How to easily and simply convert milliamps to amperes and vice versa

');> //–> Ampere is a unit of measurement of electric current in the International System of Units (SI).

1 amp = 1000 milliamps

You can quickly perform this simple mathematical operation using our online program. To do this, enter the initial value in the appropriate field and click the button.

For complex calculations to convert several units of measurement into the required one (for example, for mathematical, physical or budget analysis of a group of positions), you can use universal unit converters.

This page provides the simplest online converter of units of measurement from milliamps to amperes. With this calculator you can convert mA to A and vice versa in one click.

');> //–> Ampere is a unit of measurement of electric current in the International System of Units (SI).

1 amp = 1000 milliamps

You can quickly perform this simple mathematical operation using our online program. To do this, enter the initial value in the appropriate field and click the button.

For complex calculations to convert several units of measurement into the required one (for example, for mathematical, physical or budget analysis of a group of positions), you can use universal unit converters.

This page provides the simplest online converter of units of measurement from milliamps to amperes. With this calculator you can convert mA to A and vice versa in one click.

Ampere

(Russian designation:
A
; international:
A
) is a unit of measurement of electric current in the International System of Units (SI), one of the seven basic SI units.
Magnetomotive force and magnetic potential difference are also measured in amperes (outdated name - ampere-turn
) [1]. In addition, the ampere is a unit of current and is one of the basic units in the ICSA system of units.

What are amperes and milliamps

Ampere is a unit of measurement of current strength, a physical quantity equal to the ratio between the magnitude of the charge and the time interval of its passage through any surface or object; one of the 7 basic units of the International System of Units (SI).


An ammeter is a device that measures in amperes.

Additional Information! The ampere was adopted as a unit of measurement in 1881 at the 1st International Congress of Electricians held in Paris and was named after the French physicist, mathematician and chemist André-Marie Ampere.


Andre Ampere

As amended in 2022, the International Committee of Weights and Measures defines ampere as follows:

"The magnitude of the ampere is fixed by determining the numerical value of the elementary charge and is equal to 1.602176634 × 10^-19, expressed in coulombs."


Emblem of the International Committee of Weights and Measures

A milliamp is a fractional value that, according to its prefix, is equal to one thousandth of an ampere, or 10^-3. It is also often written as "mamper" - a kind of middle designation between its designation (mA) and its name.

1 microamp is equivalent to 10^-6 A.

Important! Registering as "milliA" is not recommended; When using a unit of measurement designation, it is better to abbreviate the prefix with which it is used.


Table of prefixes and their meaning

Definition [edit | edit code]

On November 16, 2022, at the XXVI General Conference of Weights and Measures, a new definition of ampere was adopted, based on the use of the numerical value of the elementary electric charge. The wording, effective May 20, 2022, reads [2]:

The ampere, symbol A, is the SI unit of electric current. It is determined by fixing the numerical value of the elementary charge equal to 1.602 176 634⋅10 −19, when it is expressed in unit C, which is equal to A s, where the second is defined through Δ ν C su _>> [3].

Measurement technique

As noted earlier, ammeters, multimeters and testers are used to measure current. The first of them provides the greatest measurement accuracy. They only measure one size and one scale. And it's not very convenient. In turn, multimeters and testers allow you to measure almost all electrical quantities, and not just in a certain range. In addition, these devices have the ability to change units of measurement. For example, the device indicates that the interval has been exceeded. In this case, it is necessary to convert milliamps to amperes and thereby find out the desired value. The main disadvantage of testers and multimeters is that their error, unlike ammeters, is much greater. However, in practice they are often used, as this makes it easy and simple to find the fault and fix it. Another important nuance associated with these devices: if previously it was necessary to break the circuit, now there are testers and multimeters that allow you to measure current strength in a non-contact way, that is, without connecting. This solution is increasingly being used in practice.

Physical quantity

Ampere is a unit of measurement of current. Its value can be determined by making direct measurements with a multimeter, tester or ammeter (direct method). Current strength is measured only when the measuring device is connected in series to an electrical circuit. In the second case, its value can be found out by calculations (indirect method). If you know the voltage applied to a section of circuit and also its resistance, simply divide the former by the latter and we will get the required value. In practice, amplifiers are used infrequently - this makes a big difference. Therefore, it is necessary to use more units: micro (10-6) and milli (10-3). But to perform electrical calculations, you must convert them to base units (such as milliamps to amps). Consider the following example. The voltage on the circuit section is U = 6 V, resistance R = 100 Ohm. The current force I acting on it is determined by Ohm’s law:

I = U / R, (1)

where is it:

  • U – voltage on the circuit section, V;
  • R – resistance of the same section, Ohm;
  • I is the current force acting on it, A.

As a result of calculations, we obtain I = U / R = 6/100 = 0.06 A. This is not a very convenient number to understand. Therefore, it is converted into several units of measurement. In this case, it is convenient to express this value in milliamps. To do this, multiply the resulting value of 0.06 A by 1000 and get 60 mA. You can also do the reverse conversion - from milliamps to amps. To do this, it is enough to divide 60 mA by 1000 and we will get the same 0.06 A. From this conversion we can see how many milliamps are in amperes - 1000. Therefore, we divide or multiply by this number. If the prefix "micro" is used to change from one unit of measurement to another, multiply or divide by 1,000,000.

Measurement technique

As noted earlier, ammeters, multimeters and testers are used to measure current. The first of them provides the greatest measurement accuracy. They only measure one size and one scale. And it's not very convenient. In turn, multimeters and testers allow you to measure almost all electrical quantities, and not just in a certain range. In addition, these devices have the ability to change units of measurement. For example, the device indicates that the interval has been exceeded. In this case, it is necessary to convert milliamps to amperes and thereby find out the desired value. The main disadvantage of testers and multimeters is that their error, unlike ammeters, is much greater. However, in practice they are often used, as this makes it easy and simple to find the fault and fix it. Another important nuance associated with these devices: if previously it was necessary to break the circuit, now there are testers and multimeters that allow you to measure current strength in a non-contact way, that is, without connecting. This solution is increasingly being used in practice.

Ampere from a physics point of view

In physics and electrical engineering, ampere is a quantity that characterizes the strength of current in quantitative terms. Various methods are used to determine it. Among them, the most widespread method is direct measurements, when an ammeter, tester or multimeter is used. When taking measurements, these devices are connected in series to the electrical circuit.

Another method is considered indirect, requiring special calculations. In this case, it is necessary to know the voltage applied to a given section of the circuit and the resistance of this section. After which, the current strength is easily determined by the formula I = U/R, and the result obtained is displayed in amperes.

In practice, amperes are used quite rarely, since this unit is considered too large for ordinary use. Therefore, most specialists use multiple units - milliamps (10-3A) and microamps (10-6A), which can be otherwise designated as 0.001 A and 0.000001 A. However, when performing calculations, it is necessary to again convert milliamps into amperes and in all use these units in formulas. It is at this stage that many people have a question about how to convert milliamps to amperes.

How to correctly measure electric current in amperes

It should be clarified that current measurement is a measurement of its basic characteristics (force and voltage). Most often, in laboratory or school settings, the current strength is measured on a conductor or in the entire electrical circuit. For this, a special device is used - an ammeter. Which in the diagrams is correctly indicated by a circle with the Latin letter “A” inside.

When connecting an ammeter, the following rules must be observed:

  • Connect to the electrical circuit only in series with the section of the circuit where you want to measure the current. In other words, before or after the section of the circuit for measurements.
  • Be sure to pay attention to the “signs” of current in the circuit. We connect the plus wire from the power supply to the plus of the ammeter, and the minus to the minus.
  • Try not to exceed the value on the measurement scale, because in this case the device may not work. If the ammeter has two scales, use the one with the highest limit.


Diagram of the correct connection of an ammeter to an electrical circuit When measuring resistance, it is recommended to take into account the internal resistance of the ammeter itself, which is indicated on it.
But they are neglected at school. Additional Information! For measurements, you can use a multimeter - a device that combines the functions of measuring force, power and other current parameters. For this, the same rules for including an ammeter in the circuit are used.

What are amps, milliamps and microamps?

Correct designations: ampere - A, milliampere - mA, microampere - µA.

This physical quantity is named after the scientist's last name, so his entry will always contain a capital letter A in the Russian designation and a capital Latin letter A in the international designation.

Note! Do not confuse MA and MA, especially when solving problems. In the first case, the megaampere is indicated (10 ^ 6 A), and in the second case, the milliampere (10 ^ -3 A), which is a billion times less than a megaampere.

The writing of fractions and multiples of units, including milliamps and microamps, will be done in accordance with the rules for writing units and prefixes established by the above-mentioned International System of Measurement (SI).

  • The prefix is ​​written along with the name or designation of the unit.
  • It is unacceptable to use two or more prefixes in a row (for example, micromilliampere).
  • In most cases, it is customary to choose a prefix so that it is preceded by a number from 0.1 to 1000.

Additional Information! The prefix milli is translated from Latin (thousand) as “thousand”. The prefix “micro” has ancient Greek roots (μικρός) and is translated as “small”.

How many watts are in 1 ampere?

The concept of voltage is also important when determining the power of a circuit. This is the electromotive force that moves electrons. Measured in volts. Most devices have this feature in their documentation.

To determine the power at a current of one ampere, you need to know the mains voltage. So, for a 220 volt outlet it will be: P = 1 * 220 = 220 W. Formula for calculation: P = I * U, where I is current and U is voltage. In a three-phase network, it is necessary to take into account a correction factor, which reflects the percentage of operating efficiency. In most cases it is between 0.67 and 0.95.

How to translate

The easiest way is to convert the units manually, clearly showing amperes and milliamps, the difference between which is 10-3. As an example, we can consider a section of an electrical circuit with a voltage of 5 volts and a resistance of 100 ohms. In order to determine the current strength, you need to use the formula and divide the voltage value by the resistance I = U/R = 5/100 = 0.05 A. The result obtained is not entirely convenient to use, so it is recommended to recalculate it in multiple units of measurement, that is, in milliamps.

In this case, 1 ampere is equal to 1000 milliamps. To recalculate 0.05 A you need to multiply by 1000 and you get 50 mA. In the same way, the reverse procedure is done, when 50 mA is divided by 1000, and the result is the original 0.05 A. Thus, solving the problem for 1 ampere, how many milliamps are equal to 1000.

In order to speed up the procedure for converting units, special tables have been developed that display different types of quantities. For example, if one milliamp is 0.001 ampere, then in reverse order one ampere will be equal to 1000 milliamps. On battery cases, in addition to the current strength, the amount of time during which they can give or receive a certain charge is added. Various chargers are marked with the number of amps or milliamps, which additionally indicate their power.

What is measured in amperes

The main physical quantity measured in amperes is current (denoted in formulas by the letter “I”). As mentioned earlier in the definition of ampere, it is equal to the ratio of the amount of charge passing through a conductor in a certain time and the transit time itself.

Magnetomotive force (a physical quantity, the modulus of which shows the ability to create magnetic fluxes using electric currents) and magnetic potential difference (a scalar quantity that characterizes the energy characteristics of the electrostatic field at a given point) are also measured in amperes... Often in practice you can find the use of the term “ampere” -turn" to indicate these values. But officially this is considered outdated terminology.

Methods for converting current value

For modern energy-intensive household appliances, currents of several amperes or more work quite well, and it is not difficult to use this unit of measurement. The cheapest devices include:

  • Computer;
  • Laptop;
  • Regular smartphones and cell phones;
  • MP3 players, set-top boxes;
  • LCD – lighting equipment;
  • LCD – video devices (monitors, televisions);
  • Pills;
  • E-books;
  • Navigators;
  • VCRs.

Typical current consumption of these devices ranges from tens to hundreds of milliamps. To correctly convert amps to milliamps, remember that the prefix "milli" means one thousandth of the base unit. You can use 10 -3 or 0.001 as the numerical factor. The use of such a multiple or fractional unit is quite acceptable and legalized by national legislation in the form of GOST 8.417-2002 “Interstate standard. Unit of quantity."

The abbreviated designation of the prefix “milli” in the Russian version is “m”, in the international version it is “m”. Therefore, it is quite clear that 1000 milliamps is equal to 1 ampere.

Multiples and submultiples [edit | edit code ]

In accordance with the full official description of the SI contained in the current edition of the SI Brochure (French Brochure SI, English The SI Brochure), published by the International Bureau of Weights and Measures (BIPM), decimal multiples and submultiples of the ampere are formed using standard SI prefixes [ 5] . “Regulations on units of quantities allowed for use in the Russian Federation”, adopted by the Government of the Russian Federation, provides for the use of the same prefixes in Russia [7].

MultiplesDolnye
magnitudeNamedesignationmagnitudeNamedesignation
10 1 AdekaampereyesAdaA10 −1 AdeciampereYesdA
10 2 AhectoamperegAhA10 −2 AcentiamperesAcA
10 3 AkiloamperekAkA10 −3 AmilliamperemAmA
10 6 AmegaampereMAM.A.10 −6 AmicroampereµAµA
10 9 AgigaampereGAGA10 −9 AnanoampereonnA
10 12 AteraampereTAT.A.10 −12 ApicoamperepApA
10 15 ApetaamperePAPA10−15 AfemtoampFfA
10 18 AexaampereEAE.A.10 −18 AattoampereaAaA
10 21 AzettaampereBEHINDZA10−21 AzeptoampbehindzA
10 24 AIottaampereIAYA10−24 AioctoampereiAyA
not recommended for use

How to correctly measure electric current in amperes

It should be clarified that current measurement is a measurement of its basic characteristics (force and voltage). Most often, in laboratory or school settings, the current strength is measured on a conductor or in the entire electrical circuit. For this, a special device is used - an ammeter. Which in the diagrams is correctly indicated by a circle with the Latin letter “A” inside.

When connecting an ammeter, the following rules must be observed:

  • Connect to the electrical circuit only in series with the section of the circuit where you want to measure the current. In other words, before or after the section of the circuit for measurements.
  • Be sure to pay attention to the “signs” of current in the circuit. We connect the plus wire from the power supply to the plus of the ammeter, and the minus to the minus.
  • Try not to exceed the value on the measurement scale, because in this case the device may not work. If the ammeter has two scales, use the one with the highest limit.


Diagram of the correct connection of an ammeter to an electrical circuit
When measuring resistance, it is recommended to take into account the internal resistance of the ammeter itself, which is indicated on it. But they are neglected at school.

Additional Information! For measurements, you can use a multimeter - a device that combines the functions of measuring force, power and other current parameters. For this, the same rules for including an ammeter in the circuit are used.

How to convert milliamps to amps and vice versa

When converting values ​​from one quantity to another, you must be able to work with powers and standard form of numbers in physics. It will be easier to translate if you know the correspondence between degrees and prefixes. It is recommended to master it.

To convert milliamps to amps, divide the available numeric value by 1000, or multiply by 10^-3 when working with a standard display. And to convert back, you must either multiply by 1000 or multiply the value by 10^3.

Example: How many amps are in 500 milliamps?

A milliamp is 1000 times smaller than an amp, so divide it by 1000; 500/1000 = 0.5. It turns out 0.5 A.


Converter

1 µA = 10^-6 A = 0.0000001 A. One microamp is less than one amp per million times. To convert the first value to the second, you will need to divide by 1,000,000 or multiply by 10^-6 A.

To convert microamps to milliamps, you need to consider that 1 mA = 1000 µA. The first algorithm will use the same steps in milliamps and amps to convert the values.

Electricity is a broad topic in physics; to understand it, you need to understand many processes and, most importantly, the basic unit that characterizes it - the ampere. And to correctly translate values, you need to know the accepted prefixes in SI and mathematics.

How to measure

In order to determine the current strength in a specific section of the circuit, the measuring instruments listed above are used. Among them, the most accurate is the ammeter, which measures only one value using one scale. However, testers and multimeters are considered more convenient, with the help of which they measure not only current strength, but also other electrical quantities in various ranges. These devices have the ability to switch from one unit of measurement to another and accurately determine how many milliamps are in an ampere.

Parameters of closing reed switches of standard and intermediate types

Name of reed switchKEM-1KEM-6MK-36701MKA-27101
Reed switch typestandardstandardaverageaverage
Effective magnetomotive force, A55… 11038… 5050… 8030… 60
Response time, ms3221.5
Maximum switching power, Wthirty1221 years old12
Maximum switching voltage, V220150100110
Maximum switching current, A10,250,350,35
Electrical resistance, V500500500
Electrical contact resistance, Ohm0,080,10,070,12
Maximum switching frequency, Hz100winds50100
Ambient temperature, ° C-60… + 125-60… + 125-60… + 100-60… + 100
Vibration loads, frequency range, Hz1… 6001… 501… 6001… 600
Vibration loads, maximum acceleration, m/s298989898
Cylinder diameter, total length, mm50/8036 / 63,536 / 63,527 / 45,6
Rating
( 1 rating, average 4 out of 5 )
Did you like the article? Share with friends:
For any suggestions regarding the site: [email protected]
Для любых предложений по сайту: [email protected]