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Voltmeters | Ammeters |
Galvanometers | Ohmmeters
Next Page: Multimeters
Also See: Voltage and Current
Analogue display
Analogue displays have a pointer which moves over a graduated scale. They can be difficult
to read because of the need to work out the value of the smallest scale division. For example
the scale in the picture has 10 small divisions between 0 and 1 so each small division represents
0.1. The reading is therefore 1.25V (the pointer is estimated to be half way between 1.2 and 1.3).
The maximum reading of an analogue meter is called full-scale deflection or FSD
(it is 5V in the example shown).
Analogue meters must be connected the correct way round
to prevent them being damaged when the pointer tries to move in the wrong direction.
They are useful for monitoring continously changing values (such as the voltage across a
capacitor discharging) and they can be good for quick rough readings because the
movement of the pointer can be seen without looking away from the circuit under test.
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Correct reflection hidden |
Wrong reflection visible |
Taking accurate readings
To take an accurate reading from an analogue scale you must have your eye in line with
the pointer. Avoid looking at an angle from the left or right because you will see a
reading which is a little too high or too low. Many analogue meters have a small strip
of mirror along the scale to help you. When your eye is in the correct position the
reflection of the pointer is hidden behind the pointer itself. If you can see the
reflection you are looking at an angle.
Instead of a mirror, some meters have a twisted pointer to aid accurate readings.
The end of the pointer is turned through 90° so it appears very thin when viewed correctly.
The meter shown in the galvanometers section has a twisted pointer
although it is too small to see in the picture.
Digital display
Values can be read directly from digital displays so they are easy to read accurately.
It is normal for the least significant digit (on the right) to continually change between
two or three values, this is a feature of the way digital meters work, not an error!
Normally you will not need great precision and the least significant digit can be ignored
or rounded up.
Digital meters may be connected either way round without damage, they will show a minus
sign (-) when connected in reverse. If you exceed the maximum reading most digital meters
show an almost blank display with just a 1 on the left-hand side.
All digital meters contain a battery to power the display so they use virtually no power
from the circuit under test. This means that digital voltmeters have a very high resistance
(usually called input impedance) of 1M
or more, usually 10M,
and they are very unlikely to affect the circuit under test.
For general use digital meters are the best type. They are easy to read, they may be
connected in reverse and they are unlikely to affect the circuit under test.
Connecting meters
It is important to connect meters the correct way round:
- The positive terminal of the meter, marked + or coloured red
should be connected nearest to + on the battery or power supply.
- The negative terminal of the meter, marked - or coloured black
should be connected nearest to - on the battery or power supply.
Voltmeters
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Connecting a voltmeter in parallel |
- Voltmeters measure voltage.
- Voltage is measured in volts, V.
- Voltmeters are connected in parallel across components.
- Voltmeters have a very high resistance.
Measuring voltage at a point
When testing circuits you often need to find the voltages at various points,
for example the voltage at pin 2 of a 555 timer IC. This can seem confusing -
where should you connect the second voltmeter lead?
- Connect the black (negative -) voltmeter lead to 0V, normally the negative
terminal of the battery or power supply.
- Connect the red (positive +) voltmeter lead to the point
you where you need to measure the voltage.
- The black lead can be left permanently connected to 0V while you use the
red lead as a probe to measure voltages at various points.
- You may wish to use a crocodile clip on the black lead to hold it in place.
Voltage at a point really means the voltage difference between that point and 0V
(zero volts) which is normally the negative terminal of the battery or power supply.
Usually 0V will be labelled on the circuit diagram as a reminder.
Analogue meters take a little power from the circuit under test to operate their pointer.
This may upset the circuit and give an incorrect reading. To avoid this voltmeters should
have a resistance of at least 10 times the circuit resistance (take this to be the highest
resistor value near where the meter is connected).
Most analogue voltmeters used in school science are not suitable for electronics
because their resistance is too low, typically a few
k.
100k or more is
required for most electronics circuits.
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Connecting an ammeter in series |
Ammeters
- Ammeters measure current.
- Current is measured in amps (amperes), A.
1A is quite large, so mA (milliamps) and µA (microamps) are often used.
1000mA = 1A, 1000µA = 1mA, 1000000µA = 1A.
- Ammeters are connected in series.
To connect in series you must break the circuit and put the ammeter
across the gap, as shown in the diagram.
- Ammeters have a very low resistance.
The need to break the circuit to connect in series means that ammeters are difficult
to use on soldered circuits. Most testing in electronics is done with voltmeters which can
be easily connected without disturbing circuits.
Galvanometers
Galvanometers are very sensitive meters which are used to measure tiny currents,
usually 1mA or less. They are used to make all types of analogue meters by adding
suitable resistors as shown in the diagrams below. The photograph shows an educational
100µA galvanometer for which various multipliers and shunts are available.
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Making a Voltmeter A galvanometer with a high resistance multiplier in series to make a voltmeter. |
Making an Ammeter A galvanometer with a low resistance shunt in parallel to make an ammeter. |
Galvanometer with multiplier and shunt Maximum meter current 100µA (or 20µA reverse).
This meter is unusual in allowing small reverse readings to be shown. |
Ohmmeters
An ohmmeter is used to measure resistance in ohms
().
Ohmmeters are rarely found as separate meters but all standard
multimeters have an ohmmeter setting.
1
is quite small so k
and M
are often used.
1k =
1000,
1M =
1000k =
1000000.
Multimeters
Multimeters are very useful test instruments. By operating a multi-position switch on the
meter they can be quickly and easily set to be a voltmeter, an ammeter
or an ohmmeter. They have several settings (called 'ranges') for each type of
meter and the choice of AC or DC.
Some multimeters have additional features such as transistor testing and ranges for
measuring capacitance and frequency.
Analogue multimeters consist of a galvanometer
with various resistors which can be switched in as multipliers (voltmeter ranges)
and shunts (ammeter ranges).
For further information please see the Multimeters page.
Next Page: Multimeters
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© John Hewes 2011, The Electronics Club,
www.kpsec.freeuk.com