The Second World War marked the development of new weapons and complex machines, and new demands on the cognition of operators also arose. The machine operator's decision making, attention, situational awareness, and hand-eye coordination became the key to the success or failure of a task. It was observed that fully operational planes, flown by trained pilots, suffered air accidents. In 1943, Alphonse Chapanis, a lieutenant in the US Army, showed that this so-called "pilot error" could be greatly reduced when controls were replaced by more logical and less confusing layouts in the aircraft cockpit.

In the decades since the war, ergonomics has continued to flourish and diversify. The space age has created new human factors problems, such as weightlessness and G-forces. How far could the human body tolerate these environments in outer space, and what effects would they have on the mind and body? The dawn of the information age has translated into the field of ergonomics as human-computer interaction (HCI).

The coining of long-term ergonomics, however, is widely attributed to British psychologist Hywel Murrell"), at the 1949 meeting at the Navy Office in the United Kingdom, which led to the founding of the Spanish Ergonomics Society[5]​ created in the late 1980s.[6]​ He used it to encompass the studies in which they had participated.

Later, in the 19th century, Frederick Winslow Taylor pioneered Scientific Labor Administration (Taylorism), a method that proposes how to find the optimal method to carry out a given task. Taylor discovered that he could, for example, triple the amount of coal that workers were shoveling, gradually enlarging the size and reducing the weight of the coal shovels until the fastest rate of shoveling was achieved. Frank and Lillian Gilbreth expanded on Taylor's methods in the 1900s to develop "The Study of Time and Motion." Their goal was to improve efficiency by eliminating unnecessary steps. By applying this approach, the Gilbreths reduced the number of moves in masonry from 18 to 4.5, allowing bricklayers to increase their productivity from 120 to 350 bricks per hour.

The Second World War marked the development of new weapons and complex machines, and new demands on the cognition of operators also arose. The machine operator's decision making, attention, situational awareness, and hand-eye coordination became the key to the success or failure of a task. It was observed that fully operational planes, flown by trained pilots, suffered air accidents. In 1943, Alphonse Chapanis, a lieutenant in the US Army, showed that this so-called "pilot error" could be greatly reduced when controls were replaced by more logical and less confusing layouts in the aircraft cockpit.

In the decades since the war, ergonomics has continued to flourish and diversify. The space age has created new human factors problems, such as weightlessness and G-forces. How far could the human body tolerate these environments in outer space, and what effects would they have on the mind and body? The dawn of the information age has translated into the field of ergonomics as human-computer interaction (HCI).

The coining of long-term ergonomics, however, is widely attributed to British psychologist Hywel Murrell"), at the 1949 meeting at the Navy Office in the United Kingdom, which led to the founding of the Spanish Ergonomics Society[5]​ created in the late 1980s.[6]​ He used it to encompass the studies in which they had participated.

For example, a worker will be able to withstand a force level of 50% of maximum force for only about a minute:.

Whether repeated static contractions are performed (such as holding a load with a flexed elbow) or a series of dynamic work elements (such as moving a lever with arms or legs), work and recovery must be assigned in short and frequent cycles (Active Micro Pauses).[16]​ This is due, first of all, to a rapid initial recovery period, which then tends to level out. Thus, most of the benefit is obtained in a relatively short period.

A program of carrying out Active Breaks within the worker's working hours allows improving motor skills, increasing speed, coordination and, above all, aerobic capacity. Its objectives are:

Active pauses allow:

If the worker reaches complete muscle (or whole-body) fatigue, full recovery will require a longer time, perhaps several hours.[15]​.

For a given group of muscles, there is a considerable range of strength in the normal, healthy adult population, with the strongest being five to eight times stronger than the weakest. The difference is greater for the strength of the upper extremities and less in the lower extremities. However, the primary cause of this effect is body size (i.e., total muscle mass) and not just sex; The average woman is considerably smaller and lighter than the average man. Furthermore, with the wide distribution for the strength of a given muscle, there are many women stronger than many men. In terms of age, muscle strength appears to peak around age 25 and then decrease linearly by 20 to 25% by age 60. The decrease in strength is due to the reduction of muscle mass and the loss of muscle fibers.[15]​.

Muscle contractions are initiated by neuronal innervation from the brain and spine, which together form the central nervous system. The electrical activity of muscles, called electromyogram (EMG), is a useful measure of local muscle activity. A typical motor neuron or nerve cell that reaches the muscle from the central nervous system may have connections with several hundred muscle fibers. The innervation rate of the number of fibers per neuron ranges from less than 10 in small eye muscles to more than 1000 in large muscles and can vary considerably even within the same muscles. This functional arrangement is called motor unit and has important implications in the control of movement.[15]​.

Lifting containers with heavy parts requires targeting small motor units as well as large ones to generate the necessary muscle forces. During lifting and refueling, some motor units become fatigued and others are selected to compensate. When the operator finishes replenishing containers and returns to precise assembly work, some motor units, including small precision ones, are not available. That is, using large muscles in the first instance to perform heavy tasks at the workstation will cause that when fine control movements are used to execute precision tasks, the muscular response will not be correct because there is already greater prior fatigue.

Cross innervation of agonists and antagonists always occurs through spinal reflexes. This minimizes unnecessary conflict between the muscles, as well as the resulting excessive energy expenditure.

That is, it is preferable to use movements that describe a ballistic or parabola-shaped trajectory, from the center to the outside and from the outside to the center, than inaccurate movements with sudden and abrupt changes.

When the right hand works in its normal area to the right of the body and the left hand works in its normal area, to the left of the body, the feeling of balance tends to induce a rhythm in the operator's performance, which leads to maximum productivity. The left hand on right people can be as effective as the right and should be used. Both hands should not be left idle, except during rest periods.

It is natural for both hands to move in symmetrical patterns. Deviations from the symmetry of a two-handed workstation lead to uncomfortable movements of the operator. Many people are familiar with the difficulty of tapping the stomach with the left hand and rubbing the top of the head with the right. Another experiment that illustrates the difficulty of performing non-symmetrical operations is trying to draw a circle with your left hand and a square with your right.

Spinal reflexes that excite or inhibit muscles also lead to natural rhythms in the movement of body segments that can be compared to second-order mass-spring-damper systems, where the body segments provide the mass and the muscle has internal resistance and damping.

Natural frequency is essential for the smooth and automatic performance of a task. Drillis (1963) studied a variety of very common manual tasks and suggested optimal work times, as follows:.

Due to the nature of the ligaments that join body segments (approximating dowel joints), it is easier for people to produce curved movements, that is, pivoting around a joint. Straight-line movements that involve sharp, sudden changes in direction take more time and are less precise. This law is easily demonstrated by moving either hand in a rectangular pattern, and then in a circular pattern of approximate magnitudes.

Continuous curved movements do not require deceleration and, consequently, are performed faster per unit of distance.

This classification of movements finally ends up becoming a fundamental law of the economy of movements, to execute an adequate study of methods.

Class one moves require the least effort and time, while class five moves are considered the least efficient. Thus, the minor grading motion should always be used to do adequate work.

Since the hands are more dexterous than the feet, it would be unwise to make the feet work while the hands are still. Devices such as pedals can often be arranged to allow for clamping, ejection or feeding, freeing up the hands for other more useful work and consequently decreasing cycle time. When the hands move, the feet should not move, since simultaneous movement of hands and feet is difficult; but the feet may be applying pressure on something like a pedal. Furthermore, the operator must be seated, since it is not easy to operate a foot pedal, and support the entire weight of the body on the other foot.

These principles also apply to the seated work station. Many tasks, such as writing or light assembly, are best performed at resting elbow height. If the work requires the perception of fine detail, it may be necessary to elevate the work so that it is closer to the eyes. Seated work stations should have adjustable chairs and footrests. Ideally, once the operator is seated comfortably with both feet on the ground, the work surface is positioned at the appropriate elbow height to adjust the operation. Thus, the workstation also needs to be adjustable. Short operators, whose feet do not reach the floor even after adjusting the seat, should use a foot rest that provides appropriate support.

Sitting posture[17]​ is important from the point of view of reducing both stress on the feet and overall energy expenditure. Because comfort is an individual response, it is quite difficult to establish strict principles for sitting well. Furthermore, few chairs will accommodate the comfort of many possible sitting postures. It is very important to provide lumbar support through a bump on the back of the chair or with a lumbar cushion placed at belt level. provide easy adjustment for specific seat parameters. Height is the most critical, where the ideal is determined by the person's popliteal height. A seat that is too high will uncomfortably compress the lower thighs, decrease the angle of the trunk and, again, increase the pressure on the discs. In addition, elbow pads are recommended to provide support for shoulders, arms and footrests in the case of shorter individuals. In general, chairs should have a soft contour, a padded seat and covered with a fabric that allows air to pass through to prevent moisture from sweat. A seat with a cushion that is too soft restricts posture and can restrict circulation in the legs.

The height of the workstation should be adjusted so that it is possible to work efficiently whether standing or sitting. The human body is not designed to sit for long periods of time. The discs between the vertebrae do not have a blood supply on their own; they depend on pressure changes that result from movement to receive nutrients and eliminate waste. Stiff posture also reduces blood flow to the muscles and induces muscle fatigue and cramps.

Different researchers[18] report that more than a third of all workers have to work standing or walking for periods greater than four hours a day. Prolonged standing, defined as standing for more than two hours a day, has been linked to different health problems, such as:

People who stand for 45 to 50% of their work day have foot and leg discomfort and those who stand for more than 25% of their work day have low back pain (Rys 1994).

It is tiring to stand for long periods on a cement floor. Operators should be provided with elastic anti-fatigue mats that allow small muscle contractions in the legs, forcing blood to move and prevent it from pooling in the lower extremities.

A distance intervenes in each movement. The greater the distance, the greater the muscular effort, control and time. Therefore, it is important to minimize distances. The normal working area of ​​the right hand in the horizontal plane includes the area circumscribed by the forearm when moved in an arc with a pivot at the elbow. This area represents the most convenient zone within which the hand performs movements with a normal expenditure of energy. The normal area of ​​the left hand is established in a similar way. Since the movements are made in the third dimension, as well as in the horizontal plane, the normal work area also applies to the vertical plane.

When driving a car, we are all familiar with the short time it takes to apply your foot to the brake. The reason is obvious: since the brake pedal has a fixed position, it does not take time to decide where it is located. The body responds instinctively and applies pressure to the area where the driver knows the brake pedal is located. If its location changed, the driver would need much more time to stop the car. Likewise, providing fixed locations for all tools and materials at the workstation eliminates, or at least minimizes, the minor guesswork required to search for and select the objects needed to do the job.

Gravity chutes make a clean work area possible, as the finished material is sent outside, rather than piled up around it. A container elevated above the work surface (so that the hand can slide material under it will also decrease the time required to perform this task by 10 to 15 percent. Gravity chutes allow finished parts to be sent within the normal area and eliminate the need for distant movements.

The optimal arrangement depends on many characteristics, both human (strength, reach, senses) and task (loads, repetition, orientation). It is obvious that not all factors can be optimized. The designer must establish priorities in the distribution of the work area. Once the location has been determined for a group of components, that is, the parts most frequently used for assembly, the principles of functionality and sequence of use must be taken into account. Functionality refers to the grouping of components according to the similarity of their function, for example, all fasteners in one area, all gaskets and rubber components in another area. It is very important to place the components or subassemblies in the order in which they are assembled, as this will have a great effect on reducing wasteful movement.

The most efficient advanced production planning for manufacturing includes making multiple cuts with combination tools and simultaneous cuts with different tools. Of course, the type of work to be processed and the number of parts to be produced determines whether it is desirable to combine the cuts, as in the case of cuts with a square and hexagonal tower.

If either hand is used for holding during processing of a part, then the hand is not doing useful work. A device can always be designed to hold work satisfactorily, and allow both hands to do useful work. The devices not only save part processing time, but also allow work to be held more accurately and firmly. Many times, foot-operated mechanisms allow both hands to do productive work.

Many machine tools and other devices are perfect in the mechanical sense, but do not provide effective operation, because the designer of the installation did not take into account the different human factors. Handwheels, cranks and levers must be of adequate size and position so that the operator can manipulate them with maximum skill and minimum fatigue. Controls that are often used should be placed between elbow and shoulder height. Seated operators can apply maximum force to the levers at elbow level; standing operators, to levers that are shoulder height. The diameter of the steering wheels and handlebars depends on the torque that must be applied and the mounted position.

Shape codes, with two- or three-dimensional geometric configurations, allow for both tactile and visual identification. It is useful, especially in low light conditions, or in situations where redundancy or duplicate quality in identification is desired, to help minimize errors. Multi-rotation knobs are used for continuous controls where the adjustment range is greater than one full turn. Fractional rotation knobs are used for continuous controls with intervals less than one turn, while positioning knobs are used for discrete adjustments.

In their work assignments, operators use various types of controls and control designs all the time. The three parameters that have a great impact on performance are:.

A control that is too small or too large cannot be activated efficiently.

Compatibility is defined as the relationship between controls and displays that is consistent with human expectations. The basic principles include:

so that the operator knows that the function has been achieved.

For example, a good performance is a door with a pull-open handle or a door with a push-open plate. Space mapping is observed in well-designed stoves. Movement compatibility is provided with direct action, reading scales that increase from left to right, and clockwise movements that increase adjustment. For circular displays, the best compatibility is achieved with a fixed scale and moving pointers or needles.

In horizontal or vertical screens the Warrick principle is used, which says that the closest pointers on the screen and the control movement in the same direction provide the best compatibility. (Sanders and McCormick, 1993).

The noise dose that is above 80 dBA causes anyone listening to that amount to be affected by a partial dose. If said total daily exposure consists of several partial exposures to different noise levels, the partial doses are added to obtain a combined exposure:.

D = 100

Where:

D = noise dose

C = time spent under the effects of a specific noise level (h)

T = time allowed under the effects of a specific noise level (h).

The total exposure to different noise levels cannot be exceeded at a dose of 100%.

Noise exposures allowed.

When daily noise exposure is composed of two or more periods of noise exposure of different levels, their combined effect should be considered rather than the independent effects of each of them. If the sum of the following fractions C1/T1 + C2/T2 + … + Cn/Tn exceeds unity, the combined exposure must be considered to exceed the maximum value. Cn indicates the total exposure time to a specific noise level, while Tn is equal to the total exposure time allowed during a workday.

Exposure to impact noise should not exceed the peak sound pressure level of 140 dB.

For example, a worker will be able to withstand a force level of 50% of maximum force for only about a minute:.

Whether repeated static contractions are performed (such as holding a load with a flexed elbow) or a series of dynamic work elements (such as moving a lever with arms or legs), work and recovery must be assigned in short and frequent cycles (Active Micro Pauses).[16]​ This is due, first of all, to a rapid initial recovery period, which then tends to level out. Thus, most of the benefit is obtained in a relatively short period.

A program of carrying out Active Breaks within the worker's working hours allows improving motor skills, increasing speed, coordination and, above all, aerobic capacity. Its objectives are:

Active pauses allow:

If the worker reaches complete muscle (or whole-body) fatigue, full recovery will require a longer time, perhaps several hours.[15]​.

For a given group of muscles, there is a considerable range of strength in the normal, healthy adult population, with the strongest being five to eight times stronger than the weakest. The difference is greater for the strength of the upper extremities and less in the lower extremities. However, the primary cause of this effect is body size (i.e., total muscle mass) and not just sex; The average woman is considerably smaller and lighter than the average man. Furthermore, with the wide distribution for the strength of a given muscle, there are many women stronger than many men. In terms of age, muscle strength appears to peak around age 25 and then decrease linearly by 20 to 25% by age 60. The decrease in strength is due to the reduction of muscle mass and the loss of muscle fibers.[15]​.

Muscle contractions are initiated by neuronal innervation from the brain and spine, which together form the central nervous system. The electrical activity of muscles, called electromyogram (EMG), is a useful measure of local muscle activity. A typical motor neuron or nerve cell that reaches the muscle from the central nervous system may have connections with several hundred muscle fibers. The innervation rate of the number of fibers per neuron ranges from less than 10 in small eye muscles to more than 1000 in large muscles and can vary considerably even within the same muscles. This functional arrangement is called motor unit and has important implications in the control of movement.[15]​.

Lifting containers with heavy parts requires targeting small motor units as well as large ones to generate the necessary muscle forces. During lifting and refueling, some motor units become fatigued and others are selected to compensate. When the operator finishes replenishing containers and returns to precise assembly work, some motor units, including small precision ones, are not available. That is, using large muscles in the first instance to perform heavy tasks at the workstation will cause that when fine control movements are used to execute precision tasks, the muscular response will not be correct because there is already greater prior fatigue.

Cross innervation of agonists and antagonists always occurs through spinal reflexes. This minimizes unnecessary conflict between the muscles, as well as the resulting excessive energy expenditure.

That is, it is preferable to use movements that describe a ballistic or parabola-shaped trajectory, from the center to the outside and from the outside to the center, than inaccurate movements with sudden and abrupt changes.

When the right hand works in its normal area to the right of the body and the left hand works in its normal area, to the left of the body, the feeling of balance tends to induce a rhythm in the operator's performance, which leads to maximum productivity. The left hand on right people can be as effective as the right and should be used. Both hands should not be left idle, except during rest periods.

It is natural for both hands to move in symmetrical patterns. Deviations from the symmetry of a two-handed workstation lead to uncomfortable movements of the operator. Many people are familiar with the difficulty of tapping the stomach with the left hand and rubbing the top of the head with the right. Another experiment that illustrates the difficulty of performing non-symmetrical operations is trying to draw a circle with your left hand and a square with your right.

Spinal reflexes that excite or inhibit muscles also lead to natural rhythms in the movement of body segments that can be compared to second-order mass-spring-damper systems, where the body segments provide the mass and the muscle has internal resistance and damping.

Natural frequency is essential for the smooth and automatic performance of a task. Drillis (1963) studied a variety of very common manual tasks and suggested optimal work times, as follows:.

Due to the nature of the ligaments that join body segments (approximating dowel joints), it is easier for people to produce curved movements, that is, pivoting around a joint. Straight-line movements that involve sharp, sudden changes in direction take more time and are less precise. This law is easily demonstrated by moving either hand in a rectangular pattern, and then in a circular pattern of approximate magnitudes.

Continuous curved movements do not require deceleration and, consequently, are performed faster per unit of distance.

This classification of movements finally ends up becoming a fundamental law of the economy of movements, to execute an adequate study of methods.

Class one moves require the least effort and time, while class five moves are considered the least efficient. Thus, the minor grading motion should always be used to do adequate work.

Since the hands are more dexterous than the feet, it would be unwise to make the feet work while the hands are still. Devices such as pedals can often be arranged to allow for clamping, ejection or feeding, freeing up the hands for other more useful work and consequently decreasing cycle time. When the hands move, the feet should not move, since simultaneous movement of hands and feet is difficult; but the feet may be applying pressure on something like a pedal. Furthermore, the operator must be seated, since it is not easy to operate a foot pedal, and support the entire weight of the body on the other foot.

These principles also apply to the seated work station. Many tasks, such as writing or light assembly, are best performed at resting elbow height. If the work requires the perception of fine detail, it may be necessary to elevate the work so that it is closer to the eyes. Seated work stations should have adjustable chairs and footrests. Ideally, once the operator is seated comfortably with both feet on the ground, the work surface is positioned at the appropriate elbow height to adjust the operation. Thus, the workstation also needs to be adjustable. Short operators, whose feet do not reach the floor even after adjusting the seat, should use a foot rest that provides appropriate support.

Sitting posture[17]​ is important from the point of view of reducing both stress on the feet and overall energy expenditure. Because comfort is an individual response, it is quite difficult to establish strict principles for sitting well. Furthermore, few chairs will accommodate the comfort of many possible sitting postures. It is very important to provide lumbar support through a bump on the back of the chair or with a lumbar cushion placed at belt level. provide easy adjustment for specific seat parameters. Height is the most critical, where the ideal is determined by the person's popliteal height. A seat that is too high will uncomfortably compress the lower thighs, decrease the angle of the trunk and, again, increase the pressure on the discs. In addition, elbow pads are recommended to provide support for shoulders, arms and footrests in the case of shorter individuals. In general, chairs should have a soft contour, a padded seat and covered with a fabric that allows air to pass through to prevent moisture from sweat. A seat with a cushion that is too soft restricts posture and can restrict circulation in the legs.

The height of the workstation should be adjusted so that it is possible to work efficiently whether standing or sitting. The human body is not designed to sit for long periods of time. The discs between the vertebrae do not have a blood supply on their own; they depend on pressure changes that result from movement to receive nutrients and eliminate waste. Stiff posture also reduces blood flow to the muscles and induces muscle fatigue and cramps.

Different researchers[18] report that more than a third of all workers have to work standing or walking for periods greater than four hours a day. Prolonged standing, defined as standing for more than two hours a day, has been linked to different health problems, such as:

People who stand for 45 to 50% of their work day have foot and leg discomfort and those who stand for more than 25% of their work day have low back pain (Rys 1994).

It is tiring to stand for long periods on a cement floor. Operators should be provided with elastic anti-fatigue mats that allow small muscle contractions in the legs, forcing blood to move and prevent it from pooling in the lower extremities.

A distance intervenes in each movement. The greater the distance, the greater the muscular effort, control and time. Therefore, it is important to minimize distances. The normal working area of ​​the right hand in the horizontal plane includes the area circumscribed by the forearm when moved in an arc with a pivot at the elbow. This area represents the most convenient zone within which the hand performs movements with a normal expenditure of energy. The normal area of ​​the left hand is established in a similar way. Since the movements are made in the third dimension, as well as in the horizontal plane, the normal work area also applies to the vertical plane.

When driving a car, we are all familiar with the short time it takes to apply your foot to the brake. The reason is obvious: since the brake pedal has a fixed position, it does not take time to decide where it is located. The body responds instinctively and applies pressure to the area where the driver knows the brake pedal is located. If its location changed, the driver would need much more time to stop the car. Likewise, providing fixed locations for all tools and materials at the workstation eliminates, or at least minimizes, the minor guesswork required to search for and select the objects needed to do the job.

Gravity chutes make a clean work area possible, as the finished material is sent outside, rather than piled up around it. A container elevated above the work surface (so that the hand can slide material under it will also decrease the time required to perform this task by 10 to 15 percent. Gravity chutes allow finished parts to be sent within the normal area and eliminate the need for distant movements.

The optimal arrangement depends on many characteristics, both human (strength, reach, senses) and task (loads, repetition, orientation). It is obvious that not all factors can be optimized. The designer must establish priorities in the distribution of the work area. Once the location has been determined for a group of components, that is, the parts most frequently used for assembly, the principles of functionality and sequence of use must be taken into account. Functionality refers to the grouping of components according to the similarity of their function, for example, all fasteners in one area, all gaskets and rubber components in another area. It is very important to place the components or subassemblies in the order in which they are assembled, as this will have a great effect on reducing wasteful movement.

The most efficient advanced production planning for manufacturing includes making multiple cuts with combination tools and simultaneous cuts with different tools. Of course, the type of work to be processed and the number of parts to be produced determines whether it is desirable to combine the cuts, as in the case of cuts with a square and hexagonal tower.

If either hand is used for holding during processing of a part, then the hand is not doing useful work. A device can always be designed to hold work satisfactorily, and allow both hands to do useful work. The devices not only save part processing time, but also allow work to be held more accurately and firmly. Many times, foot-operated mechanisms allow both hands to do productive work.

Many machine tools and other devices are perfect in the mechanical sense, but do not provide effective operation, because the designer of the installation did not take into account the different human factors. Handwheels, cranks and levers must be of adequate size and position so that the operator can manipulate them with maximum skill and minimum fatigue. Controls that are often used should be placed between elbow and shoulder height. Seated operators can apply maximum force to the levers at elbow level; standing operators, to levers that are shoulder height. The diameter of the steering wheels and handlebars depends on the torque that must be applied and the mounted position.

Shape codes, with two- or three-dimensional geometric configurations, allow for both tactile and visual identification. It is useful, especially in low light conditions, or in situations where redundancy or duplicate quality in identification is desired, to help minimize errors. Multi-rotation knobs are used for continuous controls where the adjustment range is greater than one full turn. Fractional rotation knobs are used for continuous controls with intervals less than one turn, while positioning knobs are used for discrete adjustments.

In their work assignments, operators use various types of controls and control designs all the time. The three parameters that have a great impact on performance are:.

A control that is too small or too large cannot be activated efficiently.

Compatibility is defined as the relationship between controls and displays that is consistent with human expectations. The basic principles include:

so that the operator knows that the function has been achieved.

For example, a good performance is a door with a pull-open handle or a door with a push-open plate. Space mapping is observed in well-designed stoves. Movement compatibility is provided with direct action, reading scales that increase from left to right, and clockwise movements that increase adjustment. For circular displays, the best compatibility is achieved with a fixed scale and moving pointers or needles.

In horizontal or vertical screens the Warrick principle is used, which says that the closest pointers on the screen and the control movement in the same direction provide the best compatibility. (Sanders and McCormick, 1993).

The noise dose that is above 80 dBA causes anyone listening to that amount to be affected by a partial dose. If said total daily exposure consists of several partial exposures to different noise levels, the partial doses are added to obtain a combined exposure:.

D = 100

Where:

D = noise dose

C = time spent under the effects of a specific noise level (h)

T = time allowed under the effects of a specific noise level (h).

The total exposure to different noise levels cannot be exceeded at a dose of 100%.

Noise exposures allowed.

When daily noise exposure is composed of two or more periods of noise exposure of different levels, their combined effect should be considered rather than the independent effects of each of them. If the sum of the following fractions C1/T1 + C2/T2 + … + Cn/Tn exceeds unity, the combined exposure must be considered to exceed the maximum value. Cn indicates the total exposure time to a specific noise level, while Tn is equal to the total exposure time allowed during a workday.

Exposure to impact noise should not exceed the peak sound pressure level of 140 dB.