13 July 2023
Redshift due to motion, when phase shift T(deg) of the observed frequency and the source frequency f(rest) are know.:
A 1° phase shift in the wave oscillation is due to motion, we can calculate the redshift using the formula.
12 July 2023
Frequency and phase in sin:
The equation y(x) = sin(f * x + p). What does f represent and what does p represent?
In the equation y(x) = sin(f * x + p), the variables f and p represent parameters that affect the behavior of the sine function.
f: The variable f represents the frequency of the sine wave. It determines how many oscillations occur over a given interval of x values. The frequency f controls the rate at which the sine function completes a full period, which is 2π radians or 360 degrees. Higher values of f result in more oscillations within the same interval, while lower values lead to fewer oscillations.
p: The variable p represents the phase shift of the sine wave. It indicates the horizontal displacement or translation of the wave along the x-axis. Specifically, it determines the initial position of the wave at x = 0. The phase shift p is measured in radians or degrees and can move the wave to the left or right. Positive values of p shift the wave to the left, while negative values shift it to the right.
By adjusting the values of f and p, you can modify the frequency and position of the sine wave, respectively, in the y(x) equation.
Equations of f frequency; T time period; v velocity; λ wavelength; λ₀ source wavelength; Δλ changed wavelength; T(deg) phase shift in degree; z gravitational or cosmic redshift:
Given below are the simplified expressions based on the equation and the relationship between the variables. Where, f is the frequency; T time period; v velocity; λ is the wavelength; λ₀ is the source wavelength; Δλ observed change in wavelength; T(deg) phase shift in degree; z gravitational/cosmic redshift. When, f = 1/T = v/λ = v/λ₀; T(360) => T(deg) = z * 360; For 1° phase shift, T(deg) = T/360 = (1/f)/360 = z * 360; z = Δλ/λ₀.
- f is the frequency.
- We are given f = 1/T = v/λ = v/λ₀.
- Therefore, frequency f is equal to the reciprocal of the time period T, the velocity v divided by the wavelength λ, and also v divided by the source wavelength λ₀
- The specific velocities of the waves involved (343 m/s) for acoustic waves or (299,792,458 m/s) for electromagnetic waves.
- T time period.
- We are given a complete time period T in 360°, T(360) => T(deg) = z * 360.
- This equation represents the phase shift in degrees T(deg) being equal to the gravitational or cosmic redshift z multiplied by 360.
- For a complete time period T, the phase shift in degrees T(deg) is equal to z * 360, where z represents the gravitational or cosmic redshift.
- v velocity
- We are given v/λ = f = 1/T = v/λ₀.
- From these equations, we can see that v is equal to the product of the frequency f and the wavelength λ, and it is also equal to the product of the frequency f and the source wavelength λ₀.
- The specific velocities for acoustic waves (343 m/s) and electromagnetic waves (299,792,458 m/s) indicate the speed at which the waves propagate.
- λ is the wavelength
- We are given v/λ = f = 1/T = v/λ₀.
- This equation indicates that the wavelength λ is equal to the velocity v divided by the frequency f, and it is also equal to the source wavelength λ₀.
- The wavelength (λ) is related to the velocity (v) and frequency (f) through the equation λ = v/f. Using the specific velocities provided, the wavelength can be calculated by λ = v/f.
- λ₀ is the source wavelength
- We are given v/λ₀ = v/λ = f = 1/T.
- Therefore, the source wavelength λ₀ is equal to the velocity v divided by the frequency f, and it is also equal to the wavelength λ.
- The source wavelength (λ₀) can be obtained by dividing the velocity (v) by the frequency (f), using the specific velocities given. Thus, λ₀ = v/f.
- Δλ observed change in wavelength
- We are given z = Δλ/λ₀.
- This equation represents the gravitational or cosmic redshift z being equal to the change in wavelength Δλ divided by the source wavelength λ₀
- T(deg) phase shift in degree
- We are given T(deg) = T/360 = (1/f)/360 = z * 360.
- This equation states that the phase shift in degrees T(deg) is equal to the time period T divided by 360, which is also equal to the reciprocal of the frequency f divided by 360, and it is equal to the gravitational or cosmic redshift z multiplied by 360. For a complete time period T, the phase shift in degrees T(deg) is equal to z * 360, where z represents the gravitational or cosmic redshift
- z gravitational/cosmic redshift.
- We are given z = Δλ/λ₀.
- This equation indicates that the gravitational or cosmic redshift z is equal to the change in wavelength Δλ divided by the source wavelength λ₀.
These are the simplified expressions based on the given equations and the relationships among the variables.
11 July 2023
There is a direct relationship between Phase shift T(deg) and Gravitational/Cosmic Redshift (z):
Authored by Soumendra Nath Thakur. Author ORCID: 0000-0003-1871-7803
Author's Conclusion: T(deg) = z * 360.
The phase shift T(deg) is a measure of the change in phase of a wave, often caused by factors such as motion or gravitational effects. It is typically measured in degrees.
The gravitational/cosmic redshift (z) represents the change in wavelength or frequency of a wave due to gravitational or cosmological effects. It is a dimensionless quantity.
The relationship T(deg) = z * 360 indicates that the phase shift in degrees T(deg) is directly proportional to the gravitational/cosmic redshift (z) multiplied by 360.
This means that for a given redshift value, the corresponding phase shift will be proportional to that value multiplied by 360.
- 1° phase shift = T/360; T = 1/f.
- 1° phase shift = T/360 = (1/f)/360.