KR101180647B1 - Design of pixel for more higher fill factor wherein microbolometer - Google Patents

Abstract

A pixel design for increasing the fill factor in a microbolometer according to an embodiment of the present invention includes a lower layer including a reflective metal layer on the substrate; A cavity above the bottom layer; An upper layer comprising a bolometer layer over the cavity and a transmissive metal layer thereon; An insulating layer for insulating the lower layer and the upper layer; And an array of bolometer pixels each comprising an anchor supporting the top layer, wherein the four bolometer pixels share one of the anchors.

Description

DESIGN OF PIXEL FOR MORE HIGHER FILL FACTOR WHEREIN MICROBOLOMETER}

The present invention relates to a pixel design for increasing the fill factor in a microbolometer, and more particularly, to a microbolometer having four anchors in a microbolometer having four pixels sharing with each other and having a fill factor of 70% or more.

Infrared sensors can be divided into two types according to the principle of operation: a cooling type that obtains an electrical signal generated by the interaction of photons in the infrared with electrons in the material, and an uncooling type that senses temperature changes generated by the absorption of infrared light into the material. The cooling type is mainly made of semiconductor materials, has the advantage of low noise and fast response characteristics, but has the disadvantage of operating at liquid nitrogen temperature (-193 ℃), whereas uncooled materials have a little performance compared to semiconductors. It has a merit that it operates at room temperature.

Therefore, cooling materials that require cooling are mainly studied for military purposes, and uncooled materials are mainly used for civil purposes.

Uncooled infrared sensors can be broadly classified into three types: bolometer, thermocouple, and pyroelectric type. Pyroelectric sensors have good detection power but limited production, while bolometers and thermocouples have lower detection power than pyroelectrics, but are manufactured monolithically on silicon wafers with detector circuitry, which is widely developed for civilian use because of their high productivity. Among them, the bolometer-type infrared sensor detects infrared rays by absorbing the infrared rays emitted from the object and using the change in electrical resistance due to the temperature rise caused by the change in thermal energy.

Conventional bolometers typically consist of a raised level of detection as shown in US Pat. No. 5,300,915, a support level and a lower level to support it. However, since the support level to support the detection level is formed together, the total area absorbing infrared rays is reduced, so that the maximum absorption factor (fill factor) could not be obtained.

Accordingly, Korean Patent Publication No. 2000-0007216, Korean Patent Publication No. 2000-0046517, Korean Patent Registration No. 10-0299642 and US Patent No. 6,448,557 disclose a three-layer bolometer-type infrared sensor having an infrared reflecting layer. U.S. Patent No. 5,367,167 describes a cell array having a large conductive path, and U.S. Patent No. 6,441,374 discloses an infrared sensor having a thermal separation structure and high absorption rate to increase the sensitivity and absorption area of an infrared sensor. Research is ongoing.

As the size of the pixels decreases, the area occupied by the legs and anchors becomes relatively large, which results in a lower fill factor. Therefore, there is a need for a design and method that can increase the fill factor. Conventionally, one pixel is connected to two anchors, but in the present invention, one anchor is shared by four pixels, and the purpose of the fill factor is 70% or more.

In order to achieve the above object and solve the problems of the prior art, the pixel design for increasing the fill factor in the microbolometer according to an embodiment of the present invention, the lower layer including a reflective metal layer on the substrate; A cavity above the bottom layer; An upper layer comprising a bolometer layer over the cavity and a transmissive metal layer thereon; An insulating layer for insulating the lower layer and the upper layer; And an array of bolometer pixels each comprising an anchor supporting the top layer, wherein the four bolometer pixels share one of the anchors.

In addition, in the pixel design for increasing the fill factor in the micro-bolometer according to an embodiment of the present invention, the bolometer layer is made of amorphous silicon and the transmission metal layer is titanium or a titanium compound (for example, titanium nitride, titanium oxide, etc.) Characterized in that consists of.

In addition, in the pixel design for increasing the fill factor in the microbolometer according to an embodiment of the present invention, the upper layer is characterized in that a resistance line is formed by etching the transmissive metal layer into any one of a L-shaped, a straight, and a square.

In addition, in the pixel design for increasing the fill factor in the microbolometer according to an embodiment of the present invention, the ballometer array is characterized by using a focal plane array.

Conventional microbolometers have two anchors in one pixel, but in the present invention, if one anchor is shared by four pixels and a 640 × 480 focal plane array (FPA) is applied, one pixel per pixel Designed to require anchors.

This design increases the fill factor of the microbolometer to increase the final output signal voltage, which improves response and temperature resolution (NETD), which are important evaluation factors for the manufactured microbolometer. Let's do it.

In addition, by sharing four anchors with one pixel, the structural stability of the microbolometer is increased, and the chip size including the manufactured microbolometer is reduced, thereby improving productivity and lowering the manufacturing cost.

1A and 1B show the design of a microbolometer with a pattern of r-shaped resistance lines in which one anchor shares four pixels.
2 is a conceptual diagram illustrating pixels of a microbolometer.
3 is a design of a microbolometer with a pattern of straight resistance lines.
4 is a design of a microbolometer with a pattern of square resistance lines.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a pixel design for increasing the fill factor in the design of a microbolometer. The incident infrared ray heats the bolometer layer 140 of the thermal isolation structure, and the ROIC connected to the microbolometer reads the resistance change of the bolometer layer 140 according to the temperature change and outputs the voltage value. In order to increase the efficiency of the microbolometer, it must be designed to have a high fill factor.

In the pixel design of the microbolometer, when one anchor 160 is shared by four pixels to apply a 640 × 480 focal plane array (FPA), one anchor 160 is required for one pixel. As the number of anchors 160 supporting the pixels decreases, the area capable of absorbing infrared rays increases, so that a fill factor value can be obtained at 70% or more.
Herein, the FPA (Focal Plane Array, FOC) is an array of two-dimensional devices for detecting infrared rays passing through the lens system to the focal plane and reaching the focal plane.

The microbolometer manufactured based on the above design increases the fill factor to increase the final output signal voltage value, which is an important evaluation factor of the manufactured microbolometer, responsivity and temperature resolution (NETD: Noise Equivalent Temperature). Improve Difference

In addition, by sharing the four anchors of one anchor 160, the structural stability of the microbolometer increases, and the chip size including the manufactured microbolometer is reduced, thereby improving productivity and lowering the manufacturing cost.

1A and 1B are 3D designs of microbolometers in which one anchor 160 shares four pixels. Each pixel is connected to the anchor 160 via a bridge. The electrical signal processing relates to the metal layer of the bridge that is connected to the pixel, and the electrical signal is transmitted to the anchor 160 through the bridge where the metal remains. 1A and 1B show a case in which a pattern of a letter-shaped resistance line is modified.

3 and 4 show patterns of straight and square resistance lines.

2 is a conceptual diagram illustrating a pixel of a microbolometer.

The bolometer layer 140 is made of doped amorphous silicon, the thickness is preferably about 500 to 3000A. The transmissive metal layer 150 is made of titanium as a layer that transmits infrared rays, and the thickness thereof is preferably about 20 to 100A.

There is a reflective metal layer 120 on top of the substrate 110, such as a CMOS substrate. The reflective metal layer 120 is made of aluminum or gold and allows infrared rays to be reflected. The thickness of the cavity 130 is designed so that the distance from the bolometer layer 140 to the reflective metal layer 120 is λ / 4 (λ: wavelength of infrared rays) so that infrared rays are resonance absorbed.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

Claims (4)

A lower layer including a reflective metal layer over the substrate; A cavity above the bottom layer; An upper layer comprising a bolometer layer over the cavity and a transmissive metal layer thereon; An insulating layer for insulating the lower layer and the upper layer; And an array of bolometer pixels each comprising an anchor supporting the top layer, wherein the four bolometer pixels share one of the anchors. The method of claim 1,
And the bolometer layer is made of amorphous silicon and the transmission metal layer is made of titanium. The method of claim 1,
And a portion of the upper layer which is removed by etching the transparent metal layer in any one of a L-shape, a straight line, and a quadrangle is formed as a resistance line. The method of claim 1,
And the bolometer array uses a focal plane array.

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