How to measure electrical resistance of a circuit with a multimeter

Block diagram and designation on Ohmmeter diagrams

The Ohmmeter measuring device is structurally a dial or digital indicator with a battery or power source connected in series, as shown in the photograph.

All combined instruments - pointer testers and digital multimeters - have the function of measuring resistance.

In practice, a device that measures only resistance is used for special cases, for example, to measure insulation resistance at elevated voltages, ground loop resistance, or as a reference device for testing other low-precision ohmmeters.

On electrical measuring circuits, an ohmmeter is designated by the Greek letter omega enclosed in a circle, as shown in the photograph.

Preparing an Ohmmeter for Measurements

Repair of electrical wiring, electrical and radio engineering products consists of checking the integrity of the wires and searching for contact failure in their connections.

In some cases, the resistance must be equal to infinity, for example, insulation resistance. And in others it is zero, for example, the resistance of wires and their connections. And in some cases it is equal to a certain value, for example, the resistance of the filament of a light bulb or heating element.

Attention! In order to avoid failure of the Ohmmeter, it is allowed to measure the resistance of circuits only when they are completely de-energized.

You must unplug the plug from the socket or remove the batteries from the compartment. If the circuit contains electrolytic capacitors of larger capacity, then they must be discharged by shorting the capacitor terminals through a resistance of about 100 kOhm for a few seconds.

As with voltage measurements, before measuring resistance, it is necessary to prepare the device. To do this, you need to set the device switch to the position corresponding to the minimum measurement of the resistance value.

Before measurements, you should check the functionality of the device, since the batteries may be bad and the Ohmmeter may not work. To do this, you need to connect the ends of the probes together.

The tester's needle should be set exactly to the zero mark; if it is not set, then you can turn the "Set" knob. 0". If this does not work, you need to replace the batteries.

To test the continuity of electrical circuits, for example, when checking an incandescent light bulb, you can use a device whose batteries are dead and the needle does not set to 0, but reacts at least a little when the probes are connected. It will be possible to judge the integrity of the circuit by the fact that the arrow is deflected. Digital devices should also show zero readings, a deviation in tenths of ohms is possible due to the resistance of the probes and the transition resistance in the contacts connecting them to the terminals of the device.

When the ends of the probes are open, the tester arrow should be set to the point indicated on the scale ∞, and in digital instruments, the overload will blink or the number will be displayed 1

on the indicator on the left side.

The ohmmeter is ready for use. If you touch the ends of the probes to the conductor, then if it is intact, the device will show zero resistance, otherwise the readings will not change.

Expensive models of multimeters have a circuit continuity function with audio indication, indicated in the resistance measurement sector with a diode symbol. It is very convenient for testing low-impedance circuits, such as twisted pair cables for the Internet or household electrical wiring. If the wire is intact, then the continuity is accompanied by a sound signal, which eliminates the need to read readings from the multimeter indicator.

Types of voltmeters

Analog voltmeters

Includes deflection type indicator voltage meters. An analog voltmeter can be divided into three categories.

Moving Coil Tools
Moving iron
Electrostatic voltmeter

Moving Coil Tools

Type of Moving Coil Meters Analog voltmeters are available in two types. They are:

Permanent Magnet Moving Coil Tools
Moving Coil Tools

Permanent Magnet Moving Coil Tools

Moving coil permanent magnet tools only respond to direct current. These instruments have a permanent magnet to create a magnetic field. The coil is wound on a piece of soft iron and rotates around its own vertical axis. When current flows through the coil, a deflecting torque is generated according to the Lorentz force equation.

Dynamo moving coil devices consist of two coils. One coil is fixed and the other coil rotates around it. The interaction of the two fields creates a deflection moment.

Moving Iron Tools

Moving iron tools are used in AC circuits and are classified into simple moving iron, dynamometer type and induction type. It consists of soft iron containing moving and stationary coils.

The interaction of the flows created by these elements creates a deflection moment. Ranges are extended by keeping resistors in series with the coil.

Electrostatic voltmeter

It works on an electrostatic principle whereby the repulsion between two charge plates deflects a pointer attached to a spring.

These instruments are used to measure high voltage AC and DC current. These are highly sensitive instruments capable of measuring minimum charge voltage as well as high range voltages of almost 200 kV.

Vacuum tube voltmeter

These types of instruments can handle both AC/DC voltage and resistance measurements. These devices use an electronic amplifier between the input and the meter.

If this device uses a vacuum tube in the amplifier, then it is called a vacuum tube voltmeter (VTVM). VTVMs are used in high power AC measurements.

A field-effect transistor (FET) is a transistor that uses an electric field to control the electrical behavior of a device. They are also known as unipolar transistors. A FET voltmeter uses this property of FETs to measure voltage.

Digital Voltmeter (DVM)

The DVM displays the voltage using LEDs or LCDs to display the result. The device must contain an analog-to-digital converter. The device contains a programmed microcontroller, ADC, and LCD display to provide accurate digital display of analog values from 0 to 15 volts DC.

They are used for properties such as accuracy, durability and reduce parallax errors.

Examples from practice of measuring resistance of products

In theory, everything is usually clear, but in practice questions often arise that can best be answered by examples of checking the most common products with an ohmmeter.

Checking incandescent lamps

The incandescent light bulb in a lamp or car on-board devices has stopped shining, how can I find out the reason? The switch, electrical socket or wiring may be faulty. Using the tester, any incandescent lamp from a home lamp or car headlight, filament of fluorescent lamps and energy-saving lamps can be easily checked. To check, just set the device switch to the minimum resistance measurement position and touch the ends of the probes to the terminals of the light bulb base.

The resistance of the light bulb filament was 51 Ohms, which indicates its serviceability. If the thread were broken, the device would show infinite resistance. The resistance of a 220 V halogen light bulb with a power of 50 watts when illuminated is about 968 Ohms, and a 12 volt car light bulb with a power of 100 watts is about 1.44 Ohms.

It is worth noting that the resistance of an incandescent lamp filament in a cold state (when the light bulb is not lit) is several times less than in a warm state. This is due to the physical property of tungsten. Its resistance increases nonlinearly with heating. Therefore, incandescent lamps usually burn out the moment they are turned on.

Unfortunately, LED and energy-saving lamps cannot be checked with a multimeter without disassembling them, since the supply voltage from the base terminals is supplied to the driver diode bridge.

Using an online calculator, you can independently calculate the resistance of any incandescent light bulb or heating element, for example, a heating element, or an electric soldering iron.

Online calculator for calculating the resistance value based on power consumption
Supply voltage, V:
Power, W:

Checking sound-reproducing headphones

It happens with headphones in one of the emitters, or in both at once, the sound is distorted, periodically disappears or is absent. There are two possible options: either the headphones or the device from which the signal is received are faulty. Using an ohmmeter, it is easy to find the cause of their breakdown and repair the headphones.

To check the headphones, you need to connect the ends of the probes to their connector. Typically, headphones are connected to the equipment using a 3.5 mm jack connector, shown in the photo.

One end of the probe touches the common terminal, and the other, in turn, touches the terminals of the right and left channels. The resistance should be the same and be about 40 ohms. Usually, the resistance is indicated in the passport for headphones.

If the resistance of the channels is very different, then there may be a short circuit or a broken wire in the wires. It is easy to verify this; just connect the ends of the probes to the terminals of the right and left channels. The resistance should be twice that of one earphone, that is, already 80 Ohms. In practice, the total resistance of series-connected emitters is measured.

If the resistance changes when the conductors move during measurements, it means that the wire is frayed in some place. Usually the wires fray where they exit the Jack or emitters.

To localize the location of the wire break, during measurements it is necessary to bend the wire locally, fixing the rest of it. Based on the instability of the ohmmeter readings, you will determine the location of the defect. If it’s a Jack, then you need to purchase a detachable connector, bite off the old one with a section of bad wire and solder the wire to the contacts of the new Jack.

If the break is located at the entrance to the headphones, then you need to disassemble them, remove the defective part of the wire, strip the ends and solder them to the same contacts to which the wires were soldered before. In the website article “How to solder with a soldering iron” you can learn about the art of soldering.

Measuring the resistor value (resistance)

Resistors (resistance) are widely used in electrical circuits. Therefore, when repairing electronic devices, it becomes necessary to check the serviceability of the resistor or determine its value.

On electrical diagrams, a resistor is designated as a rectangle, inside which its power is sometimes written in Roman numerals. I – one watt, II – two watts, IV – four watts, V – five watts.

You can check the resistor (resistance) and determine its value using a multimeter turned on in resistance measurement mode. In the resistance measurement mode sector, there are several switch positions. This is done in order to increase the accuracy of the measurement results.

For example, position 200 allows you to measure resistances up to 200 Ohms. 2k – up to 2000 Ohm (up to 2 kOhm). 2M – up to 2,000,000 Ohm. (up to 2 MOhm). The letter k after the numbers denotes the prefix kilo - the need to multiply the number by 1000, M stands for Mega, and the number needs to be multiplied by 1,000,000.

If the switch is set to position 2k, then when measuring a resistor with a nominal value of 300 kOhm, the device will show an overload. It is necessary to switch it to position 2M. In contrast to measuring voltage, it does not matter what position the switch is in; you can always switch it during the measurement process.

Applications of Voltmeter

Voltmeter applications include:

This is very useful for determining the voltage of the charge storage device, such as checking the battery voltage. For example, a new AAA cell will read about 1.6 V. A 12 V lead-acid car battery will read 12.5 V when fully charged, or 14 V when charged from the car's alternator. If it shows 10V, then there is something wrong with the alternator.
It can be used simply to find out whether there is power in a circuit or not, such as a power outlet.
Make sure the power is turned on or off to the devices.
We can calculate the current by measuring the voltage across a known resistance. This is useful when you don't have an ammeter.
They are used to construct a continuity test with a series battery.
These are used to construct an ohmmeter using a voltage divider with an unknown resistor.
These are used to construct an ammeter by measuring the voltage across a shunt resistor.

Timerkaev Boris is a 68-year-old doctor of physical and mathematical sciences, professor from Russia. He is the head of the department of general physics at the Kazan National Research Technical University named after A. N. TUPOLEV - KAI

Online calculators for determining resistor values by color coding

Sometimes when checking a resistor, the ohmmeter shows some resistance, but if the resistor, as a result of overloads, has changed its resistance and it no longer corresponds to the marking, then such a resistor should not be used. Modern resistors are marked using colored rings. The most convenient way to determine the value of a resistor marked with colored rings is to use an online calculator.

Online calculator for determining the resistance of resistors marked with 4 colored rings

Online calculator for determining the resistance of resistors marked with 5 colored rings

Checking diodes with a multimeter or tester

Semiconductor diodes are widely used in electrical circuits to convert alternating current to direct current, and usually when repairing products, after an external inspection of the printed circuit board, the diodes are first checked. Diodes are made from germanium, silicon and other semiconductor materials.

In appearance, diodes come in different shapes, transparent and colored, in a metal, glass or plastic case. But they always have two conclusions and immediately catch the eye. The circuits mainly use rectifier diodes, zener diodes and LEDs.

The symbol for diodes in the diagram is an arrow pointing to a straight line segment. A diode is designated by the Latin letters VD, with the exception of LEDs, which are designated by the letters HL. Depending on the purpose of the diodes, additional elements are added to the designation scheme, which is reflected in the drawing above. Since there is more than one diode in a circuit, for convenience, a serial number is added after the letters VD or HL.

It is much easier to check a diode if you understand how it works. And the diode works like a nipple. When you inflate a ball, rubber boat or car tire, air enters it, but the nipple does not allow it back.

A diode works exactly the same. Only it passes in one direction not air, but electric current. Therefore, to check the diode, you need a direct current source, which can be a multimeter or a pointer tester, since they have a battery installed.

Above is a block diagram of the operation of a multimeter or tester in resistance measurement mode. As you can see, a DC voltage of a certain polarity is supplied to the terminals. It is customary to apply the plus to the red terminal, and the minus to the black. When you touch the diode terminals in such a way that the positive output of the device is on the anode terminal of the diode, and the negative output is on the cathode of the diode, then current will flow through the diode. If the probes are swapped, the diode will not pass current.

A diode can usually have three states - good, broken or broken. During a breakdown, the diode turns into a piece of wire; it will pass current no matter the order in which the probes touch. If there is a break, on the contrary, the current will never flow. Rarely, but there is another condition when the transition resistance changes. Such a malfunction can be determined by the readings on the display.

Using the above instructions, you can check rectifier diodes, zener diodes, Schottky diodes and LEDs, both with leads and in SMD version. Let's look at how to test diodes in practice.

First of all, it is necessary, observing the color coding, to insert the probes into the multimeter. Usually a black wire is inserted into COM, and a red wire into V/R/f (this is the positive terminal of the battery). Next, you need to set the operating mode switch to the dialing position (if there is such a measurement function), as in the photo, or to the 2kOm position. Turn on the device, close the ends of the probes and make sure it is working.

We’ll start the practice by checking the ancient germanium diode D7, this specimen is already 53 years old. Germanium-based diodes are now practically not produced due to the high cost of germanium itself and the low maximum operating temperature, only 80-100°C. But these diodes have the smallest voltage drop and noise level. They are highly valued by tube amplifier builders. In direct connection, the voltage drop across a germanium diode is only 0.129 V. The dial tester will show approximately 130 Ohms. When the polarity is changed, the multimeter shows 1, the dial tester will show infinity, which means a very high resistance. This diode is OK.

The procedure for checking silicon diodes is no different from checking those made of germanium. The cathode terminal is usually marked on the diode body; it can be a circle, line or dot. In direct connection, the drop across the diode junction is about 0.5 V. For powerful diodes, the drop voltage is less, and is about 0.4 V. Zener diodes and Schottky diodes are checked in the same way. The voltage drop of Schottky diodes is about 0.2 V.

For high-power LEDs, more than 2 V drops at the direct junction and the device can show 1. But here the LED itself is an indicator of serviceability. If, when turned on directly, you can see even the faintest glow of the LED, then it is working.

It should be noted that some types of high-power LEDs consist of a chain of several LEDs connected in series and this is not noticeable from the outside. Such LEDs sometimes have a voltage drop of up to 30 V, and they can only be tested from a power supply with an output voltage of more than 30 V and a current-limiting resistor connected in series with the LED.

Checking electrolytic capacitors

There are two main types of capacitors, simple and electrolytic. Simple capacitors can be included in the circuit in any way you like, but electrolytic capacitors can only be connected with polarity, otherwise the capacitor will fail.

On electrical diagrams, a capacitor is indicated by two parallel lines. When designating an electrolytic capacitor, its connection polarity must be indicated with a “+” sign.

Electrolytic capacitors have low reliability and are the most common cause of failure of electronic components of products. A swollen capacitor in the power supply of a computer or other device is not a rare sight.

Using a tester or multimeter in resistance measurement mode, you can successfully check the serviceability of electrolytic capacitors, or, as they say, ring. The capacitor must be removed from the printed circuit board and be sure to be discharged so as not to damage the device. To do this, you need to short-circuit its terminals with a metal object, such as tweezers. To test the capacitor, the switch on the device must be set to resistance measurement mode in the range of hundreds of kilo-ohms or mega-ohms.

Next, you need to touch the terminals of the capacitor with the probes. At the moment of contact, the instrument needle should sharply deviate along the scale and slowly return to the position of infinite resistance. The speed at which the needle deflects depends on the capacitance value of the capacitor. The larger the capacitor capacity, the slower the shooter will return to its place. A digital device (multimeter), when touching the probes to the terminals of the capacitor, will first show a small resistance, and then increasingly increasing up to hundreds of megohms.

If the behavior of the devices differs from that described above, for example, the resistance of the capacitor is zero Ohm or infinity, then in the first case there is a breakdown between the windings of the capacitor, and in the second, a break. Such a capacitor is faulty and cannot be used.

Regulator assembly

The head of the multiturn adjusting screw and the conical part of the rod are treated with active flux and slightly (just slightly) tinned, the same is done with the bushing holes. The bushing is then heated to the melting temperature of tin and installed on the head of the adjusting screw of the multi-turn trimmer. The tin cools and firmly fixes the sleeve in place. Then the rod is heated and inserted into the sleeve in the same way. On the first try, this connection turns out to be quite strong and absolutely coaxial, that is, there is no beating during rotation, which can gradually lead to the destruction of the structure.

A cut is made in the body along the width of the multiturn body to a depth at which the connecting sleeve will rest against the bottom. We insert the multiturn with an extended rod into the body. No additional fixation is required here, even in the form of glue. But on the side of the rod, you can (but not necessarily) install a washer - a retainer - that was previously removed from this place. And solder it.