Analysis of the Interference Modulation Depth in the Fourier Transform Spectrometer

Based on the principle of the Michelson interferometer, the paper briefly describes the theoretical significance and calculates and deduces three expressions of the interference modulation depth. The influence of the surface shape error of plane mirror on modulation depth is analyzed, and the tolerance of error is also pointed out. Moreover, the dependence of modulation depth on the reflectance change of beam splitter interface is also analyzed, and the curve is given. It is concluded that this paper is of general significance for the Fourier transform spectrometer based on the principle of the Michelson two-beam interference.


Introduction
The Fourier transform spectrometer is an instrument which is used to analyze the spectral distribution of the light source by means of the interference effect based on the Fourier transform technology.It has incomparably more advantages than conventional spectral instruments in acquiring higher spectral resolution.There are many kinds of Fourier transform spectrometers, including Michelson interferometer, Fabry-Perot interferometer, Sagnac interferometer, and double refraction interferometer [1,2].
The classical Michelson interferometer consists of a moving mirror and a fixed mirror.The two beams of lights, reflected by these two mirrors, make up the phase difference.When the moving mirror moves, the intensity of interference signals is modulated to form the interferogram.The modulation depth is also known as the interference modulation efficiency.It is one of the most important factors influencing the signal-to-noise ratio of the interferogram, and a change in it will significantly affect the sensitivity of the spectrometer [3,4].Based on the Michelson type Fourier transform spectrometer, this paper explores the optical principle of interference system through a quantitative analysis of influencing factors of surface shape of mirror and performance change of beam splitter.It is hoped that suggestions can be made for the obtaining of ideal interferogram.

The Modulation Depth of Fourier Transform Spectrometer
The most classical Fourier transform spectrometer is the Michelson interferometer, which is composed of a fixed mirror, a moving mirror, a beam splitter, and a detector.Its basic structure is shown in Figure 1.
In the Michelson interferometer, the fixed mirror and the moving mirror are perpendicular to each other, with an angle of 45 ∘ between the beam splitter and two mirrors.The collimated beam shines the interference system, and the beam splitter separates the incident light into two beams with roughly the same reflectance and transmittance.One reflected beam by the fixed mirror then goes through the beam splitter again, whereas the other transmitted beam is reflected by the moving mirror and divided by the beam splitter.Because these two beams of light are produced by the same beam, they have a constant phase difference.When these two beams of light travel through a convergent lens, the interference is formed on the detector.
Upon arrival at the detector, the two coherent beams have an optical path difference for the shift of the moving mirror.The optical path difference then shows periodic changes with round-trip translation of the moving mirror.According to the principle of interference spectroscopy, the interference signals can be obtained on the detector.According to the interference theory, the intensity of interference signals generated by the two-beam interference is [5] where  1 and  2 are, respectively, the intensity of two coherent beams and  is the phase difference of two coherent beams.The definition of the modulation depth of interference signals, namely, the visibility of interference signals , is This equation indicates the degree of bright dark contrast of fringes in the interference field, where  max and  min stand for the maximum intensity and the minimum intensity of interference signals.We then get the following equation: Then ( 1) can be rewritten as From (3), we can have the coefficient of the cosine, namely, the modulation depth, after we obtain the distribution of the cosine light intensity, and normalize the constant term.If and only if  1 =  2 =  0 , that is to say, when the intensity of two coherent beams of light is equal, the modulation depth reaches a maximum and also an ideal  = 1.However, with practical applications taken into consideration, the modulation depth  will usually be less than 1.

The Surface Shape Error of Plane Mirror
The fixed mirror and the moving mirror of Fourier transform spectrometer are composed of plane mirrors with a rectangular aperture.In the process of making plane mirrors, there are a number of factors modulating the surface error, such as polishing, coating, and mirror bending.It follows that these mirrors are not ideal surface shape, and there is always a certain surface error.Therefore, in a spectrometer composed of these mirrors, the modulation depth is often not ideal.In what follows, we will analyze the influence of curve error and polishing error of plane mirror on interference modulation depth.Suppose polishing error of mirror obeys normal distribution with zero mean, and its maximum fluctuation is  max .In addition, curve error of mirror is subject to uniform distribution, and its maximum curvature is  max .Assume also that other optical components in Fourier transform spectrometer are ideal.
When there is a surface shape error of plane mirror, the reflection of two beams of coherent light will generate wavefront distortion, which results in a change in optical path difference of interferometer.The phase difference  of the two beams of coherent light changes accordingly.For a small change  of the surface shape error, the change of the phase difference is where ] is the wave number of the incident light.Suppose () is the probability density function of surface shape error.If  ∈ (, Δ), then we obtain surface  = ().Because of the effect of surface shape error, the intensity of interference signals is [6] where   () represents the distribution of interference intensity in any one point.The probability density function is where  is the standard deviation of .
When  = () is substituted to (6), we can get the intensity of interference signals: Hence, the interference modulation depth is It can be seen that the interference modulation depth is inversely proportional to the variance of polishing error of mirror, which means that a good polishing surface can improve the modulation depth.If the interference modulation depth is set at  1 ≥ 0.9, the error tolerance of standard deviation  is In the same way, when the mirror surface is curved, the existence of the curve error causes the intensity distribution of the interference signals to be It follows that, when the surface of mirror is deformed, the interference modulation depth is Equation ( 12) shows that  2 is a function of sinc, and the modulation depth  2 decreases when the curvature  increases.If the interference modulation depth is set at  2 ≥ 0.9, the error tolerance of the curvature  is Through the above analysis, we know that the surface error of mirror has an effect on the modulation depth.In order to achieve better interference effect, the surface error of mirror should meet error tolerance requirements.

The Reflectance Change of Beam Splitter Interface
In the Michelson interferometer shown in Figure 1, the separating surface of the beam splitter is coated with transflective film.Suppose   and   represent the amplitude reflection coefficient and the amplitude transmission coefficient of beam from the surrounding medium into surface  of the beam splitter, respectively.Meanwhile,    and    are the amplitude reflection coefficient and the amplitude transmission coefficient of beam from surface  of the beam splitter into the surrounding medium, respectively.At the same time,   is the amplitude reflection coefficient of fixed mirror, and   is the amplitude reflection coefficient of moving mirror, and  stands for the amplitude of incident light [7,8].The complex amplitude of the two beams of light reflected by Michelson interferometer, respectively, is where ] is the wave number of the incident light, while  1 and  2 represent optical path of two beams of light, respectively.Generally speaking, if the amplitude reflection coefficient of the fixed mirror equals that of the moving mirror, that is,   =   , then we get From (15), the modulation depth can be expressed as According to the Fresnel formula, the amplitude reflection coefficient and the amplitude transmission coefficient satisfy the following conditions: And the interface reflectance of the beam splitter is Then substituting (18) into (17), we can get Thus, the interference modulation depth is From (20), it can be seen that the interference modulation depth  3 will change with the interface reflectance  of the beam splitter.Their relationship is captured in Figure 2.
From Figure 2, the smaller the interface reflectance  of the beam splitter is, the greater the interference modulation Advances in OptoElectronics  depth  3 becomes.To put it another way, if  value is 0, then  3 = 1.When the interference modulation depth is set at  3 ≥ 0.9,  is

Experimental Results
The analysis of interference modulation depth indicates that, in order to realize the interference modulation depth  ≥ 0.9, the maximum value of the curve error of mirror  should be  max ≤ /8.Figure 3 presents measured results of the surface of the plane mirror with the aid of Zygo interferometer.As can be seen from Figure 3, the plane mirror has a good surface, with the PV value /8.The interferometer is placed on the testbed, and the interference is formed by using the He-Ne laser.The electrical signal of the laser interference can then be acquired.Figure 4 provides the interference signal generated by the laser light source.
As can be seen from Figure 4, the laser interference signal is a sinusoidal signal, and the amplitude of the interference signal is stable and the fringe is clearly visible, which meets the requirement of the interference modulation depth.

Conclusions
In the Fourier transform spectrometer, the Michelson interferometer is the core optical system.By focusing on the classic Michelson interferometer, we have conducted a theoretical analysis of the influence of surface shape of mirror and performance change of the beam splitter on the modulation depth.Theoretical deductions are obtained regarding tolerance requirements for the error of surface shape mirror and the reflection ratio of the beam splitter.The results obtained are applicable to the Fourier transform spectrometer within the framework of the Michelson dual beam interference.

3 Figure 2 :
Figure 2: Influence of reflectance change of beam splitter on modulation depth.

Figure 3 :
Figure 3: The surface shape of plane mirror.

AmplitudeFigure 4 :
Figure 4: The electrical signal of the laser interference.