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  • Contents

Catalog

Ⅰ What Is a Potentiometer?

Ⅱ How Does a Potentiometer Work?

Ⅲ Types of Potentiometers

3.1 Manually adjustable potentiometers

3.2 Digital potentiometers

Ⅳ Basic Electrical Characteristics of Potentiometers

Ⅴ Advantages and Disadvantages of Potentiometer

5.1 Advantages of Digital Potentiometers

5.2 Disadvantages of Digital Potentiometers

Ⅵ Applications of Potentiometer

6.1 Audio control

6.2 Television

6.3 Motion control

6.4 Transducers

6.5 Computation

Ⅶ How to Wire a Potentiometer?

7.1 Part 1: Selecting and Preparing a Pot

7.2 Part 2: Soldering the Terminals

7.3 Part 3: Using Your Potentiometer

Ⅷ Rheostat VS Potentiometer

Ⅸ Conclusion

Ⅹ Frequently Asked Questions about Potentiometer

Ⅰ What Is a Potentiometer?

A potentiometer is a three-terminal resistor with a sliding or revolving contact that serves as a voltage divider that may be adjusted. When only one terminal, one end, and the wiper, are employed, it operates as a variable resistor or rheostat.

 

The term "potentiometer" is derived from the phrases Potential Difference and Metering and dates back to the early days of electrical research. It was considered at the time that altering huge wire-wound resistive coils metered or measured a specific amount of potential difference, so making it a type of voltage-metering device.

 

Basic Information of Potentiometer

 

A potentiometer is also known as a pot or potentiometer. The single-turn rotary potentiometer is the most common type of potentiometer. This sort of pot is commonly employed in audio volume control (logarithmic taper) and a variety of other applications. Potentiometers are made from a variety of materials, including carbon composition, cermet, wire-wound, conductive plastic, and metal film.

 

Potentiometers are often used to control electrical devices such as audio volume controls. Potentiometers with a machine can be used as position transducers, such as in a joystick. Potentiometers are rarely used to regulate considerable power (greater than a watt) directly since the power dissipated in the potentiometer is comparable to the power in the controlled load.

 

Ⅱ How Does a Potentiometer Work?

How Potentiometer Works

 

A potentiometer is a type of electronic component that is not active. Potentiometers function by changing the location of a sliding contact across a uniform resistance. The full input voltage is applied over the entire length of the resistor in a potentiometer, and the output voltage is the voltage drop between the fixed and sliding contacts, as shown below.

 

How Does a Potentiometer Work 1

 

The two terminals of the input source are fixed to the end of the resistor in a potentiometer. To change the output voltage, move the sliding contact along with the resistor on the output side.


This differs from a rheostat in that one end is fixed and the sliding terminal is linked to the circuit, as illustrated below.

 

How Does a Potentiometer Work 2

 

This is a simple device for comparing the emf of two cells as well as calibrating ammeters, voltmeters, and wattmeters. A potentiometer's basic operation is straightforward. Assume we have two batteries connected in parallel via a galvanometer. As indicated in the picture below, the negative battery terminals are connected together, and the positive battery terminals are likewise connected together via a galvanometer.

How Does a Potentiometer Work 3

 

If the electric potential of both battery cells is the same, there is no circulating current in the circuit, and the galvanometer shows no deflection. The operation of a potentiometer is dependent on this phenomenon.

How Does a Potentiometer Work 4

 

Consider another circuit in which a battery is linked across a resistor using a switch and a rheostat, as shown in the diagram below.

How Does a Potentiometer Work 5

 

Throughout its length, the resistor has the same electrical resistance per unit length.

 

As a result, the voltage drop per unit length of the resistor is constant along its length. Assume that by adjusting the rheostat, we get a volt voltage drop per unit length of the resistor.

 

Now, connect the positive terminal of a standard cell to point A on the resistor, and the negative terminal to a galvanometer. As indicated in the image above, the other end of the galvanometer is in touch with the resistor through a sliding contact. By adjusting this sliding end, a point like B is discovered where there is no current flowing through the galvanometer and thus no deflection in the galvanometer.

 

That is, the voltage appearing in the resistor across points A and B just balances the emf of the standard cell. If the distance between locations A and B is L, then the emf of a standard cell E = Lv volt can be written.

 

This is how a potentiometer monitors the voltage between two locations (in this case, A and B) without introducing any current into the circuit. A potentiometer's specialty is that it can measure voltage with extreme precision.

 

Types of Potentiometers

3.1 Manually adjustable potentiometers

Potentiometers come in a wide range of shapes and sizes. Manually adjusted potentiometers are classified as having either rotary or linear movement. The available types and their applications are listed in the tables below. In addition to manually adjustable pots, electronically controlled potentiometers, sometimes known as digital potentiometers, are available.

 

Rotary potentiometers

The most common type of potentiometer, with the wiper moving in a circular motion.

 

Type Description Applications
Single-turn pot A single rotation of approximately 270 degrees or 3/4 of a full turn. The most common pot is used in applications where a single turn provides enough control resolution.
Multi-turn pot Multiple rotations (mostly 5, 10, or 20), for increased precision. They are constructed either with a wiper that follows a spiral or helix form or by using a worm gear. Used where high precision and resolution are required. The worm-gear multi-turn pots are often used as trim pots on PCB.
Dual-gang pot Two potentiometers combined on the same shaft, enabling the parallel setting of two channels. Most common are single-turn potentiometers with equal resistance and taper. More than two gangs are possible but not very common. Used in for example stereo audio volume control or other applications where 2 channels have to be adjusted in parallel.
Concentric pot Dual potmeter, where the two potentiometers are individually adjusted by means of concentric shafts. Enables the use of two controls on one unit. Often encountered in (older) car radios, where the volume and tone controls are combined.
Servo pot A motorized potmeter can also be automatically adjusted by a servo motor. Used where manual and automatic adjustment is required. Often seen in audio equipment, where the remote control can turn the volume control knob.

 

Linear potentiometers

Potentiometers that allow the wiper to move in a straight line. Also referred to as a slider, slide pot, or fader.

 

Type Description Applications
Slide pot Single linear slider potentiometer, for audio applications also known as a fader. High-quality faders are often constructed from conductive plastic. For single-channel control or measurement of distance.
Dual-slide pot Dual slide potentiometer, single slider controlling two potentiometers in parallel. Often used for stereo control in professional audio or other applications where dual parallel channels are controlled.
Multi-turn slide Constructed from a spindle that actuates a linear potentiometer wiper. Multiple rotations (mostly 5, 10, or 20), for increased precision. Used where high precision and resolution are required. The multi-turn linear pots are used as trim pots on PCB but are not as common as the worm-gear trimmer potentiometer.
Motorized fader Fader which can be automatically adjusted by a servo motor. Used where manual and automatic adjustment is required. Common in-studio audio mixers, where the servo faders can be automatically moved to a saved configuration.

3.2 Digital potentiometers

Potentiometers that be operated electronically are known as digital potentiometers. In most situations, they consist of a sequence of small resistive components. Every resistive element has a switch that can be used as the tap-off point or virtual wiper position. Digital potentiometers can be controlled by up/down signals or protocols such as I2C and SPI.

 

 Basic Electrical Characteristics of Potentiometers

Nominal Total Resistance (Total Resistance)

The nominal total resistance is the resistance value that represents the standard value for a potentiometer.

Total resistance is defined as the resistance between terminals 1 and 3.

 

Residual Resistance

Residual resistance is the resistance between terminals 1 and 2 when the wiper is positioned at the terminal 1 end or the resistance between terminals 3 and 2 when the wiper is positioned at the terminal 3 ends.

 

The minimum resistance value while the wiper is at its minimum or maximum range of movement is referred to as residual resistance.

Residual-Resistance

Residual Resistance

 

Maximum Attenuation

When the output is at its lowest, the output voltage ratio (in decibels) is the highest.

 

It denotes the extent to which audio equipment's volume can be reduced.

 

Maximum attenuation and insertion loss (see below) are employed instead of residual resistance in the context of potentiometers for volume control.

 

Maximum-Attenuation

Maximum Attenuation

 

Insertion Loss

When the output is at its maximum, the output voltage ratio (in decibels) is the highest.

 

It denotes the extent to which audio equipment's volume may reach full strength.

 

In the context of volume control potentiometers, insertion loss and maximum attenuation (see below) are employed in place of residual resistance.

Insertion-Loss

Insertion Loss

 

Resistance Taper

The proportion of the output voltage between terminals 1 and 2 (or terminals 2 and 3) with respect to the input voltage between terminals 1 and 3. It varies with wiper location, as illustrated by the resistance taper curves on the right.

 

A choice can be made, for example, between the B curve, which is suitable for level adjustment, and the A curve, which produces a more natural sound to the human ear.

Resistance-Taper

Resistance Taper

 

Sliding Noise

This is the minor electrical noise produced when the wiper passes over the resistive element.


The more noise there is, the easier it is for audio equipment volume control to produce an unpleasant crackling sound.

 

Sliding-Noise

Sliding Noise

 

Ⅴ Advantages and Disadvantages of Potentiometer

5.1 Advantages of Digital Potentiometers

Digital potentiometers provide the following advantages:

1)Higher dependability

2)Increased accuracy

3)Small size, several potentiometers can be packed on a single chip

4)Minimal resistance drift

5)Impervious to environmental conditions such as vibrations, dampness, shocks, and wiper pollution.

6)There is no moving part

7)Tolerance of up to 1%

8)Very low power dissipation, tens of milliwatts or less

 

5.2 Disadvantages of Digital Potentiometers

1)Digital potentiometers have the following drawbacks: they are not ideal for high-temperature environments or high power applications.


2)In digital potentiometers, there is a bandwidth consideration due to the parasitic capacitance of the electronic switches. It is the highest frequency at which a signal can traverse the resistance terminals with less than 3 dB attenuation in the wiper. The transfer equation is analogous to that of a low pass filter.


3)The wiper resistance's nonlinearity introduces harmonic distortion onto the output signal. The total harmonic distortion, or THD, measures how much the signal degrades after passing through the resistance.

 

 Applications of Potentiometer

Potentiometers are rarely used to control considerable quantities of power directly (more than a watt or so). They are instead used to change the level of analog signals (for example, volume controls for audio equipment) and as control inputs for electronic circuits. A light dimmer, for example, employs a potentiometer to regulate the switching of a TRIAC, and so indirectly controls the brightness of lamps.

 

Preset potentiometers are commonly used in electronics to make modifications during manufacture or repair.

 

Potentiometers that are operated by the user are commonly employed as user controls and may control a wide range of equipment functions. Potentiometers were widely used in consumer electronics until the 1990s, when rotary incremental encoders, up/down pushbuttons, and other digital controllers took their place. However, they continue to be used in a variety of applications, including volume controls and position sensors.

 

6.1 Audio control

Low-power potentiometers, both slide, and rotary are used to control audio equipment by adjusting loudness, frequency attenuation, and other audio signal parameters.

 

The 'log pot,' that is, a potentiometer with a resistance, taper, or "curve" (or law) of a logarithmic (log) form, is employed as the volume control in audio power amplifiers, where it is also known as an "audio taper pot," because the amplitude response of the human ear is roughly logarithmic. It guarantees that, for example, on a volume control marked 0 to 10, a setting of 5 sounds half as loud as a setting of 10. An anti-log pot, also known as a reverse audio taper, is simply the inverse of a logarithmic potentiometer. It is nearly always ganged with a logarithmic potentiometer, for example, in audio balance control.

 

Potentiometers work as tone controllers or equalizers when used with filter networks.

 

Because of the straight-line character of the physical sliding action, the term linear is occasionally used incorrectly in audio systems to describe slide potentiometers. When applied to a potentiometer, whether sliding or rotary, the term linear refers to a linear relationship between the pot's position and the measured value of the pot's tap (wiper or electrical output) pin.

 

6.2 Television

Previously, potentiometers were employed to regulate picture brightness, contrast, and color response. A potentiometer was frequently used to modify "vertical hold," which affected synchronization between the receiver's internal sweep circuit (sometimes a multivibrator) and the received picture signal, as well as audio-video carrier offset, tuning frequency (for push-button sets), and so on. It also aids in wave frequency modulation.

 

6.3 Motion control

Potentiometers can be employed as position feedback devices in closed-loop control systems, such as servomechanisms. This motion control method is the most basic means of monitoring angle or displacement.

 

6.4 Transducers

Potentiometers are also extensively utilized as a component of displacement transducers due to their ease of manufacturing and ability to produce a large output signal.

 

6.5 Computation

High precision potentiometers are used in analog computers to scale intermediate results by specified constant factors or to create initial conditions for a calculation. A motor-driven potentiometer can be used as a function generator, with a non-linear resistance card providing trigonometric function approximations. For example, the shaft rotation may indicate an angle, and the voltage division ratio could be proportional to the angle's cosine.

 

How to Wire a Potentiometer?

Potentiometers, often known as pots, are a type of resistor that is used to control the output signal of an electronic device such as a guitar, amplifier, or speaker. They have a little shaft on top that acts like a knob; when the user twists the shaft, the resistance on the signal increases or decreases. This change in resistance is then utilized to modulate the loudness, gain, or strength of the electrical signal. To install and wire a pot, ground the first terminal, connect the input signal to the third terminal, and then connect the output signal to the terminal in the middle. To accomplish this, solder each wire to the corresponding terminal.

 

Learn How to Wire a Potentiometer

 

7.1 Part 1: Selecting and Preparing a Pot

Place the pot on a flat surface

Place the pot on a flat surface

 

Step 1: Determine the three major terminals that protrude from the pot's center.

Place the pot on a flat surface, three prongs facing you. These are your entry points. The first terminal, or terminal 1, is where you'll find your ground. The pot's input signal is sent to the middle terminal, or terminal 2. The output signal is routed to the third terminal, sometimes known as terminal 3. A tiny ring linked to the second terminal is controlled by the top shaft. You may control how low or high the input is by twisting it.

 

  • If it helps, think of a potentiometer as a dimmer switch. Terminal 1 serves as the ground, terminal 2 serves as the switch, and terminal 3 serves as the switch turned on.

 

  • In most cases, a potentiometer is used to throttle an input signal so that it can be changed. At times, a pot can be used to overclock a device with a stronger signal.

 

Look at the resistance numbers

Look at the resistance numbers

 

Step 2: Examine your pot's resistance numbers to see what range you can reach.

Pots are rarely used to control signals higher than a few volts, although the resistance they give is substantial. The wider the range, the more control you have over your gadget. The number on the front of the pot represents the highest amount of resistance of the pot. As a result, a 200K pot can give up to 200,000 ohms of resistance.

 

  • The 100K potentiometer is the most prevalent variety on the market due to its wide range of audio equipment.

 

  • These numbers are always printed immediately on a pot. They are often located on the other side of the terminals, immediately next to the shaft.

 

Tip: It is critical to understand how much resistance a pot gives in order to assess whether it is suitable for the task at hand. A 2,000-ohm pot will not provide enough range for a sound system, but it will do for a dimmer switch.

 

Three terminals

Three terminals

 

Step 3: Set your pot on a flat surface with the three terminals facing you.

Place your pot on a flat area next to your electronic device. Begin with the placement of the pot if you know where you're going to put it. Turn the three terminals so that they are facing you. Remove any panels on your electrical equipment to expose any backside input or output ports.

 

  • Place the pot on the uppermost set of rows on a breadboard, terminals facing you.

 

  • Unplug your electronic gadget before opening any panels or soldering any connections. You don't want to be electrocuted or damage your device forever.

 

Cut 0.5–1 in (1.3–2.5 cm)

Cut 0.5–1 in (1.3–2.5 cm)

 

Step 4: Measure and strip any wires you wish to utilize.

You can connect the terminals to the device with any type of soldering wire as long as it is not acid-core. If you have an installation location lined up, measure each length of wire from the termination to the device. Using a cutter, cut any wires to expose the copper. Using the notches on the cutter's blades, cut and remove 0.5–1 in (1.3–2.5 cm) of plastic off the tip of each wire.

 

  • To get a clean strip, set your wire stripper to match the gauge of the wire.

 

  • Prepare your work surface with a soldering iron and flux, since you will need to solder your wires.

 

  • Plumbing makes use of acid-core soldering wire. It is incompatible with your electronics.

 

  • If the soldering wires do not function, they can be used to wire a certain sort of electronic gadget that requires specialist wiring.

 

7.2 Part 2: Soldering the Terminals

Step 5: Connect a ground wire from terminal 1 on the left to the chassis.

Tap a tiny length of wire with your soldering iron and apply flux to the exposed section. Lower the wire and attach it to the exposed metal section on terminal 1 after it has absorbed some flux. Press your soldering tip against the connector to connect the wire to the terminal. Solder the other end of the cable to your electrical device's exposed, unpainted metal surface.

 

  • You can utilize terminal 3 on the right if you like, but you must turn the knob clockwise to lessen the signal.

 

Connect your device's output circuit to the middle terminal

Connect your device's output circuit to the middle terminal

 

Step 6: Connect your device's output circuit to the middle terminal.

Tin another length of wire in the same way and attach it to the center terminal of the pot. Because this is the point at which the signal enters the pot, it must be linked to the device's output. Solder the wire to the metal connection on the rear of your electronic device's output connection.

 

The input of the potentiometer is linked to the center terminal. That is, the signal leaves the electronic, enters terminal 2, and then leaves terminal 3. As a result, terminal 2 must be linked to the port that outputs the original signal from the device.

 

This would require wiring terminal 2 to a guitar's output jack. This would imply connecting terminal 2 to the integrated audio amplifier's speaker output terminal.

 

Terminal 3

Terminal 3

 

Step 7: Connect terminal 3 to the device's input.

Terminal 3 is the potentiometer's output. This is where the pot sends data back to the device. Place a length of exposed soldering wire directly on the terminal. After heating the wire with your soldering pen, connect it to the input port of your electronic device. Look for the exposed metal aperture on the back of the knob or the cable connector at the port's back. Solder the wire straight to the pot to connect it.

 

  • The signal from your pot exits through Terminal 3, thus it must be wired to the spot where you want to deliver the signal.

 

  • This would imply connecting terminal 3 to the guitar's input jack. The input channels would be linked to Terminal 3 of an audio amplifier.

 

7.3 Part 3: Using Your Potentiometer

Measure Potentiometer

Measure Potentiometer

 

Step 8: Using a voltmeter, check that your pot is operational.

Connect the voltmeter terminals to the input and output terminals of the pot. Turn on the voltmeter and turn the dial to feed a signal. Turn the knob on top of your pot to adjust the signal. If the signal reading on the voltmeter changes as you turn the knob, your potentiometer is working.

 

If the voltmeter registers a signal from your pot yet the gadget does not operate when you turn on your electronics, the soldered connections are faulty.

 

Signal From the Pot

Signal From the Pot

 

Step 9: Turn the shaft to adjust the signal on your device.

Turn on your gadget and send a signal to the pot by playing music, striking a guitar note, or turning on a light. Twist the shaft to the left to lessen the volume or brightness. Twist the shaft to the right to enhance the volume or brightness of the light. Switch the shaft to the left to turn off the output.

 

Using your pot, you may now control the amount of resistance that your signal receives.

 

Adjust the Amount of Resistance

Adjust the Amount of Resistance

 

You can add a knob by sliding it over the potentiometer if you like. You can install a potentiometer with the shaft naked and exposed if you wish. If you want to improve the look of your potentiometer, you may always buy a knob. There are several knobs available on the market that are meant to slide over the shaft of a pot and enhance its appearance.

 

That concludes the steps for wiring a potentiometer. Online electronic stores can tell you what possibilities are available for your specific make and model.

 

Rheostat VS Potentiometer

Differences Between Potentiometers and Rheostats

 

A potentiometer controls the voltage. Variable resistance is provided by a rheostat. A potentiometer has three terminals, whereas a rheostat has two terminals. Both gadgets appear to be similar in construction, yet their operating principles are completely different. Two end terminals of the uniform resistance are linked to the source circuit of the potentiometer. Only one terminal of the uniform resistance is connected to the circuit in a rheostat, leaving the other end of the resistance open. A sliding contact on the resistance is included in both potentiometers and rheostats.

rheostat

rheostat

 

The output voltage of a potentiometer is measured between fixed and sliding contacts. Variable resistance is produced in rheostats by alternating between fixed and sliding terminals. The potentiometer's resistance is connected across the circuit. The rheostat's resistance is linked in series with the circuit. The rheostat is commonly used to manage current by altering resistance via a sliding contact. The voltage of a potentiometer is regulated by moving the sliding contact on the resistance.

 

potentiometer

potentiometer

 

To obtain variable resistance, fixed and sliding terminals are employed. The resistance of the potentiometer is connected across the circuit. The resistance of the rheostat is linked in series to the circuit. A rheostat is a device that controls current by adjusting resistance via a sliding contact. A potentiometer's voltage is controlled by changing the sliding contact on the resistance.

 

Ⅸ Conclusion

A potentiometer, also known as a variable resistor, is made up of a resistive track with connections at both ends and a third terminal called the wiper, the position of which divides the resistive track. The wiper's position on the track is mechanically modified by spinning a shaft or using a screwdriver.

 

Variable resistors are classified into two operational modes: variable voltage dividers and variable current rheostats. The potentiometer is a three-terminal device that controls the voltage, whereas the rheostat is a two-terminal device that controls current.

 

This is summarized in the table below:

 

Type Potentiometer Rheostat
Number of Connections Three Terminals Two Terminals
Number of Turns Single and Multi-turn Single-turn Only
Connection Type Connected Parallel with a Voltage Source Connected in Series with the Load
Quantity Controlled Controls Voltage Controls Current
Type of Taper Law Linear and Logarithmic Linear Only

 

The potentiometer, trimmer, and rheostat are electromechanical devices with easily adjustable resistance values. They can be single-turn pots, presets, slider pots, or multi-turn trimmers. Wirewound rheostats are primarily used to regulate electrical current. Potentiometers and rheostats are also available in multi-gang configurations and have either a linear or a logarithmic taper.

 

Potentiometers, on the other hand, may provide highly precise sensing and measurement for linear or rotary movement because their output voltage is proportional to the position of the wipers. Potentiometers have many advantages, including inexpensive cost, simple operation, a wide variety of shapes, sizes, and designs, and the ability to be employed in a wide variety of applications.

 

However, as mechanical devices, they have drawbacks such as eventual wear-out of the sliding contact wiper and/or track, limited current handling capabilities (unlike Rheostats), electrical power constraints, and rotational angles limited to fewer than 270 degrees for single turn pots.

 

Ⅹ Frequently Asked Questions about Potentiometer

1. What is a potentiometer used for?

A position sensor is a potentiometer. They can measure displacement in any direction. Linear potentiometers measure movement linearly, whereas rotary potentiometers measure rotational displacement.

 

2. What are the 3 terminals on a potentiometer?

There are three pins on a potentiometer. Two terminals (blue and green) are linked to a resistive element, and the third (black) is linked to an adjustable wiper. The potentiometer can function as both a rheostat (variable resistor) and a voltage divider.

 

3. What is a potentiometer also known as?

A potentiometer is a three-terminal variable resistor that may be adjusted manually. A potentiometer is often referred to as a potmeter or pot. The single turn rotary potmeter is the most popular type of potmeter.

 

4. What is the potentiometer principle?

The potential lowered across a segment of a wire of uniform cross-section carrying a constant current is precisely proportional to its length, according to the principle of a potentiometer. A potentiometer is a basic device for measuring electrical potentials (or comparing the e.m.f of a cell).

 

5. Which wire is used in the potentiometer?

Potentiometer wire is typically made of alloys such as constantan or manganin. The temperature coefficient of Constantan or Manganin wire is low.

 

6. Can I use a potentiometer to control AC motor speed?

It is unlikely that you will be able to control the speed of an AC fan with a potentiometer. The technology employed determines whether an AC "mains" fan can be speed adjusted with a pot. Typically, a single-phase induction motor with a capacitor start.

 

7. What is the null point in a potentiometer?

The potentiometer's balancing point, also known as the null point, is the point on the sliding wire where the galvanometer indicates zero deflection. The balance point is discovered in order to ascertain the unknown voltage of the cell connected to the cell.

 

8. What is the sensitivity of the potentiometer?

Potentiometer sensitivity is defined as the smallest potential difference detected with a potentiometer. Potentiometer sensitivity can be enhanced by increasing the length of the potentiometer wire. Using a rheostat to reduce the current in the circuit.

 

9. What is a potentiometer wire?

Potentiometer: A potentiometer is a three-terminal resistor with a sliding or revolving contact that forms an adjustable voltage divider. If only one terminal, one end, and the wiper, are employed, it operates as a variable resistor or rheostat.

 

10. Why copper wire is not suitable for a potentiometer?

Copper wire is not suitable for potentiometers due to its high-temperature coefficient of resistance and low resistivity. As a result, even a small change in temperature might cause a significant change in resistance, changing the experimental conditions.

 

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