Difference between revisions of "Instrumentation"

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*Making plots in Python
 
*Making plots in Python
  
The students are taken through each section with example codes which they are supposed to run. At the end of the exercise, students are given some tasks in these areas to undertake and present their findings. The complete manual for this lab is available at[[Media:Instrumentation_Lab1.pdf|#REDIRECT]]  
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The students are taken through each section with example codes which they are supposed to run. At the end of the exercise, students are given some tasks in these areas to undertake and present their findings. The complete manual for this lab is available at [[Media:Instrumentation_Lab1.pdf|Instrumentation Lab1.pdf]]
  
  

Revision as of 15:21, 26 October 2015

Instrumentation

This course is taught in the third year of the electrical engineering curriculum. The course mainly deals with

  • Transducers for non-electrical quantities .
  • Signal conditioning
  • Remote sensing techniques
  •  Microprocessor applications in instrumentation
  •  Noise and interference reduction
  • Data storage, recording and display systems. 

We aimed to develop a laboratory exercise that will introduce  equip the students with relevant skills in transducers and their applications, to signal conditioning and remote sensing and data storage.

Three labs are  have been development as follows

Introduction to Python Prgramming

The aim of this laboratory practice is to Introduce the student to programming in Python and equip the students with important skills in programming with Python to be used later in proceeding labs. Python is a very high level language. The Raspberry PI was actually developed to run Python as its programming platform, hence the term PI in the name Raspberry PI. The lab explores a bit of programming syntax used in Python.  Key areas captured in this lab are

  • Entering variables in Python
  • Common Arithmetic 
  • Vectors and Matrices
  • Flow Control
  • Functions in Python
  • Making plots in Python

The students are taken through each section with example codes which they are supposed to run. At the end of the exercise, students are given some tasks in these areas to undertake and present their findings. The complete manual for this lab is available at Instrumentation Lab1.pdf



Analog to Digital Conversion

Most of signals from sensros are analogue in form. Raspberry Pi being a microprocessor based systems handles only digital signals. It has no inbuild analogue to digital             converter. This necessitates for development of an analogue to digital converter in instrumentation.

MCP3008 analogue to digital converter chip is used in this work. It is a 10 bit, 8 channel IC as shown in the schematic. A variable resistor is used as the source of the analogue signal and is connected to 5 V source. The analogue input (0 to 5 V) is fed to one of the 8 channels of the MCP3008. Other connections to be made are described in the lab manual  [[Media:adc.pdf|(see pdf) provided]] for this lab.

By adjusting the variable resistor, different values of analog voltages are used for testing the converter. The output (digital equivalent in decimal form) is displayed on the monitor

The setup and sample results for this lab are shown below

ADC setup  ADC sample result 1  ADC sample result 2


Real-time Remote Force Measurement and Recording
Telemetry is important in instrumentation as it enables collection of data from several measurement points at inconvenient locations or inaccessible areas transmit that data to a convenient location and present the several individual measurements in a usable form.

The stain gauge on the principle that a resistance of a wire of a semiconductor is changed by elongation or compression due to externally applied stress. It is commonly used in the measurement of force , torque and displacement. The output signal of the strain gauge requires amplification and AD620 (operational amplifier) chip has been used for this purpose.

After amplification, the signal is converted to digital form using similar procedure in lab 1 described above.  WiFi network is used for transmission of the digital output from the remote location to the central control room. At the receiver side, data is first displayed on the monitor for purpose of real time monitoring. Its later stored in a database developed using mySQL.

The procedure to be used is detailed in the lab manual [[RTECOLONmedia:instrumentation_manual|(see pdf)]] provided for this lab. Two weights (0.5 kg and 0.25 kg) are used for testing the system. The setup and sample results are shown below



Inst setup.jpg            Half kg weight           Half kg weight results