Smoke. Since a voltmeter is in parallel with the load it is right across the source voltage. Putting the amp meter across the line with its low resistance it will act like a fuse, hence the smoke. Newer solid state testers are usually smarter that the operators. They have built in circuitry which sense the wrong settings you are using and shut the tester off with a "beep" to let you know that you are doing something wrong.
If the voltmeter was ahead of the ammeter, the voltmeter would read supply voltage, and the ammeter would read current through the voltmeter, a very small reading. If the ammeter was ahead of the voltmeter, the ammeter would read supply current, which is probably many times in excess of the ammeter's rating, so you would either destroy the ammeter (or battery) or blow its fuse. It does not matter about the voltmeter, as the ammeter is now blown.
Voltmeter must be connected parallel and ammeter in series, if voltmeter is connected in series, only the voltage of the source will be read, and the current is approx. zero because voltmeter is a high resistance tester.
A: In reality an ammeter reads voltage across a shunt resistance of very low value. A direct substitution probably will result of no reading or very little deflection or reading.
ammeter in series at any side as required since it is bilateral and voltmeter is connected in parallel to measure voltage drop across it
An Ammeter connects a low impedance on the test points, so the equivalent of that is a "short circuit" between the test points. This is done to avoid a drop of current on the tested circuit. A Voltmeter connects a high impedance on the test points, so the equivalent of that is a "open circuit" between the test points. This is done to avoid a drop of voltage on the tested circuit. --------- In terms of external connections Ammeter (used to measure current) is connected in series of the circuit (through which the current flow need to be measured) and voltmeter (used to measure voltage) is connected in parallel to points in circuit (across which voltage needs to be measured).
A digital voltmeter will read negative voltage, if connecting backward. If the meter is an analogue type, the needle will go backwards and dip below the 0 on the scale.
An ammeter measures current THROUGH a circuit, a voltmeter measures current ACROSS a circuit. The ammeter is connected to a power source in series, essentially actually becoming part of the circuit. The current is flowing directly through the ammeter as if there were a wire in its place. If there is a surge from a substantial power source, the ammeter would be destroyed and the user could be severely injured. The fuse will "blow" if its "load" is exceeded breaking the circuit. A volt meter is connected to a power source in parallel because it has an extremely high resistance and little to no current would get through. You don't need a fuse because the current doesn't flow through it openly.
an ideal ammeter has zero or negligible resistance when this is connected in series no effective resistance would be added in the circuit so that the value of curret that we get is exactly of the circuit only. but when the ammeter is connected in parllel as it has zero resistance , the resistor to which it is connected in parllel gets shorted and due to his the effective resistance of the circuit is changed and so the effective current ... due to this the w=value measured by the ammeter would be different (incresed due to dec. in effective resistance)
The ammeter is used in series, because you want to measure the current through a circuit. The voltmeter is used in parallel, because you want to measure the voltage across a circuit. If you were to place the voltmeter in series, no current would flow because of the relatively high impedance of the voltmeter. If you were to place the ammeter in parallel, you would create a short-circuit, due to the relatively low impedance of the ammeter.
if we would like to expand the range of voltmeter we should change the voltmeter resistance even to be appropriate . we should use a variable resistance to control of its value . I would extend the range of a voltmeter by adding resistance in series with it. I would extend the range of an ammeter by connecting resistance in paerallel with it.
An ammeter should not be used as a voltmeter. An ammeter is a low impedance device that measures the current going through a circuit, often by measuring the small voltage across a known resistance. A voltmeter is a high impedance device that measures the voltage across a circuit. If you were to connect an ammeter as if it were a voltmeter, you would effectively short out the circuit, drastically affecting its operation, and potentially damaging both the circuit and the ammeter.
You would load the circuit, and it is likely it would not operate correctly. A volt meter is designed to have a very high resistance between the two probes; an ammeter is designed to have a very low resistance. For instance, say you have a 120 watt light bulb that runs on 120 volts (you would then draw ~1 amp of current). If you tried to measure this with a meter that has .1 ohm resistance on ammeter setting, and 1,000,000 ohms on volt meter: Error due to loading: ammeter: .1 / (120 + .1) = .08%; Current will be .999Amps, power to the light bulb will be 119.9 watts Volt meter: 1,000,000/ (120 + 1,000,000) = 99.9%; current will be 120micro Amps, power to the light bulb will be 14.4 milliwatts (the light bulb will not appear to be on).
ammeter in series at any side as required since it is bilateral and voltmeter is connected in parallel to measure voltage drop across it
The Thevenin equivalent circuit of this battery is 1.5V and 0.6 ohms in series. A more exact answer cannot be given without knowing the actual resistance of the 2 meters (I assumed infinite for the voltmeter and zero for the ammeter, as would be for ideal meters).However I would NEVER attempt this test as you describe it, many types of batteries will explode like bombs when shorted (as they would be when an ammeter was placed across them)! The correct way to do this test safely is with just a voltmeter and an adjustable high wattage resistor.
An Ammeter connects a low impedance on the test points, so the equivalent of that is a "short circuit" between the test points. This is done to avoid a drop of current on the tested circuit. A Voltmeter connects a high impedance on the test points, so the equivalent of that is a "open circuit" between the test points. This is done to avoid a drop of voltage on the tested circuit. --------- In terms of external connections Ammeter (used to measure current) is connected in series of the circuit (through which the current flow need to be measured) and voltmeter (used to measure voltage) is connected in parallel to points in circuit (across which voltage needs to be measured).
As there are multiple properties of an electrical circuit that can be metered or tested then a multimeter would be useful
The voltmeter would read 12 volts. An ammeter connected to to battery would only read 4 amps (12 volts divided by 3 ohms =4)
All the current would go through the ammeter. The whole purpose for making a measurement with an ammeter is to determine current draw through a component or circuit. If the ammeter takes all the current away from the device under test, the reading would be meaningless. Also, since the ammeter would present pretty much a dead short to the power supply, blown fuses or toasted components usually result.
It would be equivalent to adding a high value resistor (>10M ohms) in series in the circuit. Voltmeters typically present a high internal impedance so as to not change the current flow in the circuit you are tying to measure. the circuit wont work the voltmeter only takes a voltage reading power does not actually pass through the meter sometimes it can be used to measure very low leakage current using the hi impedance of the meter. EXAMPLE leakage offset from an amplifier. it could be into the nanoamps.
An ammeter is connected in series with the circuit being measured because you want to measure the current flowing through the circuit, whereas a voltmeter is connected in parallel with the circuit being measured because you want to measure the voltage across the circuit. Kirchoff's current law states that the signed sum of the currents entering a node is zero. A consequence of that law is that the current at every point is a series circuit is the same. The ammeter measures that current and, so long as its impedance is not too high, it won't disturb the circuit being measured. Kirchoff's voltage law, on the other hand, states that the signed sum of the voltage drops in a series circuit adds up to zero. A consequence of that law is that the voltage across parallel nodes must be equal. The voltmeter measures that voltage and, so long as it impedance is not too low, it won't disturb the circuit being measured. Formalities aside... An ammeter is a low impedance device. If you were to connect it in parallel with a circuit, it would draw all of the available current from that circuit. It and the circuit or its power supply would be damaged, because the ammeter represents a short circuit. A voltmeter is a high impedance device. If you were to connect it in series with a circuit, it would prevent any of the available current from reaching that circuit. While it and the circuit would probably not be damaged, the circuit would not function. Since practical meters are not perfect, the ammeter is not zero ohms impedance, nor is the voltmeter infinity ohms impedance. If you intend to measure both current and voltage in a circuit, it is normal protocol to measure the voltage across the circuit downstream of the ammeter, so that you would not be also measuring the additional voltage drop across the ammeter.