Figure of Merit of a galvanometer
Here, current will flows through th circuit when key k1 is closed and k2 is open. The current flowing through the galvanometer is proportional to the deflection in it. Where, E - emf f the cell R - resistance from the resistance box
G - galvanometer resistance for current I
θ - galvanometer deflection for current I
k – proportionality constant.When k2 is closed and by adjusting the shunt resistance S, we can make galvanometer deflection as θ/2.Then the current in the circuit is ; Now, a fraction, S/ (G+S) of the current in the circuit is flows through the galvanometer, which is given by, Now, from the above relations, we can get the resistance of the given galvanometer as,
The figure of merit of the given galvanometer, k =---------- Amp / div.
Video of this experiment above
Viva Voice -
1)Why a moving coil galvanometer is called so?None of theseBecause the coil moves while the magnet remains fixed.Because the number of turns of the coil varies with current.Because the coil moves along with the magnet.2)How can you increase the sensitivity of a moving coil galvanometer?By increasing the area of the coilBoth a and cBy increasing the number of turns of the coilBy decreasing the number of turns of the coil3)What is meant by the figure of merit of a galvanometer?Voltage required to produce unit deflection on the galvanometerMaximum deflection on the galvanometerNone of theseCurrent required to produce unit deflection on the galvanometer4)If the current through a galvanometer is, I = Kθ/NAB, then what is the sensitivity of the galvanometer?None of theseS = NAB/KθS = K/NABS = NAB/K5)What is the unit of figure of merit of a galvanometer?AmpereAmpere per meterAmpere per divisionVolt6)Choose the incorrect statement from the following.The resistance of the coil of the galvanometer is called the resistance of the galvanometer.Figure of merit of a galvanometer is the reciprocal of current sensitivity.Galvanometer has positive and negative terminals.Galvanometer deflection is proportional to the amount of current passed through it.7)What is the figure of merit of the galvanometer if current I produce a deflection θ in it?I^2/θIθI/2θI/θ
8)A resistance of 900Ω is connected in series with a galvanometer of resistance 100Ω. A potential difference of 1 V produces 100 division deflections in the galvanometer. Find the figure of merit of the galvanometer?2×10^-5 A/div.0.5×10^-5 A/div.10^-5 A/div.10^-6 A/div.
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Select Resistance:
Large Small
1 2 2
5 10 20
20 50 100
200 200 500
1000 2000 2000
5000 10000 INF
0.1 0.2 0.2
0.5 1 2
2 5 10
20 20 50
100 INF
var expTitle="Ohm's Law"; document.getElementById("expName").innerHTML=expTitle; Developed by Amrita University Under research grant from
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Objective
To determine the resistance of a galvanometer by half deflection method and to find its figure of merit.Theory
Galvanometer
A galvanometer is a device used to detect feeble electric currents in a circuit. It consists of a coil suspended between the poles of a powerful magnet. As current passes through the coil, it deflects. It can be detected from the deflection on galvanometer needle. The deflection is proportional to the current passed through it.Resistance of galvanometer by half deflection method
Here, current will flows through th circuit when key k1 is closed and k2 is open. The current flowing through the galvanometer is proportional to the deflection in it. Where, E - emf f the cell R - resistance from the resistance box
G - galvanometer resistance for current I
θ - galvanometer deflection for current I
k – proportionality constant.When k2 is closed and by adjusting the shunt resistance S, we can make galvanometer deflection as θ/2.Then the current in the circuit is ; Now, a fraction, S/ (G+S) of the current in the circuit is flows through the galvanometer, which is given by, Now, from the above relations, we can get the resistance of the given galvanometer as,
Figure of merit of a galvanometer
Figure of merit is in general is the numerical value representing the degree of effectiveness or efficiency of an instrument approximated by different estimation techniques. The figure of merit of a galvanometer is the current required to produce a deflection of one division in the galvanometer scale. It is represented by the letter k, and is given as, or ,Learning Outcomes
Students understand the various components used in the experiment.Students learn the concept, ‘figure of merit’.Students are able to construct circuits based on circuit diagrams.Procedure :
Materials Required
A weston type galvanometerA battery or battery eliminatorTwo resistance boxesTwo one-way keysConnecting wiresReal Lab Procedure
Resistance of galvanometer by half deflection method :
Arrange the components on a table and connect them as per the circuit diagram.Make sure that plugs of the resistance boxes are tight.Take out a high resistance from the resistance box 1 and insert the key k1.Adjust the resistance from this resistance box to get maximum galvanometer deflection.Note the deflection and record it as θ in the tubular column.Insert the key k2 also, without changing the value on the resistance box.Now, adjust the resistance from the low resistance box such that galvanometer shows deflection which is exactly half of the previous reading.Record the value of low resistance box.We can repeat the experiment by changing the value of high resistance R and adjusting low resistance S.The resistance of the given galvanometer can be calculated each time by using the relation G= RS/(R-S).Figure of merit of the galvanometer :
Release key k2 from the connection. Insert key k1.Adjust the value of R such that the galvanometer shows a certain deflection.Record the observations in a tabular column.Repeat the experiment by changing the value of R and note the galvanometer deflection each time.We can find the figure of merit of the galvanometer by using the equation, k= E/(R+G)θ.Simulator Procedure (as performed through the Online Labs)
Select the ‘Galvanometer’ form the drop down list.To see the circuit diagram, click on the ‘Show circuit diagram’ check box seen inside the simulator window.Connections can be made as seen in the circuit diagram by clicking and dragging the mouse from one connecting terminal to the other connecting terminal of the devices to be connected.Once all connections are made, click and drag key 1 to insert it into the switch.You can select the desired large resistance from the resistance box.The galvanometer shows a deflection.Now click and drag key 2 to insert it into the switch without changing the value of the resistance.Select the resistance from the small resistance box such that the galvanometer shows deflection which is exactly half of the previous reading.To see the result, click on the ‘Show result’ check box.To redo the experiment, click on the ‘Reset’ button.Observations
Resistance of the galvanometer by half deflection method.
No.Resistance, R()Deflection in thegalvanometer, Shunt Resistance, S ()Half deflection, Galvanometerresistance()1 Figure of Merit of a Galvanometer:3.63636 *10-5 ΩmFigure of merit of the galvanometer
No.Resistance, R ()Deflection, (div.)Figure of Merit, ( Amp/div ) Figure of Merit of a Galvanometer:3.63636 *10-5 ΩmCalculations
Calculate the value of G in each case and record it in the tabular column. The mean of these calculated values will give the resistance of the given galvanometer.Calculate the value of k in each case and record it in the tabular column. The mean of these calculated values will give the figure of merit of the given galvanometer.Results
The resistance of the given galvanometer, G =--------- ΩThe figure of merit of the given galvanometer, k =---------- Amp / div.
Video of this experiment above
Viva Voice -
1)Why a moving coil galvanometer is called so?None of theseBecause the coil moves while the magnet remains fixed.Because the number of turns of the coil varies with current.Because the coil moves along with the magnet.2)How can you increase the sensitivity of a moving coil galvanometer?By increasing the area of the coilBoth a and cBy increasing the number of turns of the coilBy decreasing the number of turns of the coil3)What is meant by the figure of merit of a galvanometer?Voltage required to produce unit deflection on the galvanometerMaximum deflection on the galvanometerNone of theseCurrent required to produce unit deflection on the galvanometer4)If the current through a galvanometer is, I = Kθ/NAB, then what is the sensitivity of the galvanometer?None of theseS = NAB/KθS = K/NABS = NAB/K5)What is the unit of figure of merit of a galvanometer?AmpereAmpere per meterAmpere per divisionVolt6)Choose the incorrect statement from the following.The resistance of the coil of the galvanometer is called the resistance of the galvanometer.Figure of merit of a galvanometer is the reciprocal of current sensitivity.Galvanometer has positive and negative terminals.Galvanometer deflection is proportional to the amount of current passed through it.7)What is the figure of merit of the galvanometer if current I produce a deflection θ in it?I^2/θIθI/2θI/θ
8)A resistance of 900Ω is connected in series with a galvanometer of resistance 100Ω. A potential difference of 1 V produces 100 division deflections in the galvanometer. Find the figure of merit of the galvanometer?2×10^-5 A/div.0.5×10^-5 A/div.10^-5 A/div.10^-6 A/div.
Books
Laboratory Manual Physics for class XII - Published by NCERTWebsites
http://www.vbpsnoida.com/student/Worksheets/Moving%20coil%20galv.pdfhttps://www.youtube.com/watch?v=9f6K7NgX9x0http://www.citycollegiate.com/galvanometer_XIIb.htmhttp://notes.tyrocity.com/moving-coil-galvanometer/https://books.google.co.in/books?isbn=8131803848https://books.google.co.in/books?isbn=8173352275var simPath="../PHY/CLA/Figure_Of_Merit/"; @font-face { font-family:digi; src: url(../PHY/CLA/Figure_Of_Merit/css/DS-DIGII.TTF); } var language_script= 'en-IN'; var language=language_script.toString(); language=language.slice(0, 2); var gt=$; gt.gettext.setLocale(language); if( !Modernizr.inputtypes.range ){ document.write(""); $(document).ready(function(){ $.webshims.setOptions("waitReady", false); $.webshims.polyfill('forms-ext'); }); }; SAVEFULLSCREENEXIT var simPath="../PHY/CLA/Figure_Of_Merit/"; 00:00
Select Resistance:
Large Small
1 2 2
5 10 20
20 50 100
200 200 500
1000 2000 2000
5000 10000 INF
0.1 0.2 0.2
0.5 1 2
2 5 10
20 20 50
100 INF
var expTitle="Ohm's Law"; document.getElementById("expName").innerHTML=expTitle; Developed by Amrita University Under research grant from
Department Of Electronics & Information Technology function simFullScreenOlab(){ var $ = function(selector,context){return(context||document).querySelector(selector)}; var iframe = $("iframe"), domPrefixes = 'Webkit Moz O ms Khtml'.split(' '); var fullscreen = function(elem){ var prefix; // Mozilla and webkit intialise fullscreen slightly differently for ( var i = -1, len = domPrefixes.length; ++i len; ) { prefix = domPrefixes[i].toLowerCase(); if ( elem[prefix + 'EnterFullScreen'] ) { // Webkit uses EnterFullScreen for video return prefix + 'EnterFullScreen'; break; } else if( elem[prefix + 'RequestFullScreen'] ) { // Mozilla uses RequestFullScreen for all elements and webkit uses it for non video elements return prefix + 'RequestFullScreen'; break; } } return false; }; // Webkit uses "requestFullScreen" for non video elements var fullscreenother = fullscreen(document.createElement("iframe")); if(!fullscreen) { alert("Fullscreen won't work, please make sure you're using a browser that supports it and you have enabled the feature"); return; } iframe[fullscreenother](); (this,this.document); } Original link
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