{"id":11358,"date":"2022-11-26T05:28:39","date_gmt":"2022-11-26T05:28:39","guid":{"rendered":"https:\/\/www.szlaser.com\/?page_id=11358"},"modified":"2022-11-26T08:21:21","modified_gmt":"2022-11-26T08:21:21","slug":"lens-for-terahertz-detector","status":"publish","type":"page","link":"https:\/\/www.szlaser.com\/index.php\/wiki\/lens-for-terahertz-detector\/","title":{"rendered":"Design of optical lens for terahertz detector array using Tracepro"},"content":{"rendered":"

Design of optical lens for terahertz detector array using Tracepro<\/h1><\/h1><\/div>

terahertz; detector array; Tracepro; optical lens<\/p>\n<\/div>

Abstract<\/h3><\/h1><\/div>

Terahertz imaging technology is a rising detection technology with great development prospects. In order to satisfy the requirement for terahertz detector array imaging,,a compact refractive optical lens is designed. The lens material is HRFZ-Si with a parylene anti-reflection coating on the surface. The imaging on the focal plane of the point at infinity on the axis and off axis through the optical lens is silmulated by using Tracepro software, and the structural parameters of the optical lens are optimized. The optimizing lens simulation results indicate that the focal length of the optical lens is 26.2mm, the filed angle is 16.3\u00b0,the relative aperture is 1.9: 1 and the resolution is 20 Ip\/mm.<\/p>\n<\/div>

1 Introduction<\/h3><\/h1><\/div>

Terahertz waves are in the transition region between electronics and photonics, and their unique properties have attracted increasing interest in the scientific community. Terahertz detection imaging is an important direction for the application of terahertz technology.<\/p>\n

Uncooled array thermal detectors have the characteristics of low cost, light weight, reliability and broadband, and research institutions in the United States, Japan, Canada and other countries have made them the focus of terahertz detector research.<\/p>\n

Tracepro is a set of optical design and simulation software generally applicable to lighting systems, optical analysis, radiometric analysis and photometric analysis.<\/p>\n

In this paper, based on the basic theory of applied optics, a refractive optical lens is designed for a terahertz detection array with a detection array size of 80 \u00d7 60 and a detection pixel size of 75 \u03bcm.<\/p>\n

The Tracepro optical simulation software is used to simulate the imaging situation of the infinity point passing through the designed optical lens on the focal plane, and the structural parameters of the optical lens are optimized.<\/p>\n<\/div>

2 Optical structure design<\/h3><\/h1><\/div>

There are generally three types of optical lens structure designs for terahertz microbolometers: reflection type, refraction type, and reflection-refractive type. The schematic diagrams of the three optical structures are shown in Figure 1.<\/p>\n

\"\"

Fig.1 Three optical structures
(reflective system, refractive system, catadioptric system)<\/p><\/div>\n

The advantage of the reflective structure is that the transmittance of the terahertz wave passing through the material does not need to be considered, only the material with high reflectivity needs to be considered (the gold-coated mirror has a reflectivity of nearly 100% for the terahertz wave).<\/p>\n

However, for the detection optical structure which should have a relatively large field of view and a small aperture coefficient, it is difficult to correct the aberration caused by adopting the reflective design. The advantage of the refractive structure is that the aberration can be better corrected by adjusting the size of the optical element, but it will be restricted by the transmittance of the optical element to the terahertz wave.<\/p>\n

The reflection-refractive structure can correct aberrations better, and its transmittance is higher than that of the refractive structure (the number of terahertz waves passing through the optical elements is less than that of the refractive structure), but its structure is relatively complex. In line with the principle that the optical structure should be as simple as possible under the premise of meeting the requirements, and the terahertz wave transmittance of the reflection-refractive structure is not qualitatively improved compared with the refractive structure, the refractive structure is selected as the terahertz micrometer. The basic structure of the bolometer optical lens.<\/p>\n<\/div>

2.1 Material selection of optical components<\/h4><\/h1><\/div>

The refractive structure will be restricted by the transmittance of optical components to terahertz waves, so the design of the optical structure of the terahertz detection array should select materials with low absorption rate of terahertz waves as the lens material, and add an effective anti-reflection film to reduce Reflection of terahertz waves on lens surfaces.<\/p>\n

Most materials have a high absorption rate for terahertz waves, but some polymers show good permeability, such as TPX (poly4-methylpentene-1), HDPE (high density polyethylene), Picarin (polytetrafluoroethylene) and so on. The absorption rate of these polymer materials is about 4%\/mm. To ensure a high transmittance of terahertz waves, a thin lens (generally 2 to 3 mm) must be used, otherwise there will be a large loss (10 mm). mm thickness is about 40% loss). At the same time, the refractive index of these polymers is around 1.5, and the smaller refractive index and thinner lens thickness will limit the correction of aberrations.<\/p>\n

The only requirement to achieve image quality is to increase the number of lenses, which increases the complexity of the optical structure and increases the loss of terahertz waves.<\/p>\n

Another material that exhibits excellent performance in the terahertz band is high-resistance floating-zone silicon (HRFZ-Si), which has an absorption rate between 0.2%\/mm and 1%\/mm. Low absorptivity allows thicker lens thicknesses.<\/p>\n

The refractive index of HRFZ-Si is about 3.4, the large refractive index and thick lens thickness can easily correct the aberration, and the double-lens structure can meet the image quality requirements. However, HRFZ-Si has a large refractive index and a large surface reflectivity, but the transmittance of terahertz waves is relatively low. The transmittance and reflectivity are shown in Fig. 2.<\/p>\n

\"\"

Fig.2 Transmission and reflection of HRFZ-Si 5mm-thick sample in THz range<\/p><\/div>\n

In order to increase the transmittance of terahertz wave and reduce its reflectivity, it is necessary to coat the surface of HRFZ-Si with an effective anti-reflection film. Parylene (parylene) film can effectively reduce the reflectivity of THz waves on the lens surface, and is an effective anti-reflection film.<\/p>\n

The transmittance of the lens coated with parylene anti-reflection film can be increased from 50% to 60% before coating to 80% to 90%.<\/p>\n

Therefore, HRFZ-Si is selected as the material of the refractive optical lens lens, and a parylene anti-reflection film is coated on its surface to enhance the transmittance of terahertz waves.<\/p>\n<\/div>

2.2 Design of optical structure parameters<\/h4><\/h1><\/div>

There are four main parameters that describe the properties of optical structures: Focal length f’, relative aperture D\/f’, field angle 2\u03c9 and resolution N.<\/p>\n

The focal length determines the proportion of the object image, the relative aperture determines the illuminance of the image plane, the field of view determines the spatial range of imaging, and the resolution represents the ability to distinguish the details of the object to be measured. The field of view determines the spatial range of imaging, which is determined by the photosensitive size of the detector and the focal length of the optical structure. The field of view is:<\/p>\n

\"\"<\/p>\n

Among them, y’max is the length of the diagonal of the detection array.<\/p>\n

The size of the terahertz detection array designed in this paper is 80 \u00d7 60, and the size of the detection pixel is 75 \u03bcm. To meet the requirement of 15\u00b0 for the angle of view 2\u03c9, the focal length f’ should meet:<\/p>\n

\"\"<\/p>\n

The resolution of the optical structure should be greater than the resolution of the detection array, and the detection frequency of the detector is around 3 THz, that is, the wavelength \u03bb = 100 \u03bcm, according to the Rayleigh criterion:<\/p>\n

\"\"<\/p>\n

The entrance pupil diameter D should satisfy:<\/p>\n

\"\"<\/p>\n

The relative aperture determines the illuminance of the image plane. The larger the relative aperture, the stronger the light energy reaching the detection array.<\/p>\n

According to the photometric theory, the formula for the illuminance of the image point on the axis is:<\/p>\n

\"\"<\/p>\n

Among them, L is the brightness of the measured object; \u03c4 is the transmittance of the optical structure. The energy of terahertz sources is relatively weak, so a large relative aperture is required, which is in line with the size requirements of the optical structure for resolution.<\/p>\n

The refracting optical structure adopts the double-lens structure shown in Fig. 1. The first lens is a convex-concave lens, which converges the light beam emitted by the measured object and forms an image, and the second lens is a concentric meniscus lens, which is used to correct aberrations. The third block is the terahertz wave entrance window, which is used to encapsulate and protect the detector.<\/p>\n

The initial structural dimensions of the two lenses should be set to satisfy the above-mentioned optical structural parameters. According to the thick lens base point position and focal length formula:<\/p>\n

\"\"<\/p>\n

Among them, lH<\/sub>‘ and lH<\/sub> are the position of the base point of the image square and the base point of the object side, respectively; f’ and f are the focal length of the image side and the focal length of the object side of the thick lens, respectively; r1<\/sub> and r2<\/sub> are the radius of curvature of the front surface and the rear surface of the thick lens, respectively. Radius of curvature; n is the refractive index of the thick lens material; d is the thickness of the lens.<\/p>\n<\/div>

The formula for the composite image of the two-light group:<\/p>\n

\"\"<\/p>\n

Among them, f’ is the focal length of the two-optical group image side; lH<\/sub>‘ is the base point position of the two-optical group image square; lF<\/sub>‘ is the focal position of the two-optical group image square, f1<\/sub>‘ and f2<\/sub>‘ are the first lens in the two-optical group and f2<\/sub>‘ respectively. The image-side focal length of the second lens; d is the distance between the first lens and the second lens.<\/p>\n

When \u03bb=100 \u03bcm, the refractive index of HRFZ-Si is about 3.422, and the initial structure of the probe optical structure can be obtained:<\/p>\n