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Duty cycle

The duty cycle D is defined as the ratio between the pulse duration (\Tau) and the period (P) of a rectangular waveform
Spectrum in relation to duty cycle

A duty cycle is the percentage of one period in which a signal is active.[1][2][3] A period is the time it takes for a signal to complete an on-and-off cycle. As a formula, a duty cycle may be expressed as:

D = \frac{T}{P} \times 100\%[2]

where D is the duty cycle, T is the time the signal is active, and P is the total period of the signal. Thus, a 60% duty cycle means the signal is on 60% of the time but off 40% of the time. The "on time" for a 60% duty cycle could be a fraction of a second, a day, or even a week, depending on the length of the period.

Duty cycles can be used to describe the percent time of an active signal in an electrical device such as the power switch in a switching power supply or the firing of action potentials by a living system such as a neuron.[4][5]

Contents

  • Applications 1
    • Electrical devices 1.1
    • Biological systems 1.2
  • References 2

Applications

Electrical devices

Electrical motors typically use less than a 100% duty cycle. For example, if a motor runs for one out of 100 seconds, or 1/100 of the time, then, its duty cycle is 1/100, or 1 percent.[6]

In electronic music, music synthesizers vary the duty cycle of their audio-frequency oscillators to obtain a subtle effect on the tone colors. This technique is known as pulse-width modulation (PWM).

In the printer / copier industry, the duty cycle specification refers to the rated throughput (that is, printed pages) of a device per month.

In a welding power supply, the maximum duty cycle is defined as the percentage of time in a 10 minute period that it can be operated continuously before overheating.[7]

Biological systems

The concept of duty cycles is also used to describe the activity of neurons and muscle fibers. In a neural network for example, a duty cycle specifically refers to the proportion of a cycle period in which a neuron remains active.[5]

References

  1. ^ Barrett, Steven Frank; Pack, Daniel J. (2006). "Timing subsystem". Microcontrollers Fundamentals for Engineers and Scientists. Morgan and Claypool Publishers. pp. 51–64.  
  2. ^ a b Cox, James F.; Chartrand, Leo (June 26, 2001). "Nonsinusoidal oscillators". Fundamentals of Linear Electronics: Integrated and Discrete (2 ed.). Cengage Learning. pp. 511–584.  
  3. ^ """Federal Standard 1037C, "Telecommunications: Glossary of Telecommunication Terms. Boulder, Colorado: Institute for Telecommunication Sciences. 1996. Retrieved March 3, 2011. 
  4. ^ Brown, Martin (1990). "How a switching power supply works". Practical Switching Power Supply Design (Motorola Series in Solid State Electronics). San Diego, CA: Academic Press. pp. 87–139.  
  5. ^ a b Harris-Warrick, Ronald; Nagy, Frédéric; Nusbaum, Michael (1992). Harris-Warrick, Ronald; Marder, Eve; Silverston, Alan et al., eds. Dynamic biological networks: the stomatogastric nervous system. Massachusetts: MIT Press. pp. 87–139.  
  6. ^ "Electric Motors". Machine Design. Retrieved March 23, 2011. 
  7. ^ "What does the term duty cycle mean?". ZENA, Inc. welding systems. Retrieved March 23, 2011. 
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