The calibration process begins with the design of the arithmetic measurement instrument that must be calibrated. The design has to be able to “withstand calibration” throughout its calibration interval. That is, the design must be capable of taking measurements that are within the “engineering tolerance” when used under ambient conditions for a reasonable period of time. The exact mechanism for assigning tolerance values ​​varies depending on the country or type of industry. In general, measurement equipment manufacturers assign measurement tolerances, suggest a calibration interval, and specify the range of normal use and storage. Having a design of these characteristics increases the probability that current measurement instruments will behave as expected. The next step is to define the calibration process. The selection of the standard or standards is the most visible part of the calibration process. Ideally, the standard must have less than a quarter of the measurement uncertainty that is given by the device to be calibrated.[6]​ The process consists of choosing a standard that meets the previously mentioned standard on measurement uncertainty and using it to compare its measurement with that of the calibrated device. After choosing a standard with a tighter degree of uncertainty and repeating the previous operation. This process is repeated until the standard with the greatest possible certainty is reached that is available in the calibration or metrology laboratory. This process establishes calibration traceability.

It must be said that this calibration process using standards is, practically always, preceded by a visual inspection of the instrument, where it is verified that it does not present any physical damage that can be seen with the naked eye. The results of this inspection are commonly referred to as the “as-found” inspection data. Normally the entire calibration process is entrusted to a single specialized technician who will be responsible for documenting that the calibration has been completed successfully.

The process that has been explained above is a difficult and expensive challenge. The cost of technical support for ordinary equipment is generally approximately 10% of the original purchase price on an annual basis. Other more exotic and/or complex machinery can be even more expensive to maintain.

The extent of the calibration program exposes the core beliefs of the organization involved. The integrity of the organization can easily be called into question depending on the calibration program that has been established. In general, each machine in an organization has a specific calibration process planned for it. For example, if a company has several of the same machines, the older machines will be used for the least demanding jobs and, therefore, will require limited calibration. Machines that are used frequently and on which the production process depends, on the other hand, will have to be calibrated more regularly and with fairly tight tolerances. On the other hand, each machine will have to be calibrated only in relation to the operation/task it performs. This means that although the machine can actually perform many more jobs than it actually does in the production process, only the work that it actually does actively has to be calibrated. The rest of the calibration processes will be unnecessary.

This process of choosing and designing the calibration process must be carried out for all the basic instruments that are present in the organization.

In order to improve the quality of the calibration in favor of external organizations accepting the results obtained, it is desirable that the corresponding measurements be easily convertible to the International System of Units. The action of establishing traceability can be carried out by making a formal comparison with a standard that may be directly or indirectly related to national standards, international standards or certified reference materials. Quality management systems require an effective metrology system that includes formal, periodic and documented calibration of all measuring instruments. The ISO 9000 and ISO 17025 standards establish that these actions have high traceability and indicate how it must be quantified.

To measure exteriors, the two long extensions are used, to measure interiors (for example, diameters of holes) the two short extensions, and to measure depths, a stem that comes out from the back and is called a depth probe. To carry out a measurement, the caliper will be adjusted to the object to be measured and fixed. The movable extension has a graduated scale (10, 20 or 50 divisions, depending on precision).

The measurement using this instrument is carried out in the following way: First, the moving part is made to slide so that the object to be measured is between the two extensions (if it is an exterior measurement). The mobile extension will indicate the whole millimeters that the measurement contains. The decimals will have to be found with the help of the vernier. For this purpose, it will be observed which division of the vernier coincides with a division (any) of those present in the fixed rule. This division will coincide with the decimal values ​​of the measurement being carried out.

The calibration process begins with the design of the arithmetic measurement instrument that must be calibrated. The design has to be able to “withstand calibration” throughout its calibration interval. That is, the design must be capable of taking measurements that are within the “engineering tolerance” when used under ambient conditions for a reasonable period of time. The exact mechanism for assigning tolerance values ​​varies depending on the country or type of industry. In general, measurement equipment manufacturers assign measurement tolerances, suggest a calibration interval, and specify the range of normal use and storage. Having a design of these characteristics increases the probability that current measurement instruments will behave as expected. The next step is to define the calibration process. The selection of the standard or standards is the most visible part of the calibration process. Ideally, the standard must have less than a quarter of the measurement uncertainty that is given by the device to be calibrated.[6]​ The process consists of choosing a standard that meets the previously mentioned standard on measurement uncertainty and using it to compare its measurement with that of the calibrated device. After choosing a standard with a tighter degree of uncertainty and repeating the previous operation. This process is repeated until the standard with the greatest possible certainty is reached that is available in the calibration or metrology laboratory. This process establishes calibration traceability.

It must be said that this calibration process using standards is, practically always, preceded by a visual inspection of the instrument, where it is verified that it does not present any physical damage that can be seen with the naked eye. The results of this inspection are commonly referred to as the “as-found” inspection data. Normally the entire calibration process is entrusted to a single specialized technician who will be responsible for documenting that the calibration has been completed successfully.

The process that has been explained above is a difficult and expensive challenge. The cost of technical support for ordinary equipment is generally approximately 10% of the original purchase price on an annual basis. Other more exotic and/or complex machinery can be even more expensive to maintain.

The extent of the calibration program exposes the core beliefs of the organization involved. The integrity of the organization can easily be called into question depending on the calibration program that has been established. In general, each machine in an organization has a specific calibration process planned for it. For example, if a company has several of the same machines, the older machines will be used for the least demanding jobs and, therefore, will require limited calibration. Machines that are used frequently and on which the production process depends, on the other hand, will have to be calibrated more regularly and with fairly tight tolerances. On the other hand, each machine will have to be calibrated only in relation to the operation/task it performs. This means that although the machine can actually perform many more jobs than it actually does in the production process, only the work that it actually does actively has to be calibrated. The rest of the calibration processes will be unnecessary.

This process of choosing and designing the calibration process must be carried out for all the basic instruments that are present in the organization.

In order to improve the quality of the calibration in favor of external organizations accepting the results obtained, it is desirable that the corresponding measurements be easily convertible to the International System of Units. The action of establishing traceability can be carried out by making a formal comparison with a standard that may be directly or indirectly related to national standards, international standards or certified reference materials. Quality management systems require an effective metrology system that includes formal, periodic and documented calibration of all measuring instruments. The ISO 9000 and ISO 17025 standards establish that these actions have high traceability and indicate how it must be quantified.

To measure exteriors, the two long extensions are used, to measure interiors (for example, diameters of holes) the two short extensions, and to measure depths, a stem that comes out from the back and is called a depth probe. To carry out a measurement, the caliper will be adjusted to the object to be measured and fixed. The movable extension has a graduated scale (10, 20 or 50 divisions, depending on precision).

The measurement using this instrument is carried out in the following way: First, the moving part is made to slide so that the object to be measured is between the two extensions (if it is an exterior measurement). The mobile extension will indicate the whole millimeters that the measurement contains. The decimals will have to be found with the help of the vernier. For this purpose, it will be observed which division of the vernier coincides with a division (any) of those present in the fixed rule. This division will coincide with the decimal values ​​of the measurement being carried out.