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Electrical DC Waveform Frequency

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YogeshIJTSRD

One wave per second is also called a Hertz Hz and in SI units is a reciprocal second s 1 . The variable c is the speed of light. For the relationship to hold mathematically, if the speed of light is used in m s, the wavelength must be in meters and the frequency in Hertz. So what would be frequency of DC waveform weather it’s 0 HZ or more than 0 HZ up to 1 HZ Natvarbhai P Gajjar "Electrical DC Waveform Frequency" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-5 , August 2021, URL: https://www.ijtsrd.com/papers/ijtsrd45018.pdf Paper URL: https://www.ijtsrd.com/engineering/electrical-engineering/45018/electrical-dc-waveform-frequency/natvarbhai-p-gajjar

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International Journal of Trend in Scientific Research and Development (IJTSRD) Volume 5 Issue 5, July-August 2021 Available Online: www.ijtsrd.com e-ISSN: 2456 – 6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1041 Electrical DC Waveform Frequency Natvarbhai P Gajjar Retired Teacher, Ahmedabad, Gujarat, India ABSTRACT One wave per second is also called a Hertz (Hz) and in SI units is a reciprocal second (s−1 ). The variable c is the speed of light. For the relationship to hold mathematically, if the speed of light is used in m/s, the wavelength must be in meters and the frequency in Hertz. So what would be frequency of DC waveform weather it’s 0 HZ or more than 0 HZ up to 1 HZ? How to cite this paper: Natvarbhai P Gajjar "Electrical DC Waveform Frequency" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-5, August 2021, pp.1041-1045, URL: www.ijtsrd.com/papers/ijtsrd45018.pdf Copyright © 2021 by author (s) and International Journal of Trend in Scientific Research and Development Journal. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0) (http://creativecommons.org/licenses/by/4.0) We can understand by following below illustrations. Typical Examples of Electrical Waveform : In electronic circuits we need to produce many different types, frequencies and shapes of Signal Waveforms such as Square Waves, Rectangular Waves, Triangular Waves, Saw toothed Waveforms and a variety of pulses and spikes. These types of signal waveform can then be used for either timing signals, clock signals or as trigger pulses. However, before we can begin to look at how the different types of waveforms are produced, we firstly need to understand the basic characteristics that make up Electrical Waveforms. Technically speaking, Electrical Waveforms are basically visual representations of the variation of a voltage or current over time. In plain English this means that if we plotted these voltage or current variations on a piece of graph paper against a base (x- axis) of time, (t) the resulting plot or drawing would represent the shape of a Waveform as shown. There are many different types of electrical waveforms available but generally they can all be broken down into two distinctive groups. 1. Uni-directional Waveforms – these electrical waveforms are always positive or negative in nature flowing in one forward direction only as they do not cross the zero axis point. Common uni-directional waveforms include Square-wave timing signals, Clock pulses and Trigger pulses. 2. Bi-directional Waveforms – these electrical waveforms are also called alternating waveforms as they alternate from a positive direction to a negative direction constantly crossing the zero axis point. Bi-directional waveforms go through periodic changes in amplitude, with the most common by far being the Sine-wave. Whether the waveform is uni-directional, bi- directional, periodic, non-periodic, symmetrical, non- symmetrical, simple or complex, all electrical waveforms include the following three common characteristics: Period: – This is the length of time in seconds that the waveform takes to repeat itself from start to finish. This value can also be called the Periodic Time, (T) of the waveform for sine waves, or the Pulse Widthfor square waves. Frequency: – This is the number of times the waveform repeats itself within a one second time period. Frequency is the reciprocal of the time period, (ƒ = 1/T) with the standard unit of frequency being the Hertz, (Hz). IJTSRD45018
International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1042 Amplitude: – This is the magnitude or intensity of the signal waveform measured in volts or amps. We are taking examples of some Periodic Waveforms. Periodic waveforms are the most common of all the electrical waveforms as it includes Sine Waves. The AC (Alternating Current) mains waveform in your home is a sine wave and one which constantly alternates between a maximum value and a minimum value over time. The amount of time it takes between each individual repetition or cycle of a sinusoidal waveform is known as its “periodic time” or simply the Period of the waveform. In other words, the time it takes for the waveform to repeat itself. Then this period can vary with each waveform from fractions of a second to thousands of seconds as it depends upon the frequency of the waveform. For example, a sinusoidal waveform which takes one second to complete its cycle will have a periodic time of one second. Likewise a sine wave which takes five seconds to complete will have a periodic time of five seconds and so on. So, if the length of time it takes for the waveform to complete one full pattern or cycle before it repeats itself is known as the “period of the wave” and is measured in seconds, we can then express the waveform as a period number per second denoted by the letter T as shown below. A Sine Wave Waveform Units of periodic time, (T) include: Seconds (s ), milliseconds (ms) and microseconds (µs ). For sine wave waveforms only, we can also express the periodic time of the waveform in either degrees or radians, as one full cycle is equal to 360o (T = 360o ) or in Radians as 2pi, 2π (T = 2π ), then we can say that 2π radians = 360o – (Remember this! ). We now know that the time it takes for electrical waveforms to repeat themselves is known as the periodic time or period which represents a fixed amount of time. If we take the reciprocal of the period, (1/T) we end up with a value that denotes the number of times a period or cycle repeats itself in one second or cycles per second, and this is commonly known as Frequency with units of Hertz, (Hz). Then Hertz can also be defined as “cycles per second” (cps) and 1Hz is exactly equal to 1 cycle per second. Both period and frequency are mathematical reciprocals of each other and as the periodic time of the waveform decreases, its frequency increases and vice versa with the relationship between Periodic time and Frequency given as. Relationship between Frequency and Periodic Time Where: ƒ is in Hertz and T is in Seconds. One Hertz is exactly equal to one cycle per second, but one hertz is a very small unit so prefixes are used that denote the order of magnitude of the waveform such as kHz, MHz and even GHz.
International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1043 Square Wave Electrical Waveforms Square-wave Waveforms are used extensively in electronic and micro electronic circuits for clock and timing control signals as they are symmetrical waveforms of equal and square duration representing each half of a cycle and nearly all digital logic circuits use square wave waveforms on their input and output gates. Unlike sine waves which have a smooth rise and fall waveform with rounded corners at their positive and negative peaks, square waves on the other hand have very steep almost vertical up and down sides with a flat top and bottom producing a waveform which matches its description, – “Square” as shown below. A Square Wave Waveform We know that square shaped electrical waveforms are symmetrical in shape as each half of the cycle is identical, so the time that the pulse width is positive must be equal to the time that the pulse width is negative or zero. When square wave waveforms are used as “clock” signals in digital circuits the time of the positive pulse width is known as the “Duty Cycle” of the period. Then we can say that for a square wave waveform the positive or “ON” time is equal to the negative or “OFF” time so the duty cycle must be 50%, (half of its period). As frequency is equal to the reciprocal of the period, (1/T) we can define the frequency of a square wave waveform as: So, These are examples of some electronics waveforms of AC and DC supply. Now taking some examples from oscilloscope to find out actual frequency waveform of DC supply. This will help us to understand weather actual frequency of DC waveform is 0 HZ or above 0 HZ up to 1HZ. frequency vs length chart will help us to understand about actual distance travel by waveform according to frequency. Oscilloscope Screen Results : Fig (A) Fig(B) Fig(C)
International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1044 Figure (A) represent Sine wave at 50 HZ frequency. Figure (B) represent Square wave at 65 Hz frequency. Figure (C) represent Square wave at 1 HZ frequency. From following figure it can be understood that any wave(example sine wave or square wave) at 1 HZ frequency act as linear constant wave like DC waveform as shown in below mention figure DC circuits have a unidirectional flow of current and like AC it is not changing the direction periodically. Waveform of DC is a pure sine wave. As you can see, the voltage is constant with respect to time. . Frequency Vs Wavelength Chart: Frequency in Hz. Wavelength quarter wavelength 0 1 20 0000.00 1115.49 56.50 0000.00 278.87 14.13 Feet Feet Feet 25 45.2 11.3 feet 31.5 35.87 8.97 feet 40 28.25 7.06 feet 50 22.6 5.65 feet 63 17.94 4.48 feet 80 14.13 3.53 feet 100 11.3 2.83 feet 125 9.04 2.26 feet 160 7.06 1.77 feet 200 5.45 1.41 feet 250 4.52 1.13 feet 320 3.53 0.88 feet 400 2.83 0.71 feet 500 27.12 6.78 inches 640 21.19 5.3 inches 800 16.95 4.24 inches 1000 13.56 3.39 inches 1280 10.59 2.65 inches 1600 8.48 2.12 inches 2000 6.78 1.7 inches 2560 5.3 1.32 inches 3200 4.24 1.06 inches 4000 3.39 0.85 inches 5120 2.65 0.66 inches 6400 2.12 0.53 inches 8000 1.7 0.42 inches 10240 1.32 0.33 inches 12800 1.06 0.26 inches 16000 0.85 0.21 inches 20480 0.66 0.17 inches
International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1045 Conclusion: zero frequency means basically a constant term, no wave, no peaks passing you ever. Notice that the "wave" would have infinite period and wavelength, the time between peaks become infinite. The frequency of times you go to space is zero. A quantity oscillating with frequency equal to zero would simply be static or constant. When Time goes to infinity, it is not possible for an observer to see that the phenomenon is periodic. Firstly, in case of DC waveform. it is constant term with Wave. DC waveform travel some distance like 340 meter at 1HZ frequency(As shown in frequency vs wavelength chart). We have some distance within specific period of time. That travelling could not be possible at 0 HZ frequency. Secondly, Wave velocity means, distance traversed by a periodic, or cyclic, motion per unit time (in any direction). ... The velocity of a wave is equal to the product of its wavelength and frequency (number of vibrations per second) and is independent of its intensity. One wave per second is also called a Hertz (Hz) and in SI units is a reciprocal second (s−1 ). The variable c is the speed of light. For the relationship to hold mathematically, if the speed of light is used in m/s, the wavelength must be in meters and the frequency in Hertz. If we put 0 HZ frequency in this formula, wave velocity becomes Zero. That is contra verdict to previous statement. When we Put 1 HZ or below less than 0 HZ frequency, than we can find some distance within specific period of time. Finally, in my opinion it should not be 0 HZ, it should between 0 HZ< DC Waveform Frequency < = 1HZ frequency.

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Electrical DC Waveform Frequency

  • 1. International Journal of Trend in Scientific Research and Development (IJTSRD) Volume 5 Issue 5, July-August 2021 Available Online: www.ijtsrd.com e-ISSN: 2456 – 6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1041 Electrical DC Waveform Frequency Natvarbhai P Gajjar Retired Teacher, Ahmedabad, Gujarat, India ABSTRACT One wave per second is also called a Hertz (Hz) and in SI units is a reciprocal second (s−1 ). The variable c is the speed of light. For the relationship to hold mathematically, if the speed of light is used in m/s, the wavelength must be in meters and the frequency in Hertz. So what would be frequency of DC waveform weather it’s 0 HZ or more than 0 HZ up to 1 HZ? How to cite this paper: Natvarbhai P Gajjar "Electrical DC Waveform Frequency" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-5, August 2021, pp.1041-1045, URL: www.ijtsrd.com/papers/ijtsrd45018.pdf Copyright © 2021 by author (s) and International Journal of Trend in Scientific Research and Development Journal. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0) (http://creativecommons.org/licenses/by/4.0) We can understand by following below illustrations. Typical Examples of Electrical Waveform : In electronic circuits we need to produce many different types, frequencies and shapes of Signal Waveforms such as Square Waves, Rectangular Waves, Triangular Waves, Saw toothed Waveforms and a variety of pulses and spikes. These types of signal waveform can then be used for either timing signals, clock signals or as trigger pulses. However, before we can begin to look at how the different types of waveforms are produced, we firstly need to understand the basic characteristics that make up Electrical Waveforms. Technically speaking, Electrical Waveforms are basically visual representations of the variation of a voltage or current over time. In plain English this means that if we plotted these voltage or current variations on a piece of graph paper against a base (x- axis) of time, (t) the resulting plot or drawing would represent the shape of a Waveform as shown. There are many different types of electrical waveforms available but generally they can all be broken down into two distinctive groups. 1. Uni-directional Waveforms – these electrical waveforms are always positive or negative in nature flowing in one forward direction only as they do not cross the zero axis point. Common uni-directional waveforms include Square-wave timing signals, Clock pulses and Trigger pulses. 2. Bi-directional Waveforms – these electrical waveforms are also called alternating waveforms as they alternate from a positive direction to a negative direction constantly crossing the zero axis point. Bi-directional waveforms go through periodic changes in amplitude, with the most common by far being the Sine-wave. Whether the waveform is uni-directional, bi- directional, periodic, non-periodic, symmetrical, non- symmetrical, simple or complex, all electrical waveforms include the following three common characteristics: Period: – This is the length of time in seconds that the waveform takes to repeat itself from start to finish. This value can also be called the Periodic Time, (T) of the waveform for sine waves, or the Pulse Widthfor square waves. Frequency: – This is the number of times the waveform repeats itself within a one second time period. Frequency is the reciprocal of the time period, (ƒ = 1/T) with the standard unit of frequency being the Hertz, (Hz). IJTSRD45018
  • 2. International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1042 Amplitude: – This is the magnitude or intensity of the signal waveform measured in volts or amps. We are taking examples of some Periodic Waveforms. Periodic waveforms are the most common of all the electrical waveforms as it includes Sine Waves. The AC (Alternating Current) mains waveform in your home is a sine wave and one which constantly alternates between a maximum value and a minimum value over time. The amount of time it takes between each individual repetition or cycle of a sinusoidal waveform is known as its “periodic time” or simply the Period of the waveform. In other words, the time it takes for the waveform to repeat itself. Then this period can vary with each waveform from fractions of a second to thousands of seconds as it depends upon the frequency of the waveform. For example, a sinusoidal waveform which takes one second to complete its cycle will have a periodic time of one second. Likewise a sine wave which takes five seconds to complete will have a periodic time of five seconds and so on. So, if the length of time it takes for the waveform to complete one full pattern or cycle before it repeats itself is known as the “period of the wave” and is measured in seconds, we can then express the waveform as a period number per second denoted by the letter T as shown below. A Sine Wave Waveform Units of periodic time, (T) include: Seconds (s ), milliseconds (ms) and microseconds (µs ). For sine wave waveforms only, we can also express the periodic time of the waveform in either degrees or radians, as one full cycle is equal to 360o (T = 360o ) or in Radians as 2pi, 2π (T = 2π ), then we can say that 2π radians = 360o – (Remember this! ). We now know that the time it takes for electrical waveforms to repeat themselves is known as the periodic time or period which represents a fixed amount of time. If we take the reciprocal of the period, (1/T) we end up with a value that denotes the number of times a period or cycle repeats itself in one second or cycles per second, and this is commonly known as Frequency with units of Hertz, (Hz). Then Hertz can also be defined as “cycles per second” (cps) and 1Hz is exactly equal to 1 cycle per second. Both period and frequency are mathematical reciprocals of each other and as the periodic time of the waveform decreases, its frequency increases and vice versa with the relationship between Periodic time and Frequency given as. Relationship between Frequency and Periodic Time Where: ƒ is in Hertz and T is in Seconds. One Hertz is exactly equal to one cycle per second, but one hertz is a very small unit so prefixes are used that denote the order of magnitude of the waveform such as kHz, MHz and even GHz.
  • 3. International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1043 Square Wave Electrical Waveforms Square-wave Waveforms are used extensively in electronic and micro electronic circuits for clock and timing control signals as they are symmetrical waveforms of equal and square duration representing each half of a cycle and nearly all digital logic circuits use square wave waveforms on their input and output gates. Unlike sine waves which have a smooth rise and fall waveform with rounded corners at their positive and negative peaks, square waves on the other hand have very steep almost vertical up and down sides with a flat top and bottom producing a waveform which matches its description, – “Square” as shown below. A Square Wave Waveform We know that square shaped electrical waveforms are symmetrical in shape as each half of the cycle is identical, so the time that the pulse width is positive must be equal to the time that the pulse width is negative or zero. When square wave waveforms are used as “clock” signals in digital circuits the time of the positive pulse width is known as the “Duty Cycle” of the period. Then we can say that for a square wave waveform the positive or “ON” time is equal to the negative or “OFF” time so the duty cycle must be 50%, (half of its period). As frequency is equal to the reciprocal of the period, (1/T) we can define the frequency of a square wave waveform as: So, These are examples of some electronics waveforms of AC and DC supply. Now taking some examples from oscilloscope to find out actual frequency waveform of DC supply. This will help us to understand weather actual frequency of DC waveform is 0 HZ or above 0 HZ up to 1HZ. frequency vs length chart will help us to understand about actual distance travel by waveform according to frequency. Oscilloscope Screen Results : Fig (A) Fig(B) Fig(C)
  • 4. International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1044 Figure (A) represent Sine wave at 50 HZ frequency. Figure (B) represent Square wave at 65 Hz frequency. Figure (C) represent Square wave at 1 HZ frequency. From following figure it can be understood that any wave(example sine wave or square wave) at 1 HZ frequency act as linear constant wave like DC waveform as shown in below mention figure DC circuits have a unidirectional flow of current and like AC it is not changing the direction periodically. Waveform of DC is a pure sine wave. As you can see, the voltage is constant with respect to time. . Frequency Vs Wavelength Chart: Frequency in Hz. Wavelength quarter wavelength 0 1 20 0000.00 1115.49 56.50 0000.00 278.87 14.13 Feet Feet Feet 25 45.2 11.3 feet 31.5 35.87 8.97 feet 40 28.25 7.06 feet 50 22.6 5.65 feet 63 17.94 4.48 feet 80 14.13 3.53 feet 100 11.3 2.83 feet 125 9.04 2.26 feet 160 7.06 1.77 feet 200 5.45 1.41 feet 250 4.52 1.13 feet 320 3.53 0.88 feet 400 2.83 0.71 feet 500 27.12 6.78 inches 640 21.19 5.3 inches 800 16.95 4.24 inches 1000 13.56 3.39 inches 1280 10.59 2.65 inches 1600 8.48 2.12 inches 2000 6.78 1.7 inches 2560 5.3 1.32 inches 3200 4.24 1.06 inches 4000 3.39 0.85 inches 5120 2.65 0.66 inches 6400 2.12 0.53 inches 8000 1.7 0.42 inches 10240 1.32 0.33 inches 12800 1.06 0.26 inches 16000 0.85 0.21 inches 20480 0.66 0.17 inches
  • 5. International Journal of Trend in Scientific Research and Development @ www.ijtsrd.com eISSN: 2456-6470 @ IJTSRD | Unique Paper ID – IJTSRD45018 | Volume – 5 | Issue – 5 | Jul-Aug 2021 Page 1045 Conclusion: zero frequency means basically a constant term, no wave, no peaks passing you ever. Notice that the "wave" would have infinite period and wavelength, the time between peaks become infinite. The frequency of times you go to space is zero. A quantity oscillating with frequency equal to zero would simply be static or constant. When Time goes to infinity, it is not possible for an observer to see that the phenomenon is periodic. Firstly, in case of DC waveform. it is constant term with Wave. DC waveform travel some distance like 340 meter at 1HZ frequency(As shown in frequency vs wavelength chart). We have some distance within specific period of time. That travelling could not be possible at 0 HZ frequency. Secondly, Wave velocity means, distance traversed by a periodic, or cyclic, motion per unit time (in any direction). ... The velocity of a wave is equal to the product of its wavelength and frequency (number of vibrations per second) and is independent of its intensity. One wave per second is also called a Hertz (Hz) and in SI units is a reciprocal second (s−1 ). The variable c is the speed of light. For the relationship to hold mathematically, if the speed of light is used in m/s, the wavelength must be in meters and the frequency in Hertz. If we put 0 HZ frequency in this formula, wave velocity becomes Zero. That is contra verdict to previous statement. When we Put 1 HZ or below less than 0 HZ frequency, than we can find some distance within specific period of time. Finally, in my opinion it should not be 0 HZ, it should between 0 HZ< DC Waveform Frequency < = 1HZ frequency.