beam to monitor its deflection. The change in the light intensity of the optical fibre is monitored using a light dependant resistor (LDR) and a basic voltage divider circuit. The output of the LDR is continuously measured by the ADC-16 and this simple system is able to provide real-time beam deflection monitoring with a PC.

2. What the experiment is trying to teach
The experiment highlights the potential use of an optical fibre as a sensor for monitoring, in real-time, the deflection of a structure. Students will also gain practical experience in building up a basic electrical circuit based on simple devices such a light dependant resistor (LDR), reading resistor values, principle of voltage dividers and Ohm's law.

3. Prior knowledge required:
Students need to have an idea of how an optical fibre transmit light through its core and the principle of total internal reflection (TIR) and the effect of excessive bending on the light transmission in these light-guiding medium. Secondly, students should have some appreciation of the function of a light-dependent resistor, the principles of voltage dividers and Ohm's law.

4. Target group
This experiment is suitable for students taking Advanced Physics and serves as a simple introduction to the practical use of optical, electronic and optoelectronic devices.

Equipment required

• Data logging equipment e.g. ADC16 from Pico Technology Ltd
• Light dependant resistor (LDR), Light emitting diode (LED)
• 1kOhm resistor
• Soldering iron
• A voltage/signal amplifier (optional)
• 2x 1.5 V batteries (to power LED) and 2x9V batteries (for divider circuit)
• Optical fibre connectors (SMA multimode type connectors)
• Optical fibre sensor
• A flexible beam (e.g. a plastic ruler)
• Fast-curing adhesive

Safety warning: Although it is generally safe to work with most low-power LEDs, for safety reasons, do not look directly into the LED when illuminated. Soldering iron should only be used under supervision.

Experiment Setup

Figure 1 shows the experimental set-up for the experiment.

figure 1: Experimental set up

Voltage divider circuit (within the Basic Circuitry in Figure 1)

The experimental arrangements for both the three-point bend and tensile tests are shown in Figure 4. A standard voltage supply was used to power the light emitting diode The detector and data acquisition system consisted of a light-dependent resistor (LDR) and a low cost commercial data acquisition system from Pico Technology which automatically records voltage changes across the LDR as the light intensity varies. The data acquisition system offers up to a 16 bit-resolution analogue to digital conversion (ADC) with up to 8 input channels. The resolution of the ADC system allows for the detection of voltage changes as small as 40 mV in electrical signal. A sampling rate of 2 data samples per second will be sufficient for the purpose of the experiment. The data from the optical fibre were automatically collected by the computer and displayed graphically in real-time

A schematic of the beam with the bonded optical fibre sensor is shown in Figure 2. Details will be given in the following section.

Figure 2 Schematic of beam specimen with bonded optical fibre sensor

When the experiment is properly set-up, the beam should flex about its centre with a load applied at the centre of the supports, as shown in Figure 3.

Figure 3 properly set up beam

where W is the applied load, d_ctr is the central deflection.

Carrying out the experiment

1. Attach the optical fibre sensor to the beam (e.g. plastic ruler) using superglue or other available adhesive and wait for it to dry. Ensure that the bond is secure and that the sensor does not de-bond when the beam specimen is flexed.
2. Connect the optical connectors to both ends of the optical fibre and couple them to the LED and LDR respectively. Ensure they are securly coupled to minimise any unwanted changes in the voltage signal due to loss in the coupling and environmental noise.
3. Carefully put the beam on to the supports. The beam can also be secured on one end and free the other end as in a cantilever beam set-up as an alternative support system to the one shown.
4. Check that there is voltage output reading by PicoLog to ensure that the set-up is correct and ready for the beam deflection test to begin.
5. Adjust the scale of the Y-axis of the graph in PicoLog to obtain an optimum display. If you have a signal amplifier, you can also adjust the voltage level sent to the ADC.
6. Apply a small deflection on the beam slowly and observe the change in the voltage level displayed by PicoLog. Did the signal increases or decreases when the deflection was applied? Depending on the sensitivity of the fibre, you can expect a change in the voltage of at least 100mV for a deflection of 10mm using the set-up shown.
7. Now release the deflection and observe the change in the voltage level as indicated by PicoLog. What happens to the signal? Does the signal return back to the initial signal value?
8. Now try with different amounts of deflection and observe the changes in the voltage signal. What do you observed?

Questions

1. Can you explain how the circuity works to give a proportional signal output when the light intensity of the optical fibre sensor changes?
2. What do you think will happen to the voltage signal if the beam is deflected upwards instead of downwards as previously done?

Further study

Dynamic monitoring using optical fibre sensors:
An important aspect in monitoring real-life engineering structures involve performing dynamic analyses of vibrating structures. Optical fibre sensors based on the above system represent a cost effective method to monitor a dynamic system. As a further study, the beam used in the above experiment may be subjected to a continuous deflection using a cam attached to a motor, providing a constant rate of deflection to the beam while monitoring the output signal of the optical fibre. Other types of ADC supplied by Pico Technology Ltd. may be more appropriate for dynamic monitoring. Contact Pico Technology for advice.

Results