JP4265928B2 - Photoelectric encoder - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a photoelectric encoder used for precision measurement.
[0002]
[Prior art]
Conventionally, a photoelectric encoder (hereinafter also referred to as “encoder”) has been used for precise measurement of linear displacement and angular displacement. The encoder is mounted on a coordinate measuring machine or an image measuring machine. The encoder includes a light source, a scale including an optical grating, and a plurality of light receiving elements, and is arranged to be relatively movable with respect to the scale together with the light source. And.
[0003]
Specifically, the light receiving elements (PD) for detecting the phases A, B, AA, and BB are arranged close to each other in the vertical and horizontal directions, and the spatial phases are varied by 90 ° on the light receiving surfaces of the light receiving elements. Arrange the index grid. There is also known a photoelectric encoder in which the light receiving element itself is finely divided and arranged in a lattice shape so that the light receiving element itself can also serve as an index grating to reduce the size and cost (for example, patents). Reference 1). In the case of this photoelectric encoder, there is an advantage that the influence of burst noise can be reduced by spatially dispersing light receiving elements for detecting in-phase signals. Further, as an intermediate form between the two, there is also known a photoelectric encoder in which a common light receiving element is allocated to several index gratings and the light receiving elements for detecting the in-phase signal are dispersed.
[0004]
[Patent Document 1]
JP-A-7-190808 (paragraphs [0003], [0004], [0010], [0011], FIG. 1, FIG. 2, FIG. 5, FIG. 6)
[0005]
[Problems to be solved by the invention]
By the way, in order to take out the signal of each phase from the light receiving element, a metal wiring layer such as Al is formed on the light receiving element such as a photodiode (PD), and the metal wiring layer and the light receiving element are connected by a contact hole or the like. It has been made to connect. Normally, the metal wiring layer is arranged at the end of the diffusion region that becomes the light receiving surface so that the light receiving surface of the light receiving element is not covered by the metal wiring layer, and the end of the diffusion region and the metal wiring layer are contact holes. Connect with. However, in this case, the signal taken out from the end opposite to the end connected to the metal wiring layer is taken out through the diffusion region having a high resistance value. Is a problem. Therefore, as disclosed in Patent Document 1, a metal wiring layer is disposed in a space between one diffusion region and the next diffusion region of the light receiving element, and the light receiving elements are disposed at a plurality of locations in the longitudinal direction of the light receiving element. It is also known that the influence of the signal propagation delay inside the light receiving element is reduced by making contact with the metal wiring layer.
[0006]
However, in this case, since the metal wiring layer is formed between the diffusion regions of the light receiving element, the parasitic capacitance Csub is provided between the substrate (for example, a P-type Si substrate) serving as the light receiving element and the Al wiring layer. Occurs, which causes a problem that hinders the high-speed response of the encoder.
[0007]
The present invention has been made in view of such problems, and an object of the present invention is to provide a photoelectric encoder capable of increasing the effective light receiving area of the light receiving surface and reducing the capacitance caused by the wiring.
[0008]
[Means for Solving the Problems]
A photoelectric encoder according to the present invention includes a light source, a scale including a first optical grating that is irradiated with light from the light source and generates a light / dark pattern of light along the measurement axis, and relative movement with the light source relative to the scale. A light receiving element having a light receiving surface on which a bright and dark pattern along the measurement axis generated by the first optical grating is incident, and a period of the light and dark pattern by the first optical grating disposed on the light receiving surface of the light receiving element. Correspondingly, the second optical grating in which the light transmission portions and the conductive light shielding portions are alternately arranged periodically, and the contact portion that electrically connects the conductive light shielding portion and the light receiving surface directly below the light shielding portion. And a wiring connected to the conductive light shielding portion.
[0009]
According to the photoelectric encoder of the present invention, the conductive light-shielding portion of the second optical grating also serves as a wiring connected to the light-receiving element, and the conductive light-shielding portion and the light-receiving surface directly below the light-shielding portion are electrically connected. The contact part to connect is provided. For this reason, the effective light receiving area of the light receiving surface can be increased. Further, since the conductive light shielding portion and the light receiving element are connected by the contact portion, it is possible to prevent a capacitance from being formed between them. Therefore, the capacitance generated by the wiring can be reduced.
[0010]
In the photoelectric encoder according to the present invention, each conductive light-shielding portion extends in a direction orthogonal to the measurement axis, and is connected to the light-receiving surface of the light-receiving element through a contact portion at a plurality of locations in the extending direction of the conductive light-shielding portion. Can be. According to this, since the contact resistance between the contact portion and the light receiving surface can be lowered, the response speed of the photoelectric encoder can be improved.
[0011]
In the photoelectric encoder according to the present invention, the second optical grating includes a plurality of groups including a plurality of conductive light shielding portions, and the conductive light shielding portions are arranged with different spatial phases between the groups. be able to.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, first to third embodiments of a photoelectric encoder according to the present invention will be described with reference to the drawings. In the drawings describing the second and third embodiments, the same components as those shown in the already described embodiments are designated by the same reference numerals and the description thereof is omitted.
[0013]
[First Embodiment]
FIG. 1 is a diagram showing a schematic configuration of a photoelectric encoder 1 according to the first embodiment. The first embodiment is mainly characterized by the structure of the light receiving chip included in the light receiving unit, and the photoelectric encoder 1 will be described as a premise of this understanding. First, the configuration of the encoder 1 will be described. The encoder 1 includes a light emitting diode (LED) 3, a scale 5 arranged along an order close to the light emitting diode (LED) 3, and a light receiving unit 7.
[0014]
The light emitting diode 3 is an example of a light source, and the light 5 from the diode 3 is irradiated to the scale 5. The scale 5 includes a long transparent substrate 9 made of a transparent material such as glass, and a part thereof is shown in FIG. A first optical grating 11 is formed on the surface of the transparent substrate 9 opposite to the surface facing the light emitting diode 3 side. The first optical grating 11 is arranged such that a plurality of light shielding portions 13 are provided in a linear shape with a predetermined pitch, and each light shielding portion 13 extends in the depth direction of the drawing. The light shielding unit 13 is made of metal (for example, chromium).
[0015]
The light receiving unit 7 is arranged with a gap from the scale 5. The light receiving unit 7 includes a light receiving chip 15 located on the scale 5 side and a circuit board 17 on which the light receiving chip 15 is mounted. A plurality of photodiodes (hereinafter, “photodiodes” may be referred to as PDs) (not shown) are formed on the light receiving chip 15. The light receiving surfaces of these PDs face the first optical grating 11 side. PD is an example of a light receiving element. As the light receiving element, a phototransistor can be used instead of the PD. An IC chip 19 for calculation is mounted on the circuit board 17, and a displacement amount is calculated by the IC chip 19 based on optical signals detected by a plurality of PDs of the light receiving chip 15.
[0016]
The light receiving unit 7 is attached to the holder 21 together with the light emitting diode 3, and the holder 21 is movable in the longitudinal direction of the scale 5 indicated by X in the drawing. That is, the photoelectric encoder 1 measures the displacement amount by moving the holder 21 with respect to the fixed scale 5. Therefore, the X direction becomes the measurement axis (hereinafter, the X direction is referred to as “measurement axis X”). Note that the present invention can also be applied to a type in which the light emitting diode 3 and the light receiving unit 7 are fixed and the scale 5 is moved to measure the amount of displacement. Therefore, the scale of the present invention is arranged to be relatively movable with respect to the light receiving unit and the light source.
[0017]
Next, the measurement operation of the photoelectric encoder 1 will be briefly described. When the light L from the light emitting diode 3 is applied to the first optical grating 11 of the scale 5, a light / dark pattern is generated by the first optical grating 11. Then, a change in light / dark pattern (sine wave-like optical signal) generated by moving the holder 21 along the measurement axis X is detected by each photodiode (PD) formed on the light receiving chip 15. That is, an A phase (0 degree) optical signal, a B phase (90 degree) optical signal that is 90 degrees out of phase with the A phase, and an AA phase (180 degree) light that is 180 degrees out of phase with the A phase. The optical signal of the BB phase (270 degrees) whose phase is shifted by 270 degrees from the signal and the A phase is detected by the corresponding PD.
[0018]
An electrical signal generated by each optical signal is sent to the IC chip 19. In the IC chip 19, after predetermined processing (DC component removal or the like) is performed on the A phase and the B phase, the displacement amount is calculated based on the processed A phase and B phase. The result is output to a display unit (not shown). The above is the operation of the photoelectric encoder 1.
[0019]
The main feature of the first embodiment is the light receiving chip 15, which will be described in detail. First, the planar structure of the light receiving chip 15 will be described. FIG. 2 is a plan view schematically showing the entire light receiving chip 15 as viewed from the first optical grating 11 side in FIG. The light receiving surfaces 31 of the four photodiodes 23, 25, 27, and 29 and the second optical grating 33 formed so as to cover the light receiving surfaces 31 are arranged in two rows and two columns on the xy plane facing the first optical grating. Has been. The x-axis is in the same direction as the measurement axis X described in FIG. A set of PDs 23 and 25 and a set of PDs 27 and 29 are arranged along the measurement axis X, respectively.
[0020]
The second optical grating 33 has five conductive light shielding portions 35 extending in the y direction (a direction perpendicular to the measurement axis X) arranged on the light receiving surface 31 at intervals. In other words, the second optical grating 33 is disposed on the light receiving surface 31, and the light transmissive portions and the conductive light shielding portions are alternately disposed periodically corresponding to the period of the bright and dark pattern by the first optical grating 11. Become. As a result, a phase difference is formed on the light receiving surface 31. The light receiving surface 31 is divided into six regions that receive light of the same phase by five light blocking portions 35. Note that the number of light shielding portions 35 constituting the second optical grating 33 is not limited to five.
[0021]
The pitch of the conductive light shielding portions 35 of the PDs 27 and 29 is shifted from the pitch of the conductive light shielding portions 35 of the PDs 23 and 25 by λ / 4. Here, λ is the wavelength of the optical signal. That is, the second optical grating 33 includes a plurality of groups each including a plurality of conductive light shielding portions, and the conductive light shielding portions are arranged with different spatial phases between the groups.
[0022]
Four optical signals having different phases (A phase, B phase, AA phase, BB phase) generated based on the light irradiated to the first optical grating 11 from the light source 3 of FIG. The light enters the corresponding light receiving surface 31 of the diode.
[0023]
Specifically, among the PDs 23 and 25 arranged along the measurement axis X, an A-phase (0 degree) optical signal is incident on the light-receiving surface 31 of the PD 23, and the phase is 180 degrees from the A-phase to the light-receiving surface 31 of the PD 25. The AA phase (180 degrees) optical signal that has shifted is incident. Similarly, among the PDs 27 and 29 arranged along the measurement axis X, an optical signal of phase B (90 degrees) whose phase is shifted by 90 degrees from the phase A is incident on the light receiving surface 31 of the PD 27, and the light receiving surface 31 of the PD 29. The BB phase (270 degrees) optical signal whose phase is shifted by 270 degrees from the A phase enters. As described above, optical signals of the A phase are detected by the PD 23, the AA phase by the PD 25, the B phase by the PD 27, and the BB phase by the PD 29 are detected.
[0024]
Of the conductive light shielding portions 35 arranged on each light receiving surface 31, the central conductive light shielding portion 35-1 is connected to the wiring 37. The wiring 37 and the conductive light shielding portion 35 are formed by patterning at the same time. A plurality of contact portions 39 connected to the conductive light shielding portion 35-1 are disposed under the conductive light shielding portion 35-1. Thus, the conductive light shielding portion 35-1 is connected to the light receiving surface 31 via the contact portion 39 at a plurality of locations in the extending direction thereof. The number of contact portions 39 disposed on each light receiving surface 31 is not limited to a plurality, and may be one.
[0025]
Next, the cross-sectional structure of the light receiving chip 15 will be described. FIG. 3 is a schematic view of the light receiving chip 15 of FIG. 2 as viewed from the III (a) -III (b) cross section. The light receiving chip 15 includes an n-type semiconductor substrate 41. A p-type diffusion region 43 is formed on one surface of the substrate 41. The junction between the semiconductor substrate 41 and the diffusion region 43 becomes the photodiode 23. Of the one surface of the semiconductor substrate 41, the region where the p-type diffusion region 43 is formed becomes the light receiving surface 31.
[0026]
One surface of the semiconductor substrate 41 is covered with an insulating film 45 such as a silicon oxide film so as to cover the diffusion region 43. On the insulating film 45, a plurality of conductive light shielding portions 35 are formed at intervals. The material of the light shielding part 35 is, for example, a metal such as chromium or aluminum.
[0027]
A contact hole 47 is formed in the insulating film 45 between the conductive light shielding portion 35-1 and the light receiving surface 31. In the contact hole 47, a contact portion 39 made of a conductive plug (for example, aluminum) is formed. The contact part 39 electrically connects the conductive light shielding part 35-1 and the light receiving surface 31 immediately below the light shielding part.
[0028]
In the first embodiment, the conductive plug is used as the contact portion 39. However, when the film that becomes the light shielding portion 35 is formed on the insulating layer 45, this film is buried in the contact hole 47, and this is used as the contact portion. May be.
[0029]
A protective film 49 such as a silicon oxide film or a silicon nitride film is formed so as to cover the conductive light shielding portion 35. A common electrode (for example, an Au electrode) 51 for the PDs 23, 25, 27, and 29 is formed on the entire other surface of the semiconductor substrate 41.
[0030]
The main effects of the photoelectric encoder 1 according to the first embodiment will be described.
[0031]
(1) According to the first embodiment, the effective light receiving area of the light receiving surface 31 can be increased. This will be described in comparison with a comparative example. FIG. 4 is a plan view schematically showing the arrangement relationship between the pair of second optical gratings 33 and the light receiving surface 31 provided in the photoelectric encoder according to the comparative example.
[0032]
In the comparative example, the wiring 37 is disposed between the conductive light shielding portions 35 on the light receiving surface 31. A contact portion 39 under the wiring 37 is in contact with the light receiving surface 31. Since a part of the wiring 39 is located on the light receiving surface 31, the effective light receiving area of the light receiving surface 31 is reduced. On the other hand, in the first embodiment, as shown in FIG. 2, the conductive light shielding portion 35-1 of the second optical grating 33 also serves as the wiring 37 connected to the PD 23, and the conductive light shielding portion 35. A contact portion 39 in contact with the light receiving surface 31 is provided under -1. For this reason, since the effective light receiving area of the light receiving surface 31 can be increased, a highly accurate encoder can be obtained.
[0033]
{Circle around (2)} In the first embodiment, as shown in FIG. 3, the conductive light shielding portion 35-1 and the p-type diffusion region 43 are connected by a contact portion 39. Accordingly, no capacitance is formed during this period. Thereby, the response speed of the photoelectric encoder can be increased.
[0034]
(3) In the first embodiment, as shown in FIG. 2, a plurality (here, three) of contact portions 39 are in contact with each light receiving surface 31. Since the plurality of contact portions 39 are disposed under the conductive light shielding portion 35-1, the effective light receiving area of the light receiving surface 31 is not reduced even if the contact portions 39 are increased. Since the light receiving surface 31 is in contact with the plurality of contact portions 39, the contact area between the contact portion 39 and the light receiving surface 31 (the contact area is the contact between the light receiving surface and the contact portion when there is one contact portion). In the case where there are a plurality of contact portions, it is the total area of the above regions). Therefore, since the contact resistance between the contact part 39 and the light receiving surface 31 can be lowered, the response speed of the photoelectric encoder 1 can be improved.
[0035]
[Second Embodiment]
The second embodiment will be described focusing on the differences from the first embodiment. FIG. 5 is a plan view schematically illustrating the entire light receiving chip 15 provided in the photoelectric encoder of the second embodiment when viewed from the first optical grating side. FIG. 6 is an enlarged view of a region indicated by VI in FIG. FIG. 7 is a schematic view of FIG. 6 as seen from the section VII (a) -VII (b).
[0036]
As shown in FIGS. 5 to 7 (particularly FIG. 5), a set of PD 61 for A phase, PD 63 for B phase, PD 65 for AA phase, and PD 67 for BB phase arranged along the measurement axis X is provided. There are two. These sets are arranged along the measurement axis X. The light receiving chip 15 is provided with four wires 69 (wires for A phase, B phase, AA phase, and BB phase) along the measurement axis X. Each wiring 69 is connected to a wiring 37 through which a signal having a corresponding phase flows.
[0037]
An n ⁺ type diffusion region 71 is formed in the semiconductor substrate 41 between the p type diffusion regions 43 in FIG. As a result, the p-type diffusion region 43 is separated from the adjacent diffusion region 43, that is, each photodiode is isolated.
[0038]
The second embodiment improves the averaging effect compared to the first embodiment. This will be described below. In principle, measurement is possible if there are a number of photodiodes corresponding to a plurality of optical signals having different phases. Therefore, in the case of four optical signals having different phases, it is sufficient if there are four photodiodes as in the first embodiment. By the way, the light intensity may vary due to the light intensity distribution of the light source, the dirt on the scale surface, and the like. According to the first embodiment, each phase of the optical signal is detected at a single location, and thus is easily affected by variations in the amount of light. For example, when the location of the PD 23 for A phase shown in FIG. 2 is lower than the location of the other PDs 25, 27, and 29, the output of the phase A is weak, so the measurement accuracy is high. descend.
[0039]
Therefore, in the second embodiment, the A phase PD 61, the B phase PD 63, the AA phase PD 65, and the BB phase PD 67 are set as one set, and a plurality of sets are arranged along the measurement axis X direction. It was. According to this, since the optical signal of each phase can be detected at a plurality of locations, the influence of the variation in the amount of light can be reduced (this is referred to as “averaging effect”).
[0040]
The photoelectric encoder according to the second embodiment configured as described above also has the same effect as that of the first embodiment.
[0041]
[Third Embodiment]
The third embodiment will be described with reference to FIGS. 8 to 10 with a focus on differences from the second embodiment. FIG. 8 is a plan view schematically showing the entire light receiving chip 15 provided in the photoelectric encoder of the third embodiment when viewed from the first optical grating side, and corresponds to FIG. 9 is an enlarged view of the area indicated by IX in FIG. 8, and corresponds to FIG. FIG. 10 is a schematic view of FIG. 9 as seen from the X (a) -X (b) cross section, and corresponds to FIG.
[0042]
As shown in FIGS. 8 to 10, in the third embodiment, among the plurality of conductive light shielding portions 35 constituting the second optical grating 33, the conductive light shielding portion 35-2 (not connected to the contact portion 39) ( Another example of the conductive light shielding portion is also connected to the wiring 37. As a result, the potential of the conductive light shielding part 35-2 can be fixed, so that the stray capacitance caused by the conductive light shielding part 35-2 can be prevented.
[0043]
In the third embodiment, the conductive light shielding part 35 other than the central conductive light shielding part 35-1 is also connected to the contact part 39. Accordingly, since the number of contact portions 39 can be increased, the contact resistance can be further reduced.
[0044]
In the first to third embodiments, the displacement amount is measured using optical signals having different phases (A phase, B phase, AA phase, and BB phase optical signals). The encoder is not limited to this. For example, three optical signals having different phases (an optical signal having a phase of 0 degree, an optical signal having a phase shifted by 120 degrees from 0 degree, and an optical signal having a phase shifted by 240 degrees from 0 degree) are also included in the present invention. It can be applied to such a photoelectric encoder.
[0045]
In addition to the A-phase and B-phase signals, the AA-phase and BB-phase signals generated by inverting them are generated by removing the DC component contained in the A-phase and B-phase signals, This is to ensure reliability and high-speed followability. Further, the reason why the A phase and the B phase are used for the measurement of the displacement amount is to determine the moving direction of the holder 21 (the light receiving unit 7 and the light emitting diode 3). The quantity can be measured. Therefore, the present invention can also be applied to an optoelectronic encoder that uses A-phase and B-phase signals and does not use AA-phase and BB-phase signals, and a photoelectric encoder that uses only A-phase signals.
[0046]
As shown in FIG. 1, the photoelectric encoder 1 according to the first to third embodiments measures the amount of displacement using the light L from the light emitting diode 3 that has passed through the first optical grating 11 of the scale 5. This is a so-called transmission type. However, the present invention can also be applied to a reflection type, that is, when the amount of displacement is measured using the light L from the light emitting diode 3 reflected by the first optical grating 11 of the scale 5.
[0047]
【The invention's effect】
As described above, according to the photoelectric encoder according to the present invention, since the effective light receiving area of the light receiving surface of the light receiving element can be increased, a highly accurate encoder can be realized. Moreover, since the capacity generated by the wiring can be reduced, the response speed of the encoder can be increased.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic configuration of a photoelectric encoder according to a first embodiment.
FIG. 2 is a plan view schematically showing the entire light receiving chip viewed from the first optical grating side in FIG.
3 is a schematic view of the light-receiving chip of FIG. 2 as viewed from the III (a) -III (b) cross section.
FIG. 4 is a plan view schematically showing an arrangement relationship between a second optical grating and a light receiving surface provided in a photoelectric encoder according to a comparative example.
FIG. 5 is a plan view of the entire light receiving chip provided in the photoelectric encoder according to the second embodiment when viewed from the first optical grating side.
6 is an enlarged view of a region indicated by VI in FIG. 5;
FIG. 7 is a schematic view of FIG. 6 as viewed from the section VII (a) -VII (b).
FIG. 8 is a plan view of the entire light receiving chip provided in the photoelectric encoder according to the third embodiment when viewed from the first optical grating side.
FIG. 9 is an enlarged view of a region indicated by IX in FIG. 8;
FIG. 10 is a schematic view of FIG. 9 as seen from the X (a) -X (b) cross section.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Photoelectric encoder, 3 ... Light emitting diode, 5 ... Scale, 7 ... Light-receiving part, 9 ... Transparent substrate, 11 ... 1st optical grating, 13 ... Light-shielding part , 15 ... light receiving chip, 17 ... circuit board, 19 ... IC chip, 21 ... holder, 23, 25, 27, 29 ... photodiode (PD), 31 ... light receiving surface 33 ... second optical grating, 35 ... conductive light shielding part, 37 ... wiring, 39 ... contact part, 41 ... n-type semiconductor substrate, 43 ... p-type diffusion region, 45 ... insulating film, 47 ... contact hole, 49 ... protective film, 51 ... common electrode, 61, 63, 65, 67 ... photodiode (PD), 69 ... wiring, 71... N ⁺ type diffusion region

Claims (3)

A light source;
A scale including a first optical grating irradiated with light from the light source to generate a light-dark pattern of light along the measurement axis;
A light-receiving element having a light-receiving surface that is arranged so as to be relatively movable with the light source with respect to the scale and on which a light-dark pattern along the measurement axis generated by the first optical grating is incident;
A second optical grating arranged on the light receiving surface of the light receiving element, wherein light transmitting portions and conductive light shielding portions are alternately arranged periodically corresponding to the period of the bright and dark pattern by the first optical grating;
A contact portion for electrically connecting the conductive light shielding portion and the light receiving surface immediately below the light shielding portion;
A photoelectric encoder comprising: a wiring connected to the conductive light shielding portion. Each of the conductive light shielding portions extends in a direction orthogonal to the measurement axis, and is connected to the light receiving surface of the light receiving element via the contact portion at a plurality of locations in the extending direction of the conductive light shielding portion. The photoelectric encoder according to claim 1. The second optical grating includes a plurality of groups composed of a plurality of conductive light shielding portions,
The photoelectric encoder according to claim 1, wherein the conductive light-shielding portions are arranged with different spatial phases between groups.

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