The present disclosure relates to an image sensor, an image capturing system, an electronic apparatus including an image sensor, an automotive vehicle including an electronic apparatus including an image sensor, and a production method of an image sensor.
In the past, various types of solid-state image sensors that can simultaneously acquire both of an image of visible light and an image of infrared light were proposed to be applied to distance measurement or the like. As such, structures including a solid-state image sensor, a structure that arrays pixels that detect visible light (RGB pixels) and pixels that detect infrared light (IR pixel(s)) that were arranged in a horizontal direction were considered, including a structure where four pixels including RGB pixels and an IR pixel were arrayed. However, when the solid-state image sensor having this structure is compared with a solid-state image sensor in which the RGB pixels are configured to have a Bayer array, at least one of positions at which the pixels for the visible light are located in the normal Bayer array is replaced by the IR pixel, and this results in degradation of its resolution.
In order to prevent the degradation of the resolution in the above structure of the horizontal array, Patent Literature 1 (below) proposes a solid-state image sensor structure that stacks the pixels for the visible light and the pixels for the infrared light in the vertical direction to simultaneously acquire both of the image of the visible light and the image of the infrared light, for example.
However, when the vertically stacked structure is used as proposed in the above Patent Literature 1, and the infrared light pixel is an avalanche multiplication light-emitting diode (avalanche photo diode: APD), such as a single photon avalanche diode (SPAD), for example, then high voltage must be applied to the APD, which means that a part of high voltage drive and a part of low voltage drive are created in the same substrate. As a result, it is difficult to design circuits of such vertically stacked structures that will work efficiently, and it is also problematic to design the structure because the pixel size differs between the visible light pixel and the infrared light pixel.
Thus, in consideration of the above circumstances, the present disclosure proposes an image sensor, an image capturing system, and a production method of an image sensor that can reduce or prevent degradation of resolution as well as mixed color, as well as provide improved separation of a drive circuit when simultaneously detecting light of two types of wavelength bands (e.g., visible and infrared light).
According to embodiments of the present disclosure, there is provided an image sensor including a light receiving unit that includes a long wavelength sensor array composed of a plurality of pixels that receive light of a long wavelength side among light of a predetermined wavelength band, an insulator layer that is positioned on the long wavelength sensor array, and reflects light of a short wavelength side among the light of the predetermined wavelength band, and allows the light of the long wavelength side to transmit through the insulator layer, and a short wavelength sensor array positioned on the insulator layer and composed of a plurality of pixels that receive the light of the short wavelength side. According to further embodiments of the present disclosure, there is provided an imaging device, an electronic apparatus including an imaging device, an automotive vehicle including an electronic apparatus including an imaging device, and methods for producing the same, where the imaging device includes: a first substrate including a first set of photoelectric conversion units; a second substrate including a second set of photoelectric conversion units; and an insulating layer between the first substrate and the second substrate; where the insulating layer has a capability to reflect a first wavelength range of light and transmit a second wavelength range of light that is longer than the first wavelength range of light.
According to embodiments of the present disclosure, there is provided an image capturing system including: an image sensor including a light receiving unit that includes a long wavelength sensor array composed of a plurality of pixels that receive light of a long wavelength side among light of a predetermined wavelength band, an insulator layer that is positioned on the long wavelength sensor array, and reflects light of a short wavelength side among the light of the predetermined wavelength band, and allows the light of the long wavelength side to transmit through the insulator layer, and a short wavelength sensor array positioned on the insulator layer and composed of a plurality of pixels that receive the light of the short wavelength side, and an optical filter that is positioned at a prior stage of the light receiving unit, and allows light of a part of a wavelength band among the light of the long wavelength side to transmit through the optical filter; and a light source that emits light of a wavelength band that transmits through the optical filter.
According to embodiments of the present disclosure, there is provided a production method of an image sensor, including: forming a short wavelength sensor array composed of a plurality of pixels that receive light of a short wavelength side among light of a predetermined wavelength band, on a predetermined substrate; forming a long wavelength sensor array composed of a plurality of pixels that receive light of a long wavelength side among the light of the predetermined wavelength band, on the predetermined substrate; and providing the short wavelength sensor array at one side of an insulator that reflects the light of the short wavelength side and allows the light of the long wavelength side to transmit through the insulator, and locating the long wavelength sensor array at another side of the insulator.
According to embodiments of the present disclosure, the short wavelength sensor array of the light receiving unit receives the light of the short wavelength side among the light of a predetermined wavelength band, and the long wavelength sensor array of the light receiving unit receives the light of the long wavelength side among the light of the predetermined wavelength band. Also, the short wavelength sensor array and the long wavelength sensor array are electrically separated by an insulator layer that reflects the light of the short wavelength side among the light of the predetermined wavelength band and allow the light of the long wavelength side to transmit through the insulator layer.
As described above, according to embodiments of the present disclosure, the degradation of the resolution is reduced or prevented, mixed color is reduced or prevented, and there is improved separation of the drive circuit when light of two types of the wavelength bands (e.g., visible and infrared light) are detected simultaneously.
The advantageous effects described herein are not limitative. With or in the place of the effects described herein, there may be achieved any one or more of the effects described herein or other effects.
Hereinafter, (an) embodiment(s) of the present disclosure will be described in detail with reference to the appended drawings. In this specification and the appended drawings, structural elements that have substantially the same function and structure are denoted with the same reference numerals, and repeated explanation of these structural elements is omitted.
Note that description will be made in the following order.
<With Regard to Overall Structures of Image Sensor>
First, an overall structure of an image sensor according to embodiments of the present disclosure will be described in detail with reference to
The image sensor 10 according to the present embodiment is a CMOS image sensor for example, and includes a light receiving unit that includes a long wavelength sensor array 101, an insulator layer 103, and a short wavelength sensor array 105, as schematically illustrated in
Incoming light of a predetermined wavelength band (e.g., light in the visible light spectrum and light in the infrared light spectrum) enters into the image sensor 10. The long wavelength sensor array 101 is a sensor array that includes a plurality of pixels that receive light of a relatively long wavelength side (e.g., light in the infrared light spectrum) from the incoming light. This long wavelength sensor array 101 is formed by using photoelectric conversion material that converts the light of the long wavelength side to electric charge (for example, electrons) in an amount that corresponds to an amount of the detected light of the long wavelength side.
The insulator layer 103 is positioned on the long wavelength sensor array 101. The insulator layer 103 reflects the light of the relatively short wavelength side (e.g., light in the visible light spectrum) from the incoming light of the predetermined wavelength band that enters into the image sensor 10, and allows the light of the long wavelength side to transmit through the insulator layer 103.
The short wavelength sensor array 105 is positioned on the insulator layer 103. The short wavelength sensor array 105 is a sensor array that includes a plurality of pixels that receive the light of the relatively short wavelength side from the incoming light of the predetermined wavelength band that enters into the image sensor 10. This short wavelength sensor array 105 is formed by using photoelectric conversion material that converts the light of the short wavelength side to electric charge (for example, electrons) in an amount that corresponds to an amount of the detected light of the short wavelength side.
In various embodiments, it may be preferable that the long wavelength sensor array 101 and the short wavelength sensor array 105 are formed in such a manner that the wavelengths of the amounts of light to be detected differ from each other, and thus it may be preferable that the photoelectric conversion material used in the long wavelength sensor array 101 and the photoelectric conversion material used in the short wavelength sensor array 105 differ from each other.
As is illustrated in
Thus, as shown by the illustrative structure in
In various embodiments, it may be preferable that the wavelength band of interest in the incoming light is from the visible light band to the infrared light band, in the image sensor 10 according to the present embodiment. When this wavelength band is from the visible light band to the infrared light band, it may be preferable that the short wavelength sensor array 105 is set to a visible light sensor array that detects visible light which is light of relatively short wavelength, and the long wavelength sensor array 101 is set to an infrared light sensor array that detects infrared light which is light of relatively long wavelength. As described below, when the incoming light is from the visible light band to the infrared light band, the detailed description describes an illustrative case in which the short wavelength sensor array 105 is a visible light sensor array, and the long wavelength sensor array 101 is an infrared light sensor array.
In some embodiments, an infrared light detection sensor array that uses a photoelectric conversion material that can detect infrared light can be utilized as the long wavelength sensor array 101 that functions as the infrared light sensor array. Various types of semiconductor materials that can detect the infrared light can be utilized as the photoelectric conversion material, which can include one or more of at least InGaAs, FeS2, CulnGaSe, and Si, for example. Also, an avalanche multiplication diode (APD) (e.g., a carrier multiplication diode), such as a single photon avalanche diode (Single Photon Avalanche Diode: SPAD), can be utilized as the infrared light detection sensor array, for example.
In some embodiments, a visible light detection sensor array that uses a photoelectric conversion material that can detect visible light can be utilized as the short wavelength sensor array 105 that functions as the visible light sensor array. This photoelectric conversion material can be various types of semiconductors including compound semiconductors. In various embodiments, it may be easier and convenient to use a photoelectric conversion material that includes at least Si, for example.
As illustrated in
As described above, the image sensor 10 according to the present embodiment is advantageous over the prior art because, for example, the pixels of the infrared optical sensor do not need to be located in an area that would otherwise be a part of the pixels of the visible light sensor array (e.g., at the sacrifice of a part of the pixels of the visible light sensor array) as was done in the past. In contrast, in various embodiments described herein, by separating the long wavelength sensor array 101 and the short wavelength sensor array 105 into top and bottom by the insulator layer 103 (e.g., separating the long wavelength sensor array 101 and the short wavelength sensor array 105 in a vertical or depth direction with respect to the substrate), the degradation of the resolution can be reduced as compared with an image sensor (for example, a CMOS image sensor) in which the visible light/infrared light pixels are arrayed in the horizontal direction.
Also, when a carrier multiplication sensor array such as the APD is used as the long wavelength sensor array 101 that functions as the infrared light sensor array, the short wavelength sensor array 105 that functions as the visible light sensor array can be driven with low drive voltage (e.g., about 2V to about 5V), and the long wavelength sensor array 101 can be driven with high drive voltage (e.g., about 10V to about 30V, or about 15V to about 25V). As described above, according to the image sensor 10 of the present embodiment, even when different voltage drives are to be used, the long wavelength sensor array 101 and the short wavelength sensor array 105 can be separated electrically by the insulator layer 103. As a result, the circuit design of the image sensor 10 becomes extremely easy compared to the past.
In various embodiments, it may be preferable to further provide a visible light wavelength selection filter 107 and a light collection structural element 109, as illustrated in
The visible light wavelength selection filter 107 is not limited by the description herein, and may be formed by using a material that allows the light of a wavelength band to transmit through, and also absorbs or reflects the light of another wavelength band. The material allowing such transmittance and absorption/reflection may be chosen depending on a desired wavelength band to form an image at the pixel of the short wavelength sensor array 105.
In various embodiments, it may be preferable to provide a light collection structural element (for example, an On-Chip-Lens: OCL) 109 for causing the light that enters into the pixel of the short wavelength sensor array 105 of interest to form a desired image on the short wavelength sensor array 105, in the upper portion of the visible light wavelength selection filter 107.
The long wavelength sensor array 101 according to the present embodiment may be shared by a plurality of pixels of the short wavelength sensor array 105 as illustrated in
Also, the pattern of colors for the visible light wavelength selection filter 107 is not limited by the description herein. For example, the R filters made of color filters that allow reddish light to transmit through, the G filters made of color filters that allow greenish light to transmit through, and the B filters made of color filters that allow bluish light to transmit through may be located to form a Bayer array as illustrated in
Next, an example of the insulator layer 103 that is provided in the image sensor 10 according to the present embodiment will be described with reference to
In various embodiments, it may be preferable that the image sensor 10 according to the present embodiment described above further includes an optical filter 111 that transmits a part of the light of the wavelength band among the incoming light of the long wavelength side, at a prior stage of the short wavelength sensor array 105 (e.g., a position closer to incoming light than the short wavelength sensor array 105). When the long wavelength sensor array 101 functions as the infrared light sensor array, and the short wavelength sensor array 105 functions as the visible light sensor array, the optical filter 111 functions as an infrared cut filter that transmits only a part of wavelength band λ0 from the infrared light band. As described above, a part of the light of the long wavelength side is cut by the optical filter 111 to restrict the wavelength band of the light of the long wavelength side that enters into the short wavelength sensor array 105, and thereby the mixed color of the light of the long wavelength side into the short wavelength sensor array 105 is reduced, and the color reproducibility of the short wavelength sensor array 105 is additionally improved.
Note that the position of the location of the optical filter 111 is not limited by the description herein. The optical filter 111 may be location at a position that is a prior stage to the short wavelength sensor array 105 (e.g., a position closer to incoming light than the short wavelength sensor array 105), and the optical filter 111 may also be provided in position that is a prior stage of the light collection structural element 109 as illustrated in
The optical characteristics of the optical filter 111 may be determined depending on the optical characteristics of the photoelectric conversion material of the short wavelength sensor array 105. For example, when Si is used as the photoelectric conversion material of the short wavelength sensor array 105, Si absorbs the near-infrared light up to wavelength 1.0 μm. Hence, it may be preferable that when the near-infrared light band equal to or smaller than wavelength 1.0 μm is selected as the wavelength band λ0, the optical characteristics of the optical filter 111 are such that the optical filter 111 allows the visible light band to transmit through the optical filter 111 and also allows only a selective band (or extremely selective band) at the vicinity of the wavelength band λ0 to transmit through the optical filter 111, as schematically illustrated in
Next, wiring lines (also referred to as “lines” herein) of the short wavelength sensor array in the image sensor according to the present embodiment will be described with reference to
As a further illustrative example, a case is described in which the pixel array of the long wavelength sensor array 101 has a cycle that is twice the cycle of the pixel array in the short wavelength sensor array 105, as illustrated in
Also, as illustratively shown in
When the drive voltage of the long wavelength sensor array 101 and the drive voltage of the short wavelength sensor array 105 differ from each other, it may be preferable to provide each of the penetrated connection holes 127 for extracting the signal from the long wavelength sensor array 101 separately from each of the penetrated connection holes 129 for extracting the signal from the short wavelength sensor array 105, as illustrated in
On the other hand, when the drive voltage of the long wavelength sensor array 101 and the drive voltage of the short wavelength sensor array 105 are the same, the penetrated connection holes for extracting the signal from the long wavelength sensor array 101 and the penetrated connection holes for extracting the signal from the short wavelength sensor array 105 are in common (e.g., the penetrated connection holes for extracting the signal from the long wavelength sensor array 101 are the same as the penetrated connection holes for extracting the signal from the short wavelength sensor array 105), and pads 137 are provided at the bottom portions of these common penetrated connection holes 135, as illustrated in
Also, as illustrated in
Thus, the overall structure of the image sensor 10 according to the present embodiment has been described in detail with reference to
<With Regard to Production Methods of Image Sensor>
Next, the production method of the image sensor 10 according to the present embodiment described above will be described simply with reference to
The production method of the image sensor 10 according to the present embodiment includes forming the short wavelength sensor array composed of a plurality of pixels that receive the light of the relatively short wavelength side from the light of a predetermined wavelength band, on a predetermined substrate; forming the long wavelength sensor array composed of a plurality of pixels that receive the light of the relatively long wavelength side from the light of the predetermined wavelength band, on the predetermined substrate; providing the short wavelength sensor array on one side of the insulator that reflects the light of the short wavelength side and allows the light of the long wavelength side to transmit through the insulator; and locating the long wavelength sensor array on another side of the insulator.
As illustratively shown in in
On the other hand, the long wavelength sensor array 101 described previously is formed on the predetermined substrate, by utilizing the production process (step S105).
Thereafter, the short wavelength sensor array 105 and the long wavelength sensor array 101 are connected via the insulator layer 103 (step S107). Thereby, the image sensor according to the present embodiment can be produced.
Note that
In the description above, the production method of the image sensor 10 according to the present embodiment has been described simply with regard to
<With Regard to Image Capturing Systems>
Next, an image capturing system that utilizes the image sensor 10 according to the present embodiment will be described with reference to
The image capturing system 1 according to the present embodiment includes an image sensor 10 that includes an optical filter 111, a light source 20, and a control unit 30, as schematically illustrated in
In various embodiments, it may be preferable that the image sensor 10 used in the image capturing system 1 according to the present embodiment is the image sensor 10 that includes the optical filter 111, as illustrated in
The light source 20 emits, toward an imaged object, the light (the near-infrared light, in the present example) of the wavelength band that transmits through the optical filter 111 provided in the image sensor 10. The light source 20 is not limited and can be any light source that emits the light of a desired wavelength band. Various types of light-emitting diodes (LED) and various types of laser light sources can be utilized as the light source 20, for example.
For example, the short wavelength sensor array 105 of the image sensor 10 may be formed of a photoelectric conversion material that includes Si, and set in such a manner that the near-infrared light band that transmits through the optical filter 111 is included in the wavelength band that is absorbed by Si. In this case, an LED or a laser light source that utilize AlGaAs-based semiconductor can be used as the light source 20, for example.
Also, the short wavelength sensor array 105 of the image sensor 10 may be formed of a photoelectric conversion material that includes Si, and set in such a manner that the near-infrared light band that transmits through the optical filter 111 does not include the wavelength band that is absorbed by Si. In this case, an LED or a laser light source that utilizes a InGaAs-based semiconductor can be used as the light source 20, for example.
The light source 20 according to the present embodiment may continuously emit the light of the above wavelength, but it may be preferable that the light source 20 can emit pulse light of the above wavelength. By using a light source 20 that is capable of a pulse drive, this enables distance measurements based on the principle of time of flight (TOF). TOF measures the distance to the imaged object by utilizing a delay time Δt during which the pulse light is emitted, reflected on an imaged object, and returned. The distance measuring method based on the principle of TOF will be described again below.
The control unit 30 is configured with various types of electricity circuits (also referred to as circuits herein), or various types of IC chips or the like configured with a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), or other type of memory, or a digital signal processor (DSP) or other type of processor, for example. This control unit 30 is a processing unit that controls an overall drive state of the image sensor 10 and the light source 20 according to the present embodiment. For example, the control unit 30 outputs a control signal for emitting the light of a predetermined wavelength to the light source 20, and emits the light of the predetermined wavelength from the light source 20 at a predetermined timing. Also, the control unit 30 controls the drive state of the image sensor 10, and acquires signal data output from the long wavelength sensor array 101 of the image sensor 10 and signal data output from the short wavelength sensor array 105. In addition, various types of signal processing can be performed on the acquired signal data.
Also, the control unit 30 can perform the distance measurement process based on the principle of TOF, by driving the light source 20 with pulses. In this case, the control unit 30 outputs a control signal for emitting a pulse light to the light source 20, and starts the measurement of the delay time Δt. Thereafter, the control unit 30 waits until the signal data that is generated by detecting the pulse light is output from the long wavelength sensor array 101 of the image sensor 10. The time from outputting the control signal for emitting the pulse light to outputting the signal data from the long wavelength sensor array 101 is the delay time Δt. Now, a relationship L=(½)×c×Δt is established, where L is the distance to the imaged object (distance to be measured), and c is the light speed. Thus, the control unit 30 can calculate the distance L to the imaged object, by utilizing the obtained delay time Δt and the light speed c.
Thus, the image capturing system 1 according to the present embodiment can calculate distance information (information relevant to the value of the distance L) based on the principle of TOF, for each pixel of the long wavelength sensor array 101, in consideration of which position the pixel that outputs the signal data exists in the long wavelength sensor array 101. Thus, a two-dimensional map of the distance information can be generated by calculating the distance information for all pixels included in the long wavelength sensor array 101.
Also, in the past technology, the image information and the distance information were acquired by different optical systems, and thus the image information and the distance information were unable to be aligned accurately; however, in the image sensor 10 according to the present embodiment, the long wavelength sensor array 101 and the short wavelength sensor array 105 exist in a vertically stacked state, and thus the image (for example, the visible light image) generated by the short wavelength sensor array 105 and the distance information can be aligned more easily and accurately than when using the past technology.
Note that, when the distance measurement by TOF is performed by using the image capturing system 1 according to the present embodiment, it may be preferable that the long wavelength sensor array 101 that functions as the infrared light sensor array has high sensitivity by utilizing a carrier multiplication sensor such as an APD or an SPAD, so that the distance measurement can be performed even when the distance to the imaged object is a long distance. The reason for this is that, for example, the drive voltage is high when the APD and the SPAD are used, but the long wavelength sensor array 101 and the short wavelength sensor array 105 are separated by the insulator layer 103, and therefore the image sensor 10 according to the present embodiment provides advantageous improvements to drive each sensor array separately with different voltages (e.g., the driving of the sensor arrays is faster, requires less processing, etc.).
The optical system 40 is provided as desired and/or necessary, to direct to the image sensor 10 the light that propagates from the imaged object side. This optical system is not limited by the description herein, and an optical system that utilizes one or a plurality of optical elements such as lenses can be utilized.
In the description above, the configuration of the image capturing system 1 according to the present embodiment has been described with reference to
A collision prevention system that utilizes the distance measurement based on the principle of TOF can be configured by applying the image capturing system 1, as described above, to a collision prevention onboard camera system provided in a vehicle as illustrated in
Note that, when the collision prevention system is configured as described herein (e.g., in a simpler and more convenient manner), the distance information does not need to be calculated for every one of the pixels that compose the long wavelength sensor array 101. For example, the site that is closest in the visible light image may be identified by identifying the pixel position in the long wavelength sensor array 101 that provides the shortest delay time Δtmin, and by identifying the pixel of the short wavelength sensor array 105 that corresponds to the pixel position that was identified.
Also, as illustrated in
Note that
In the above, the image capturing system 1 that utilizes the image sensor 10 according to the present embodiment has been described in detail, with reference to
In the following description, the image sensor 10 according to the present embodiment will be described with reference to
A first specific example of the image sensor according to the present embodiment will be described with reference to
The present specific example shows an image sensor that has the structure as illustrated on the right side of
The insulator layer 103 in the present specific example is formed with a SiO2 film, a Si3N4 film, and a TiO2 film, as illustrated in
In a specific production procedure of the image sensor 10, a photo diode (PD) structure or the like that has a p-n junction is produced on a silicon-on-insulator (SOI) substrate at the Si side, by a CIS process (which is a production process of CMOS Image Sensor (CIS) that includes, for example, a resist mask process, an ion implantation process, an anneal process, an electrode wiring process, and/or other CIS processes) in order to form the short wavelength sensor array 105, as schematically illustrated in
Also, the long wavelength sensor array 101 is produced on another SOI substrate by utilizing the CIS process, and the two sensor arrays are bonded together via the insulator layer 103. Then, a process for producing the visible light wavelength selection filter 107 and the light collection structural element 109 of the upper layer (hereinafter, referred to as “upper layer formation process”) is performed.
The dopant that is utilized when forming the short wavelength sensor array 105 and the long wavelength sensor array 101 may include a p-type dopant, such as boron (B), indium (In), and/or other p-type dopants, and may include a n-type dopant, such as phosphorus (P), arsenic (As), antimony (Sb), bismuth (Bi), and/or other n-type dopants. Also, an APD that is capable of avalanche multiplication may be utilized as the long wavelength sensor array 101.
Next, the optical filter 111 that has optical characteristics illustrated in
The transmission spectrum of the optical filter 111 that is produced as described above is illustrated in
Note that the oscillation wavelength of the semiconductor laser illustrated in
Also, a lens (such as a collimator lens) may be located at the prior stage of the light source 20 (such as a semiconductor laser), to efficiently project the laser light or the LED light to the imaged object. The visible light image and the infrared light information can be simultaneously acquired by the same optical system, by using the image capturing system 1 composed of the image sensor 10 and the light source 20. It is thereby possible to obtain visible light image and the distance information that is accurately aligned to the visible light image. This image capturing system can be applied to the onboard collision prevention system, and can be applied to the automatic focusing mechanism of the camera, as described herein.
In the above, the first specific example of the image sensor 10 according to the present embodiment has been described in detail with reference to
Next, a second specific example of the image sensor according to the present embodiment will be described with reference to
The present specific example relates to the image sensor 10 that utilizes the optical filter 111 that has the optical characteristics illustrated in
In the present specific example, the insulator layer 103 is formed of a SiO2 film, a Si3N4 film, and a TiO2 film. That is, each layer of a Si3N4 film, a TiO2 film, a SiO2 film, a TiO2 film, a SiO2 film, a TiO2 film, a SiO2 film, a TiO2 film, a SiO2 film, a TiO2 film, a SiO2 film, a TiO2 film, and a Si3N4 film are formed in this order, as the interference films, on the SiO2 film that is 1 μm or more. The thicknesses of the respective films are 0.228 μm, 0.046 μm, 0.082 μm, 0.046 μm, 0.082 μm, 0.046 μm, 0.082 μm, 0.046 μm, 0.082 μm, 0.046 μm, 0.082 μm, 0.046 μm, and 0.228 μm. In addition, after the interference films are formed, a SiO2 film of 1 μm or more is stacked. The reflection spectrum of the insulator layer 103 that is produced as described above is illustrated in
In
With regard to a specific production procedure of the image sensor 10, the short wavelength sensor array 105 that functions as the visible light sensor array is produced by the CIS process by forming the PD structure (or a similar structure) having the p-n junction, on the SOI substrate at the Si side. Thereafter, the insulator layer 103 that has the structure described above is formed on the back surface (e.g., the surface furthest from the light-incident side) of the SOI substrate, by the vacuum vapor deposition method.
As shown in
An example of this is illustrated in
After producing the long wavelength sensor array 101, the long wavelength sensor array 101 is bonded to the short wavelength sensor array 105 and the insulator layer 103, and then the upper layer formation process described in the first specific example is performed to produce the image sensor 10 according to the present specific example. Note that, in the present specific example, the APD that is capable of avalanche multiplication can be utilized instead of the long wavelength sensor array 101 that utilizes the InGaAs-based semiconductor.
Next, the optical filter 111 that has the optical characteristics as illustrated in
The transmission spectrum of the optical filter 111 that is produced as described above is illustrated in
Also, the light source that is used with this optical filter 111 may be, for example, the one that is illustrated in
Note that the oscillation wavelength of the semiconductor laser as illustrated in
Also, a lens (such as a collimator lens) may be located at a prior stage to the light source 20 (such as a semiconductor laser), in order to efficiently project the laser light or the LED light to the imaged object. In the present specific example, light having a wavelength of 1.1 μm or more is utilized, and thus the retina is unlikely to be damaged even if the light is projected on the retina of a person. Thereby, an eye-safe system can be built. By using the image capturing system 1 composed of the above image sensor 10 and the light source 20, the visible light image and the infrared light information can be simultaneously acquired by the same optical system, and thereby it is possible to obtain the visible light image and the distance information that are accurately aligned to the visible light image. This image capturing system can advantageously be applied to the onboard collision prevention system, and also can be advantageously applied to the automatic focusing mechanism of the camera, as described herein.
In the above, the second specific example of the image sensor 10 according to the present embodiment has been described in detail with reference to
Next, a third specific example of the image sensor according to the present embodiment will be described with reference to
In the present specific example, the InGaAs-based long wavelength sensor array 101 illustrated in the second specific example is replaced by a FeS-based (FeSSe-based) sensor array as illustrated in
The image sensor 10 that utilizes the long wavelength sensor array 101 illustrated in
In the above, the third specific example of the image sensor 10 according to the present embodiment has been described with reference to
Next, a fourth specific example of the image sensor according to the present embodiment will be described with reference to
In the present specific example, the long wavelength sensor array 101 of the InGaAs system as illustrated in the second specific example is replaced by a CuInGaSe-based sensor array as illustrated in
The image sensor 10 that utilizes the long wavelength sensor array 101 as illustrated in
In the above, the fourth specific example of the image sensor 10 according to the present embodiment has been described with reference to
In the above, the specific examples of the image sensor 10 according to the present embodiment have been described in detail with reference to
As described above, in the image sensor 10 according to the present embodiment, the short wavelength sensor array 105 and the long wavelength sensor array 101 are electrically separated and stacked, and thereby the light of the long wavelength side can advantageously be imaged without creating defective pixels in the short wavelength sensor array 105. Also, in the image sensor 10 according to the present embodiment, the short wavelength sensor array 105 and the long wavelength sensor array 101 are electrically separated and stacked, and thereby the circuit driven with low voltage and the circuit driven with high voltage can advantageously be separated easily (e.g., more efficiently and quickly than when using past technology).
Further, the image sensor 10 according to the present embodiment can prevent the light of the short wavelength side from reaching the long wavelength sensor array 101 by providing the insulator layer 103, and thus can advantageously prevent the mixed color in the long wavelength sensor array 101. Also, utilization of the optical filter 111 can advantageously further reduce the mixed color of the light of the long wavelength side into the short wavelength sensor array 105, and improve the color reproducibility.
Also, both the visible light image and the distance information can be acquired by using the image capturing system 1 that uses the image sensor 10 according to the present embodiment, and the distance information can be associated with the visible light image easily (e.g., quickly) and accurately.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations are possible depending on design requirements and other factors insofar as they are within the scope of this disclosure or equivalents thereof.
Further, the effects described in this specification are merely illustrative or exemplified effects, and are not limitative. That is, with or in the place of the above effects, the technology according to the present disclosure may achieve other effects based on the description of this specification.
Additionally, the present technology may also be configured as below.
(A1)
An image sensor including a light receiving unit that includes
(A2)
The image sensor according to (A1), wherein
(A3)
The image sensor according to (A1) or (A2), further including
(A4)
The image sensor according to (A2) or (A3), wherein
(A5)
The image sensor according to any one of (A1) to (A4), wherein
(A6)
The image sensor according to any one of (A1) to (A4), wherein
(A7)
The image sensor according to any one of (A1) to (A6), further including
(A8)
The image sensor according to any one of (A1) to (A3), wherein
(A9)
The image sensor according to any one of (A1) to (A8), wherein
(A10)
The image sensor according to any one of (A1) to (A9), wherein
(A11)
The image sensor according to (A10), wherein
(A12)
The image sensor according to any one of (A1) to (A11), wherein
(A13)
An image capturing system including:
(A14)
The image capturing system according to (A13), further including
(A15)
The image capturing system according to (A14), wherein
(A16)
The image capturing system according to (A14) or (A15), wherein
(A17)
The image capturing system according to (A14) or (A15), wherein
(A18)
A production method of an image sensor, including:
(B1)
An automotive vehicle, including:
(B2)
The automotive vehicle according to (B1), further including:
(B3)
The automotive vehicle according to according to one or more of (B1) to (B2), further including:
(B4)
The automotive vehicle according to according to one or more of (B1) to (B3), further including:
(B5)
The automotive vehicle according to according to one or more of (B1) to (B4), where
(B6)
An electronic apparatus, including:
(B7)
The electronic apparatus according to according to (B6), further including: an optical system that directs light propagating from an imaged object to the imaging device.
(B8)
The electronic apparatus according to according to one or more of (B6) to (B7), further including:
(B9)
The electronic apparatus according to according to one or more of (B6) to (B8), further including:
(B10)
The electronic apparatus according to according to one or more of (B6) to (B9), further including:
(B11)
The electronic apparatus according to according to one or more of (B6) to (B10), further including:
(B12)
The electronic apparatus according to according to one or more of (B6) to (B11), where the optical filter transmits only a part of wavelength band λ0 among the infrared light band such that a mixed color of the incoming light is reduced in the first set of photoelectric conversion units.
(B13)
The electronic apparatus according to according to one or more of (B6) to (B12), where the first wavelength range of light that is reflected is visible light reflected into the first set of photoelectric conversion units, and where the second wavelength range of light that is transmitted is infrared light transmitted into the second set of photoelectric conversion units.
(B14)
An imaging device, including:
(B15)
The imaging device according to according to (B14), further including:
(B16)
The imaging device according to according to one or more of (B14) to (B15), further including:
(B17)
The imaging device according to according to one or more of (B14) to (B16), further including:
(B18)
The imaging device according to according to one or more of (B14) to (B17), further including:
(B19)
The imaging device according to according to one or more of (B14) to (B18), further including:
(B20)
The imaging device according to according to one or more of (B14) to (B19), where the first wavelength range of light that is reflected is visible light reflected into the first set of photoelectric conversion units, and where the second wavelength range of light that is transmitted is infrared light transmitted into the second set of photoelectric conversion units.
Number | Date | Country | Kind |
---|---|---|---|
2015-244083 | Dec 2015 | JP | national |
This application is a continuation of and claims priority to U.S. patent application Ser. No. 17/403,457, filed Aug. 16, 2021, which is a continuation of U.S. patent application Ser. No. 16/845,964, filed Apr. 10, 2020, now U.S. Pat. No. 11,122,227, which is a continuation of and claims priority to U.S. patent application Ser. No. 16/060,106, filed Jun. 7, 2018, now U.S. Pat. No. 10,681,292, which is a national stage application under 35 U.S.C. 371 and claims the benefit of PCT Application No. PCT/JP2016/086239 having an international filing date of Dec. 6, 2016, which designated the United States, which PCT application claimed the benefit of Japanese Priority Patent Application JP 2015-244083 filed Dec. 15, 2015, the entire contents of each of which are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 17403457 | Aug 2021 | US |
Child | 18229463 | US | |
Parent | 16845964 | Apr 2020 | US |
Child | 17403457 | US | |
Parent | 16060106 | Jun 2018 | US |
Child | 16845964 | US |