JP2009025286A - Optical encoder and electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical encoder capable of getting precisely moving information and reference position information at low cost. <P>SOLUTION: This optical encoder is provided with a moving body 1, a photoreception part 2 and a light emitting part 3. The moving body 1 has a light-on part 6, a light-off part 7 and an index pattern part 10. Each of photoreception elements 11-15 is formed to have (1/6) P of width dimension, four of the photoreception elements 11-14 are arranged along a moving direction with (1/12) P of space, and photoreception elements 14, 15 are arranged with (1/4) P of space. Phases of incremental channel signals A, B output from differential amplifiers 16, 17 are shifted by 60° from that of an index channel signal ID output from an amplifier 18. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an optical encoder that detects a position, a moving speed, a moving direction, and the like of a moving body using a light receiving element, and as an example, particularly used in a printing machine such as a copying machine or a printer, an FA (factory automation) apparatus, or the like. And a suitable optical encoder.

  Conventionally, as an optical encoder, Patent Document 1 (Japanese Utility Model Laid-Open No. 6-7013) discloses an encoder having an encoder plate with an index track disposed at the center and an incremental track disposed at the outer periphery. In this optical encoder, the index channel signal obtained from the index track is stabilized, the reference position of the encoder plate is detected by the stabilized index channel signal, and the movement of the encoder plate is detected by the incremental channel signal obtained from the incremental track. is doing.

  Patent Document 2 (Japanese Patent Laid-Open No. 58-37515) discloses that an index channel signal having a high peak value is obtained by arranging slits of two code plates at non-uniform intervals. . In the technique disclosed in Patent Document 2, a series of scales including a light-on portion and a light-off portion includes an index pattern in addition to an incremental pattern. With the technique of Patent Document 2, the light emitting area and the light receiving area of the optical encoder can be reduced.

  In Patent Document 3 (Japanese Patent Application Laid-Open No. 2007-64981), a moving body includes an incremental pattern and an index pattern in a series of scales, and outputs an incremental channel signal as a moving signal of the moving body. An optical encoder is disclosed that generates an index channel signal by logically combining the outputs of at least three photodiodes of the array.

  By the way, in the optical encoder described in Patent Document 1, the index track is arranged at the light receiving center in order to accurately detect the index channel signal for detecting the origin (reference position detection). As described above, in the method of obtaining the index channel signal by separating the index track from the incremental track, it is necessary not only to widen the optical area to be used but also to produce parallel light corresponding to the wide optical area. In addition, since it is necessary to secure a light receiving area, the cost is increased.

  On the other hand, in the above-described optical encoder of Patent Document 2, the index channel signal having a peak value different from that of the incremental channel signal causes distortion or shift in the phase of the incremental channel signal, and the movement detection characteristics deteriorate.

  Further, in the optical encoder of Patent Document 3 described above, when a photodiode array that outputs an incremental channel signal is used to obtain an index channel signal as it is, due to the difference in pattern between the incremental pattern and the index pattern, When light enters the index pattern, the phase shift of the incremental channel signal becomes large, and the movement detection characteristic is deteriorated.

  In Patent Document 4 (Japanese Patent Laid-Open No. 2003-294494), a plurality of light receiving elements having different light receiving areas including the photodiodes ZPD1 to 4 for detecting the origin are provided, and signals of detection signals from these light receiving elements are provided. An optical encoder having a correction capacitor in a processing circuit, detecting a differential signal with a differential amplifier, and detecting the position of the origin is shown. However, in Patent Document 4, since the light receiving areas of the origin detection photodiodes ZPD1 to ZPD4 and the light reception areas of the non-origin detection photodiodes ZBPD1 to ZPD4 are different, even if correction is performed, there is always a correlation with the variation in the amount of received light Therefore, it is not possible to detect the position of the origin with high accuracy.

  Further, in the optical encoder disclosed in Patent Document 5 (Japanese Patent Application Laid-Open No. 2005-61896), when n signals of change amounts of the moving body are extracted, the n number of slits are arranged in the moving direction with respect to the moving body. A common multiple of k photodiodes and m photodiodes are arranged in a line, and output signals of a plurality of photodiodes out of the k photodiodes are added to obtain n pieces of change in the moving body. A movement information signal is obtained.

  Further, in Patent Document 6 (Japanese Patent Application Laid-Open No. 2006-84458), the number of photos arranged by the product of the number of independent movement information signals and the power of the number of light transmission regions facing the light receiving unit is arranged. An optical encoder having a diode is disclosed.

In Patent Documents 5 and 6, the light receiving area of each photodiode is reduced to subdivide the photodiode to obtain a precise movement information signal. However, an index channel signal for detecting the reference position of the moving body can be obtained. It is not a thing.
Japanese Utility Model Publication No. 6-7013 JP 58-37515 A JP 2007-64981 A JP 2003-294494 A Japanese Patent Laid-Open No. 2005-61896 JP 2006-84458 A

  Accordingly, an object of the present invention is to provide an optical encoder capable of accurately obtaining movement information and reference position information at low cost.

In order to solve the above problems, an optical encoder of the present invention includes a light emitting unit and a light receiving unit including a plurality of light receiving elements arranged in one direction in a region where light from the light emitting unit can reach. A light-on portion that causes the light to enter the light receiving element when passing through a predetermined position corresponding to the light receiving element and the light receiving light when passing through a predetermined position corresponding to the light receiving element. A photoelectric encoder that has a light-off portion that is not incident on the element and detects the movement of the moving body in which the light-on portion and the light-off portion alternately pass the predetermined position when moving in the one direction. Yes,
The moving body includes an index pattern portion arranged at a predetermined reference position,
Furthermore, the light on part and the light off part of the moving body pass through a predetermined position corresponding to the light receiving element, and the first light receiving signal output from the light receiving element and the index pattern part of the moving body are An output unit for inputting a second light receiving signal output from the light receiving element by passing through a predetermined position corresponding to the light receiving element;
The output section
Based on at least the first light reception signal of the first and second light reception signals, an incremental channel signal representing movement information of the moving body is output, and among the first and second light reception signals, An index channel signal representing the reference position of the moving body is output based on at least the second received light signal, and the incremental channel signal and the index channel signal are out of phase.

  According to the optical encoder of the present invention, the index channel signal representing the reference position of the moving body is out of phase with the incremental channel signal representing the movement information of the moving body, so the index channel signal and the incremental channel signal Mutual interference can be suppressed. Therefore, the phase shift and distortion of the incremental channel signal can be suppressed, and the movement information and the reference position information can be obtained accurately at low cost.

  In the optical encoder according to an embodiment, the output unit electrically adds received light signals having different phases output from a plurality of light receiving elements, and outputs the incremental channel signal.

  According to the optical encoder of this embodiment, since the incremental channel signal is obtained by electrically adding received light signals having different phases output from a plurality of light receiving elements, a phase shift caused by interference due to the index channel signal. Are averaged to reduce the phase shift. In addition, the influence of distortion that occurs when the output of the light receiving element is inverted is reduced.

In the optical encoder of one embodiment, the output unit is
A logical operation unit that receives a light reception signal output from the first and second light reception elements of the plurality of light reception elements and outputs a result of logical operation of both light reception signals as an index channel signal;
The light incident state of the first and second light receiving elements when the index pattern portion passes through a predetermined position corresponding to at least one of the first light receiving element and the second light receiving element. Combination of light non-incident state and light incident state of the first and second light receiving elements when the light on part or light off part passes through a predetermined position corresponding to the first and second light receiving elements. And the combination of the light non-incident state is different.

  According to the optical encoder of this embodiment, an index channel signal representing the reference position of the moving body can be obtained by performing a logical operation on the received light signals output from the first and second light receiving elements.

  In the optical encoder according to an embodiment, the light receiving unit outputs a plurality of movement information signals (A +, A−, B +, B−) that are independent from each other based on the light reception signals of the light receiving elements, and a predetermined number of light beams. The number of the light receiving elements is the same as the number of the movement information signals which are arranged corresponding to the ON portion and are independent of each other and the power of the number of the corresponding light ON portion.

  According to the optical encoder of this embodiment, since the number of the light receiving elements is equal to the product of the number of the independent movement information signals and the power of the number of the corresponding light-on portions, By subdividing, it is possible to reduce the phase variation between the incremental signals due to the movement information signal.

  In the optical encoder according to an embodiment, the dimension of the index pattern portion of the moving body in the moving direction is shorter than the dimension of the light-on portion in the moving direction and the dimension of the light-off portion in the moving direction.

  According to the optical encoder of this embodiment, it is possible to reduce the light wraparound from the index pattern portion to the corresponding region of the light-off portion and the light-on portion that form the incremental pattern portion. Thereby, reading errors in the index pattern portion can be reduced, and phase variations of the incremental channel signal can be reduced.

In the optical encoder of one embodiment, the moving body is
The index pattern side portions that are adjacent to both sides of the movement direction of the index pattern portion and that make the light not incident on the light receiving element when passing through a predetermined position corresponding to the light receiving element,
Two index pattern side portions adjacent to both sides of the movement direction of the index pattern portion are symmetric with respect to the index pattern portion,
The index pattern portion makes the light incident on the light receiving element when passing through a predetermined position corresponding to the light receiving element.

  According to the optical encoder of this embodiment, since the wraparound of light from the index pattern portion is equal to the side portions of the index pattern on both sides of the index pattern portion, the reduction of wraparound light is biased symmetrically. It is eliminated and the wraparound of light can be reduced most efficiently.

  In an optical encoder according to an embodiment, a product of a reciprocal of a number that is a natural number times the number of the light receiving elements corresponding to one light-on portion at a predetermined position and an arrangement pitch of the light-on portions. The dimension of the index pattern portion in the moving direction was used.

  According to the optical encoder of this embodiment, when the number of light receiving elements corresponding to one light-on portion is, for example, 3, 4, 5, 6,..., The index pattern portion has an arrangement pitch of the light-on portion. The moving direction dimension (width dimension) is 1 / 3n, 1 / 4n, 1 / 5n, and 1 / 6n times P (n is a natural number). Accordingly, since the number and width dimensions of the light receiving elements and the width dimension of the index pattern portion can be matched, the index channel signal can be generated relatively easily by logical operation using signals obtained from the light receiving elements.

In the optical encoder of one embodiment, the light receiving unit is
A first light receiving element group composed of a number of adjacent light receiving elements corresponding to one light-off portion of the moving body, and the same number of adjacent light receiving elements as the first light receiving element group, and the above And a second light receiving element group at a position corresponding to the light-off portion of the moving body when the index pattern part of the moving body and the index pattern side part are at a position corresponding to the first light receiving element group. ,
Further, when the light-off part of the moving body is at a position corresponding to the first light receiving element group, another light off part or the index pattern part of the moving body corresponds to the second light receiving element group. In position
The output section
A first addition signal obtained by adding a plurality of light receiving signals output from the first light receiving element group and a second addition signal obtained by adding a plurality of light receiving signals output from the second light receiving element group are input. And a differential amplifier for comparing and calculating the first addition signal and the second addition signal.

  According to the optical encoder of this embodiment, when the index pattern portion of the moving body and the index pattern side portions are at positions corresponding to the first light receiving element group, the light off portion of the moving body is It exists in the position corresponding to 2 light receiving element groups. Therefore, the differential amplifier includes a first addition signal obtained by adding a plurality of light receiving signals output from the plurality of light receiving elements corresponding to the index pattern part and the index pattern side part, and a plurality of light receiving elements corresponding to the light-off part. A second addition signal obtained by adding a plurality of light reception signals to be output is compared and calculated, and an index channel signal is output as a result of the comparison and calculation. This differential amplifier eliminates common-mode noise and suppresses malfunctions. Further, since the first and second addition signals are obtained by adding the light reception signals of a plurality of light receiving elements, the light receiving area is widened and the SN of the signal can be improved.

  When both the first light receiving element group and the second light receiving element group are at positions corresponding to the light-off part or the light-on part, the first addition signal and the second addition signal are the same signal. The differential amplifier does not output an index channel signal.

Moreover, in the optical encoder of one embodiment, a first AND circuit to which a plurality of movement information signals having different phases are input;
A second AND circuit to which an AND signal output from the first AND circuit and an output signal of the differential amplifier are input;

  In this embodiment, an index channel signal synchronized with the incremental channel signal based on the movement information signal is obtained from the second AND circuit. Therefore, the phase relationship between both phases of the incremental channel signal and the index channel signal can be maintained, and the design of the subsequent circuit for processing the encoder output becomes easy.

In the optical encoder of one embodiment,
The index pattern part is
The incremental pattern portion formed by the light-on portion and the light-off portion is adjacent to the direction perpendicular to the moving direction of the moving body.

  According to the optical encoder of this embodiment, when the index pattern portion is arranged in the direction orthogonal to the movement direction with respect to the incremental pattern portion, the phase of the incremental channel signal and the index channel signal is shifted. Therefore, mutual interference between the index channel signal and the incremental channel signal can be suppressed, and phase shift and distortion of the incremental channel signal can be suppressed.

  That is, even when the index pattern portion is arranged in a different area from the incremental pattern portion, if the phase of the incremental channel signal and the index channel signal match, noise in the motor of the drive unit and the signal processing circuit It becomes easy to cause malfunction by being influenced by.

  In this embodiment, it is preferable that the output unit performs a differential operation between the second light receiving signal and the first light receiving signal and outputs the index channel signal. This differential operation is preferable for matching the index channel signal and the incremental channel signal.

  According to this embodiment, it is possible to suppress the fluctuation of the light amount and the phase fluctuation in the incremental pattern portion from causing the waveform loss of the index channel signal, and it is possible to suppress malfunction.

  In addition, since there is usually about one index pattern portion per one round of the moving body, a fixed amount is obtained by the light receiving element corresponding to the incremental pattern portion except when the index pattern portion passes a predetermined position corresponding to the light receiving element. The amount of light can be received. Thereby, an offset can be formed between the light receiving amount of the light receiving element corresponding to the index pattern portion and the light receiving amount of the light receiving element corresponding to the incremental pattern portion. Therefore, by taking the differential of the received light signals from both light receiving elements, it is possible to suppress malfunctions such as signal inversion due to disturbance light or the like.

In the optical encoder of one embodiment, the movement direction dimension of one pattern and the movement direction dimension of the index pattern part by the pair of adjacent light-on parts and light-off parts are the same,
The light receiving part is
A light receiving element having light incident from the index pattern portion and having a moving direction dimension that is the same as the moving direction dimension of the index pattern portion is provided.

  According to this embodiment, the light receiving element whose moving direction dimension is 1 pitch can obtain the light amount of two patterns (two periods) of the incremental pattern portion from the index pattern portion. And the said output part can obtain the index channel signal for 1 period by performing the differential calculation of the said 1st light reception signal and a 2nd light reception signal. Further, by performing a logical operation on the index channel signal and the incremental channel signal, a one-pulse index channel signal can be generated.

  In addition, when the light receiving unit has a light receiving element that has the one-pitch moving direction dimension and receives light from the incremental pattern unit, the light receiving element that has the one-pitch moving direction dimension is the incremental pattern unit. Always receives a certain amount of light. Therefore, the differential output between the light receiving signal by the one-pitch light receiving element that receives light from the incremental pattern portion and the light receiving signal by the one pitch light receiving element that receives light from the index pattern portion is used as an index channel signal. Thus, it is possible to suppress the periodic fluctuation of the index channel signal. In addition, by setting the width (dimension in the moving direction) of the two light receiving elements for obtaining the index channel signal to the same pitch, the parasitic capacitance caused by both light receiving elements can be made uniform, and malfunction due to power supply noise or the like can be suppressed. .

In the optical encoder of one embodiment, the light receiving unit is
A first index light receiving element on which light from the index pattern portion is incident;
A second index light receiving element adjacent to the first index light receiving element in the moving direction and having the same moving direction dimension as the moving direction dimension of the first index light receiving element;
The output section
The first light receiving signal output from the first index light receiving element is larger than the reference incremental channel signal, and the second light receiving signal output from the second index light receiving element is the reference incremental channel signal. The index channel signal is output only when it is smaller than.

  According to this embodiment, the output unit outputs a first light receiving signal output from the first index light receiving element that is larger than a reference incremental channel signal and the second index light receiving element. The index channel signal is output only when the second received light signal is smaller than the reference incremental channel signal. As a result, it is possible to prevent erroneous detection of the index pattern part due to fluctuations in the amount of light from the index pattern part.

In the optical encoder of one embodiment, the output unit is
The incremental channel signal and the index channel signal are combined, and the incremental channel signal is present in one voltage range of a first voltage range above a reference voltage and a second voltage range below the reference voltage. The index channel signal outputs a composite signal existing in the other voltage range of the two voltage ranges.

  According to this embodiment, by outputting a synthesized signal obtained by synthesizing the incremental channel signal and the index channel signal, the number of output signals can be reduced, and the mounting area can be suppressed.

The electronic device according to an embodiment includes the optical encoder according to the embodiment described above, and is further differentially generated by a first voltage obtained by shifting the combined signal from the output unit from the reference voltage to the one voltage range. A first differential operation unit that calculates and outputs an incremental channel signal;
A second differential operation unit that outputs an index channel signal by performing a differential operation on the combined signal from the output unit with a second voltage shifted from the reference voltage to the other voltage range.

  According to the electronic apparatus of this embodiment, by having the first and second differential operation units, the synthesized signal from the output unit of the optical encoder is separated into an incremental channel signal and an index channel signal. This makes it easy to perform subsequent processing such as motor control. Further, since the first and second differential operation units perform the differential operation using the first and second voltages shifted from the reference voltage, the influence of the offset can be avoided.

  Further, in the electronic apparatus according to an embodiment, since the optical encoder is provided, movement information (incremental channel signal) and reference position information (index channel signal) can be accurately obtained at low cost.

  According to the optical encoder of the present invention, the index channel signal representing the reference position of the moving body is out of phase with the incremental channel signal representing the movement information of the moving body, so the index channel signal and the incremental channel signal Mutual interference can be suppressed. Therefore, the phase shift and distortion of the incremental channel signal can be suppressed, and the movement information and the reference position information can be obtained accurately at low cost.

  Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

(First embodiment)
FIG. 1 shows a first embodiment of an optical encoder according to the present invention. The first embodiment includes a moving body 1, a light receiving unit 2, and a light emitting unit 3. The light emitting unit 3 is composed of a light emitting element such as an LED (light emitting diode). The light receiving unit 2 includes five light receiving elements 11 to 15. Further, the moving body 1 is movable in the direction indicated by the arrow X1 or X2, and the light-on part 6 and the light-off part 7 are arranged alternately in the movement direction. In addition, the moving body 1 includes an index pattern portion 10 that is sandwiched between the light-off portion 7 and the light-off portion 8 from both sides in the moving direction. The light-off part 8 has a shorter moving direction dimension (width dimension) than the light-off part 7. The light-on unit 6 and the index pattern unit 10 allow the light from the light emitting unit 3 to pass to the light receiving unit 2 side. On the other hand, the light-off unit 8 does not allow the light from the light emitting unit 3 to pass to the light receiving unit 2 side. The light receiving elements 11 to 15 are formed of photodiodes.

  In this embodiment, when the arrangement pitch of the light-on portions 6 of the moving body 1 is P, the width dimension of each of the light receiving elements 11 to 15 is (1/6) P. The four light receiving elements 11 to 14 are arranged in the moving direction with an interval of (1/12) P, and the light receiving elements 14 and 15 are arranged with an interval of (1/4) P. In addition, the width dimension of the light-on part 6 and the light-off part 7 was set to (1/2) P.

  The light receiving signals A + and A− output from the light receiving elements 11 and 13 are input to the differential amplifier 16 via a current-voltage converter (not shown), and the light receiving signals B− output from the light receiving elements 12 and 14 B + is input to the differential amplifier 17 via a current-voltage converter (not shown). On the other hand, the light receiving signal I output from the light receiving element 15 is input to the amplifier 18 via a current-voltage converter (not shown). The differential amplifiers 16 and 17, the amplifier 18, and the current-voltage conversion unit constitute an output unit.

  The differential amplifier 16 amplifies the difference between the light reception signals A + and A− and outputs an incremental channel signal A, and the differential amplifier 17 amplifies the difference between the light reception signals B + and B− and increments the incremental channel signal B. Is output. On the other hand, the amplifier 18 amplifies the received light signal I and outputs an index channel signal ID.

  A light receiving signal A + waveform W1 output from the light receiving element 11 when the light-on unit 6 passes a position corresponding to the light receiving element 11 and a light receiving element when the light-on unit 6 passes a position corresponding to the light receiving element 15 FIG. 1 schematically shows the waveform W2 of the received light signal I output by the reference numeral 15. The waveforms W1 and W2 are out of phase by 60 °. Further, the waveform W3 of the light reception signal A + output from the light receiving element 11 when the index pattern portion 10 passes through the position corresponding to the light receiving element 11, and the time when the index pattern portion 10 passes through the position corresponding to the light receiving element 15. A waveform W4 of the light receiving signal I output from the light receiving element 15 is schematically shown in FIG. The waveforms W3 and W4 are out of phase by 60 °.

  Therefore, according to this embodiment, the phase of the incremental channel signal A representing the movement information of the moving body 1 and the index channel signal ID representing the reference position information of the moving body 1 are shifted. Although the waveform diagram is not shown, the incremental channel signal B and the index channel signal ID are also out of phase.

  Therefore, according to this embodiment, even when the signal processing circuit of the output unit is configured by the same chip, mutual interference between the index channel signal ID and the incremental channel signals A and B can be suppressed. Accordingly, the phase shift and distortion of the incremental channel signal can be suppressed, and malfunctions such as chattering and logic inversion can be avoided, and movement information and reference position information can be obtained with low cost and high accuracy.

(Comparative Example 1)
Next, with reference to FIG. 9, the comparative example 1 of the said 1st Embodiment is demonstrated. This comparative example 1 differs from the first embodiment only in that a light receiving unit 102 is provided instead of the light receiving unit 2 of the first embodiment. In the light receiving unit 102 of Comparative Example 1, the width dimension of each of the light receiving elements 111 to 115 is (1/4) P. The interval between the light receiving elements is set to zero. For this reason, in the first comparative example, the waveform W101 of the light receiving signal A + output from the light receiving element 111 when the light ON section 6 passes through the position corresponding to the light receiving element 111, and the light ON section 6 corresponds to the light receiving element 115. The phase coincides with the waveform W102 of the light receiving signal I output from the light receiving element 115 when passing through the position. In addition, when the index pattern portion 10 passes through a position corresponding to the light receiving element 111, the waveform W103 of the light reception signal A + output from the light receiving element 111 and when the index pattern portion 10 passes through a position corresponding to the light receiving element 115. The phase of the waveform W104 of the light receiving signal I output from the light receiving element 115 is the same.

  Therefore, in the first comparative example, mutual interference between the index channel signal ID and the incremental channel signals A and B is likely to occur. Therefore, phase shift and distortion of the incremental channel signal are likely to occur, and malfunctions such as chattering and logic inversion are likely to occur.

(Second embodiment)
Next, FIG. 2 shows a second embodiment of the optical encoder of the present invention. The second embodiment includes a moving body 21, a light receiving unit 22, and a light emitting unit 23. The moving body 21 can move in the direction indicated by the arrow X1 or X2, and the light-on unit 26 and the light-off unit 27 are alternately arranged in the moving direction. The moving body 21 has an index pattern portion 30 sandwiched between the light off portion 27 and the light off portion 28 from both sides in the moving direction. The light off section 28 has a shorter moving direction dimension (width dimension) than the light off section 27. The light-on unit 26 and the index pattern unit 30 allow the light from the light emitting element 23 to pass to the light receiving unit 22 side. On the other hand, the light off unit 28 does not allow the light from the light emitting element 23 to pass to the light receiving unit 22 side.

  The light receiving unit 22 includes first, second, and third light receiving element groups 31, 32, and 33. The first light receiving element group 31 includes four light receiving elements 31-1, 31-2, 31-3, and 31-4. When the arrangement pitch of the light-on portions 26 of the moving body 21 is P, each of the light receiving elements 31-1 to 31-4 has a width dimension of (1/6) P. The light receiving elements 31-1 to 31-4 are arranged in the moving direction with an interval of (1/12) P. That is, the light receiving elements 31-1 to 31-4 are arranged at an arrangement pitch of (1/12) P. In addition, the second light receiving element group 32 includes four light receiving elements 32-1, 32-2, 32-3, and 32-4. Each of the light receiving elements 32-1 to 32-4 has a width dimension of (1/6) P. The light receiving elements 32-1 to 32-4 are arranged in the moving direction with an interval of (1/12) P.

  The light receiving element 31-4 of the first light receiving element group 31 and the light receiving element 32-1 of the second light receiving element group 32 are spaced apart by (1/4) P.

  The third light receiving element group 33 is composed of four light receiving elements 33-1, 33-2, 33-3, 33-4. Each of the light receiving elements 33-1 to 33-4 has a width dimension of (1/6) P. The light receiving elements 33-1 to 33-4 are arranged in the moving direction with an interval of (1/12) P. The light receiving element 32-4 of the second light receiving element group 32 and the light receiving element 33-1 of the third light receiving element group 33 are spaced apart by (1/4) P.

  The second embodiment has an output section composed of a first differential amplifier 34, a second differential amplifier 35, and an AND circuit 36. The three light receiving signals A + having different phases output from the light receiving elements 31-1, 32-1, 33-1 are electrically added via the current distributors 81, 85, 89, and the current-voltage conversion unit (see FIG. (Not shown) to the positive phase input terminal of the first differential amplifier 34. Further, the three light receiving signals A− having different phases output from the light receiving elements 31-3, 32-3, and 33-3 are electrically added via the current distributors 83, 87, and 91 to be converted into a current voltage. This is input to the negative phase input terminal of the first differential amplifier 34 via a unit (not shown).

  Further, the three light receiving signals B + having different phases output from the light receiving elements 31-4, 32-4, and 33-4 are electrically added via the current distributors 84, 88, and 92, and the current-voltage conversion unit. The signal is input to the positive phase input terminal of the second differential amplifier 35 via (not shown). Further, the three light receiving signals B− having different phases output from the light receiving elements 31-2, 32-2, and 33-2 are electrically added via the current distributors 82, 86, and 90 to be converted into a current voltage. This is input to the negative phase input terminal of the second differential amplifier 35 via a unit (not shown). The current distributors 81 to 92 are constituted by, for example, current mirror circuits.

  The light receiving signal A + output from the light receiving element 31-1 and the light receiving signal A− output from the light receiving element 31-3 pass through the current distributors 81 and 83, and through the AD converter (not shown). , And input to the AND circuit 36. The logical product circuit 36 outputs, as an index channel signal ID, a result obtained by performing a logical product operation of signals obtained by AD converting the light reception signals A + and A−.

  Thus, when the index pattern portion 30 passes through the light receiving portion 22 and when the light on portion 26 and the light off portion 27 that are incremental patterns pass through the light receiving portion 22, the light on state and the light off state are different. The index channel signal ID is generated based on a logical value obtained by performing a logical operation on the outputs of a plurality of light receiving elements whose correlation changes.

  The first differential amplifier 34 amplifies a difference between a signal obtained by electrically adding three light receiving signals A + having different phases and a signal obtained by electrically adding three light receiving signals A− having different phases. Incremental channel signal A is output. The second differential amplifier 35 amplifies the difference between the signal obtained by electrically adding the three light receiving signals B + having different phases and the signal obtained by electrically adding the three light receiving signals B− having different phases. Incremental channel signal B is output.

  In FIG. 3, the phases output from the light receiving elements 31-1, 32-1 and 33-1 are different when the light-on unit 26 passes through positions corresponding to the light receiving elements 31-1, 32-1 and 33-1. The waveforms W11, W12, and W13 of the three light reception signals A + are schematically shown. A signal waveform W14 shown in FIG. 3 is a waveform of a signal obtained by electrically adding the received light signals A + of three waveforms W11, W12, and W13 having different phases. This signal waveform W14 corresponds to the signal waveform of the incremental channel signal A when the light-on unit 26 and the light-off unit 27 pass through the light receiving unit 22 and the index pattern unit 30 does not pass through the light receiving unit 22.

  FIG. 4 shows a waveform W21 of a light reception signal A + output from the light receiving element 31-1 when the index pattern section 30 passes a position corresponding to the light receiving element 31-1, and a light-on section 26 indicates the light receiving element 32-. Waveforms W22 and W23 of the light reception signal A + output by the light receiving elements 32-1 and 33-1 when passing the position corresponding to 1,33-1 are schematically shown. A signal waveform W24 shown in FIG. 4 is a waveform of a signal obtained by electrically adding the light reception signals A + of three waveforms W21, W22, and W23 having different phases. This signal waveform W24 corresponds to the signal waveform of the incremental channel signal A when the light-on unit 26, the light-off unit 27, and the index pattern unit 30 pass through the light receiving unit 22.

  FIG. 5 shows a signal waveform W24 of the added light reception signal A + when the index pattern section 30, the light on section 26, and the light off section 27 pass through the light receiving section 22, and the light on section 26 and the light off. A signal waveform W14 of the added light reception signal A + when the portion 27 passes through the light receiving portion 22 but the index pattern portion 30 does not pass through the light receiving portion 22 is shown.

(Comparative Example 2)
Next, with reference to FIG. 10, the comparative example 2 of the said 2nd Embodiment is demonstrated. The comparative example 2 is different from the second embodiment only in that the light receiving unit 202 is provided instead of the light receiving unit 22 of the second embodiment. The light receiving unit 202 of Comparative Example 2 includes first, second, and third light receiving element groups 231, 232, and 233. The first light receiving element group 231 includes four light receiving elements 231-1 to 231-4 having a width dimension of (1/4) P, and the second light receiving element group 232 has a width dimension of (1/4) P. The third light receiving element group 233 includes four light receiving elements 233-1 to 233-4 having a width dimension of (1/4) P. The light receiving elements are arranged in a line in the moving direction, and the interval between the light receiving elements is set to zero.

  In this comparative example 2, the three light receiving signals A + having different phases output from the light receiving elements 231-1, 232-1 and 233-1 are electrically added and passed through a current-voltage converter (not shown). It is input to the positive phase input terminal of the first differential amplifier 34. Further, the three light receiving signals A− having different phases output from the light receiving elements 231-3, 232-3, and 233-3 are electrically added, and the first light is transmitted through a current-voltage converter (not shown). It is input to the negative phase input terminal of the differential amplifier 34.

  Further, the three light receiving signals B− having different phases output from the light receiving elements 231-4, 232-4, and 233-4 are electrically added together, and the second light signal B− is output via a current-voltage converter (not shown). It is input to the negative phase input terminal of the differential amplifier 35. Further, the three light receiving signals B + having different phases output from the light receiving elements 231-2, 232-2, and 233-2 are electrically added, and the second difference is passed through a current-voltage conversion unit (not shown). It is input to the positive phase input terminal of the dynamic amplifier 35.

  The light reception signal A + output from the light receiving element 231-1 and the light reception signal A− output from the light receiving element 231-3 are input to the AND circuit 36 via an AD conversion unit (not shown). The logical product circuit 36 outputs, as an index channel signal ID, a result obtained by performing a logical product operation of signals obtained by AD converting the light reception signals A + and A−.

  In FIG. 11, in the second comparative example, when the light-on unit 26 passes through positions corresponding to the light receiving elements 231-1, 232-1, and 233-1, the light receiving elements 231-1, 232-1, and 233-1. Schematically show three waveforms W211, W212, and W213 of the light receiving signal A + that output the same phase. A signal waveform W214 shown in FIG. 11 is a waveform of a signal obtained by electrically adding the received light signals A + of three waveforms W211, W212, and W213 having the same phase.

  In FIG. 12, the waveform W221 of the light reception signal A + output from the light receiving element 231-1 when the index pattern unit 30 passes through the position corresponding to the light receiving element 231-1, and the light-on unit 26 includes the light receiving element 232-2. Waveforms W222 and W223 of the light receiving signal A + output from the light receiving elements 232-1 and 233-1 when passing through a position corresponding to 1,233-1 are schematically shown. A signal waveform W224 shown in FIG. 12 is a waveform of a signal obtained by electrically adding the light reception signals A + of the three waveforms W221, W222, and W223.

  FIG. 5 shows a signal waveform W224 of the added light reception signal A + when the index pattern unit 30, the light on unit 26, and the light off unit 27 pass through the light receiving unit 202, and the light on unit 26 and the light off. A signal waveform W214 of the added light reception signal A + when the unit 27 passes through the light receiving unit 202 but the index pattern unit 30 does not pass through the light receiving unit 202 is shown.

  In the second comparative example, a light reception signal A + having the same phase is added to generate an incremental channel signal A. Therefore, as shown in FIG. 5, the signal waveform W224 of the signal added when passing through the index pattern unit 30 is the signal waveform of the signal added when not passing through the index pattern unit 30 by the width of the index pattern unit 30. The base of the waveform has expanded from W214.

  On the other hand, in the second embodiment, since the light reception signal A + having different phases is added to generate the incremental channel signal A, the addition is performed when the index pattern unit 30 passes as shown in FIG. The signal waveform W24 of the obtained signal does not have a broadening of the waveform base from the signal waveform W14 of the signal added when the index pattern part 30 does not pass, and the distortion of the waveform from the signal waveform W14 is suppressed.

  Therefore, according to the second embodiment, an incremental channel signal with little phase shift and distortion can be obtained even if an index pattern portion exists.

(Third embodiment)
Next, a third embodiment of the optical encoder of the present invention will be described with reference to FIGS. 6A to 6C.

  The third embodiment includes a moving body 41, a light receiving unit 42, and a light emitting unit (not shown). The light emitting unit is composed of an LED or the like. The moving body 41 is movable in the direction indicated by the arrow X1 or X2, and the light-on part 46 and the light-off part 47 are alternately arranged in the movement direction. Further, the moving body 41 has an index pattern portion 50, and the index pattern portion 50 is sandwiched between index pattern side portions 44 and 49 from both sides in the moving direction. The index pattern side portions 44 and 49 do not allow the light from the light emitting portion to pass to the light receiving portion 42 side, while the index pattern portion 50 allows the light from the light emitting portion to pass to the light receiving portion 42 side. The light-on part 46 allows light from the light-emitting part to pass to the light-receiving part 42 side, while the light-off part 47 does not allow light from the light-emitting part to pass to the light-receiving part 42 side.

  Each of the index pattern portion 50 and the index pattern side portions 44 and 49 has a width dimension that is one third of the moving direction dimension (width dimension) of the light-off portion 47, that is, (1/6) P.

  The light receiving unit 42 includes first to third light receiving element groups 51 to 53. The first light receiving element group 51 includes twelve light receiving elements 51-1 to 51-12. If the arrangement pitch of the light-on portions 46 of the moving body 41 is P, each of the light receiving elements 51-1 to 51-12 has a width dimension of (1/18) P. The light receiving elements 51-1 to 51-12 are arranged in the moving direction with an interval of (1/36) P. The width dimension of the light-on part 46 and the light-off part 47 is (1/2) P.

  The second light receiving element group 52 includes twelve (1/18) P width light receiving elements 52-1 to 52-12. The light receiving elements 52-1 to 52-12 are arranged in the moving direction with an interval of (1/36) P. The third light receiving element group 53 includes twelve (1/18) P light receiving elements 53-1 to 53-12. The light receiving elements 53-1 to 53-12 are arranged in the moving direction with an interval of (1/36) P.

  The light receiving element 51-12 of the first light receiving element group 51 and the light receiving element 52-1 of the second light receiving element group 52 are spaced apart by (1/12) P. In addition, the light receiving element 52-12 of the second light receiving element group 52 and the light receiving element 53-1 of the third light receiving element group 53 are spaced apart by (1/12) P.

  This third embodiment has an output section composed of a first differential amplifier 54 and a second differential amplifier 55 shown in FIG. 6B, and inverters 56 and 57 and an AND circuit 58 shown in FIG. 6C. .

  The nine light receiving elements with different phases output from the light receiving elements 51-1, 51-3, 51-5, the light receiving elements 52-1, 52-3, 52-5, and the light receiving elements 53-1, 53-3, 53-5. The signal A + is electrically added and input to the positive phase input terminal of the first differential amplifier 54 shown in FIG. 6B via a current-voltage converter (not shown). In addition, the light output elements 51-7, 51-9, 51-11, the light receiving elements 52-7, 52-9, 52-11, the light receiving elements 53-7, 53-9, 53-11 output different phases 9 The two light reception signals A− are electrically added and input to the reverse phase input terminal of the first differential amplifier 54 via a current-voltage converter (not shown). The output signal of the first differential amplifier 54 is an incremental channel signal A.

  In addition, light receiving elements 51-2, 51-10, 51-12, light receiving elements 52-2, 52-10, 52-12, light receiving elements are connected to the positive phase input terminal of the second differential amplifier 55 shown in FIG. 6B. Nine light receiving signals B + having different phases output from the elements 53-2, 53-10, 53-12 are electrically added, and the second differential amplifier 55 is passed through a current-voltage converter (not shown). Is input to the positive phase input terminal. The light receiving elements 51-4, 51-6, 51-8, the light receiving elements 52-4, 52-6, 52-8, and the light receiving elements 53-4, 53-6, 53-8 have different phases. The two light reception signals B− are electrically added and input to the reverse phase input terminal of the second differential amplifier 55 via a current-voltage converter (not shown). The output signal of the second differential amplifier 55 is an incremental channel signal B.

  As described above, the incremental channel signals A and B are generated from the light receiving signals having different phases output from the light receiving elements 51-1 to 53-12 whose width dimensions are subdivided. The phase shift of the incremental channel signal due to the inclusion of the index pattern part 50 between the light 46 and the light-off part 47 can be suppressed.

  The light receiving signal A− output from the light receiving element 51-7 is input to the AND circuit 58 via the AD converter (not shown) and the inverter 56 shown in FIG. 6C. The light receiving signal A− output from the light receiving element 51-11 is input to the AND circuit 58 via the AD converter (not shown) and the inverter 57 shown in FIG. 6C. The light reception signal A− output from the light receiving element 51-9 is input to the AND circuit 58 via an AD conversion unit (not shown).

  In the AND circuit 58, the light reception signal A− input to the AND circuit 58 without passing through the inverter among the three light reception signals A− whose phases are shifted by 60 ° is true, and the inverters 56, When the received light signal A− input to 57 is a false value, all three signals input to the AND circuit 58 are true values. Therefore, at this time, the output of the logical product circuit 58 becomes a true value, and the logical product circuit 58 indicates that the index pattern unit 50 has passed through the locations corresponding to the three light receiving elements 51-7, 51-9, 51-11. An index channel signal ID representing is output. On the other hand, when all three light receiving elements 51-7, 51-9, and 51-11 are located at positions corresponding to the light-on unit 46 or the light-off unit 47, the output of the AND circuit 58 becomes a false value, The index channel signal ID is not output.

  As described above, in the third embodiment, as shown in FIG. 6A, the light receiving unit 42 is composed of 36 light receiving elements 51-1 to 53-12 that are subdivided into (1/18) P width dimensions. Thus, even if the width (1/6) P of the index pattern unit 50 is small, the index channel signal ID can be obtained by the subdivided light receiving elements of the light receiving unit 42. In the third embodiment, the width of the index pattern unit 50 is smaller than the width of the light-on unit 46 and is one third of the width of the light-on unit 46. Therefore, the index channel signal ID can be generated correctly by avoiding the malfunction of the logic value calculation of the logic operation circuit caused by the light sneaking. The width dimension of the index pattern portion 50 may be a value less than (1/6) P, and conversely may be a value greater than (1/6) P.

  In the third embodiment, the index pattern portion 50 is located between the index pattern side portions 44 and 49 having the same width of (1/6) P width. The wraparound of light to the light receiving element facing the side portions 44 and 49 is equalized to the index pattern side portions 44 and 49. Therefore, it becomes possible to efficiently suppress the wraparound of light.

  In the third embodiment, the reciprocal (1/6) of the number 6 obtained by multiplying the number of the light receiving elements corresponding to one light-on unit 46 by 1 which is a natural number multiple, The product (1/6) P of the light-on portion 46 with the arrangement pitch P was taken as the dimension of the index pattern portion 50 in the moving direction. Therefore, the width dimension of one light receiving element is (1/18) P with respect to the width dimension (1/6) P of the index pattern part 50, and the light receiving element facing the index pattern part 50 and the index pattern An index channel signal can be generated relatively easily by a logical operation using signals obtained from the light receiving elements facing the side portions 44 and 49.

  In the third embodiment, the light receiving unit 42 outputs four movement information signals A +, A−, B +, and B−, is disposed corresponding to the three light-on units 46, and the movement information signal Although only 36 light receiving elements, which is the product of the number 4 of A +, A-, B +, B- and the square of the number 3 of the light-on portions 46, are provided, the movement information signals A +, A-, B +, B- (4 × 3n) light receiving elements may be provided which is a product of the number 4 of the light-on portions 46 and the number 3 of the light-on portions 46 to the nth power (n is a natural number). In the third embodiment, the number of light receiving elements corresponding to one light-on portion 46 is six, but the number may be a plurality other than six. Further, the reciprocal (1 / 6n) of the number 6n obtained by multiplying the number of the light receiving elements corresponding to the one light-on portion 46 by a natural number n times (n = 2, 3, 4,...) The product (1 / 6n) P with the array pitch P of the light-on portions 46 may be the dimension of the index pattern portion 50 in the moving direction.

(Fourth embodiment)
Next, a fourth embodiment of the optical encoder of the present invention will be described with reference to FIG. The fourth embodiment is configured by a differential amplifier 61 shown in FIG. 7 in place of the output part constituted by the inverters 56 and 57 and the AND circuit 58 shown in FIG. 6C of the third embodiment described above. The difference from the third embodiment described above is that the output unit is provided. Therefore, in the fourth embodiment, the same parts as those in the third embodiment are denoted by the same reference numerals as those in the third embodiment, and differences from the third embodiment will be mainly described.

  In the fourth embodiment, six light receiving signals A−, B−, output from six light receiving elements 51-7 to 51-12 in the first light receiving element group 51 included in the light receiving unit 42 shown in FIG. 6A. A first addition signal S1 obtained by electrically adding A−, B +, A−, and B + is a positive-phase input terminal of the differential amplifier 61 shown in FIG. 7 via a current-voltage converter (not shown). Is input. On the other hand, six light receiving signals B−, A−, B−, A−, B +, A output from six light receiving elements 53-6 to 53-11 in the third light receiving element group 53 of the light receiving unit 42 are provided. A second addition signal S2 obtained by electrically adding − is input to the negative-phase input terminal of the differential amplifier 61 shown in FIG. 7 via a current-voltage converter (not shown).

  Thereby, in this 4th Embodiment, the index pattern part 50 and the index pattern side parts 44 and 49 of the moving body 41 respond | correspond to the six light receiving elements 51-7-51-12 of the 1st light receiving element groups 51. The light-off unit 47 of the moving body 41 is in a position corresponding to the six light receiving elements 53-6 to 53-11 in the third light receiving element group 53.

  Therefore, the differential amplifier 61 includes six light receiving signals A−, B−, A−, output from the six light receiving elements 51-7 to 51-12 corresponding to the index pattern portion 50 and the index pattern side portions 44, 49. The first addition signal S1 obtained by adding B +, A−, B + and the six light receiving signals B−, A−, B− output from the six light receiving elements 53-6 to 53-11 corresponding to the light-off unit 47. , A−, B +, and A− are compared and calculated, and an index channel signal ID is output as a result of the comparison and calculation. This differential amplifier 61 eliminates common-mode noise and suppresses malfunctions. Further, since the first and second addition signals S1 and S2 are obtained by adding the light reception signals of the six light receiving elements, the light receiving area is wide and the SN of the signals S1 and S2 can be improved. In the fourth embodiment, similarly to the third embodiment described above, it is possible to avoid the malfunction caused by the wraparound of the light from the index pattern unit 50 and to correctly generate the index channel signal ID.

  Note that both the six light receiving elements 51-7 to 51-12 of the first light receiving element group 51 and the six light receiving elements 53-6 to 53-11 of the third light receiving element group 53 are turned off. Since the first addition signal S1 and the second addition signal S2 are the same signal when located at the position corresponding to the unit 47 or the light-on unit 46, potential fluctuation does not occur even if it is input to the differential amplifier. The differential amplifier 61 does not output an index channel signal. In order to suppress malfunction, it is desirable that the index channel signal has a hysteresis characteristic.

(Fifth embodiment)
Next, a fifth embodiment of the optical encoder of the present invention will be described with reference to FIG. The fifth embodiment is characterized in that the output unit includes first and second AND circuits 71 and 72 in addition to the differential amplifier 61 of the fourth embodiment. Different from the embodiment. Therefore, in the fifth embodiment, the same parts as those in the above-described fourth embodiment are denoted by the same reference numerals as those in the above-described fourth embodiment, and differences from the above-described fourth embodiment will be mainly described.

  In the fifth embodiment, the incremental channel signal A output from the first differential amplifier 54 shown in FIG. 6B and the incremental channel signal B output from the first differential amplifier 55 shown in FIG. 1 is input to the AND circuit 71. The first AND circuit 71 inputs a logical product obtained by taking the logical product of the incremental channel signal A and the incremental channel signal B to the second AND circuit 72. On the other hand, the differential amplifier 61 receives the same first and second addition signals S1 and S2 as those in the fourth embodiment, and the differential amplifier 61 is the same as that in the fourth embodiment. The index channel signal ID is input to the second AND circuit 72.

  The signal output from the second logical product circuit 72 is obtained by taking the logical product of the logical product of the incremental channel signals A and B having different 90 ° phases and the index channel signal ID. It becomes a new index channel signal synchronized with the incremental channel signal.

  In addition, in the electronic apparatus including the optical encoder according to any one of the first to fifth embodiments, the movement information (incremental channel signal) and the reference position information (index channel signal) can be accurately obtained at low cost. .

(Sixth embodiment)
Next, a sixth embodiment of the optical encoder of the present invention will be described with reference to FIGS. 13A, 13B, and 14. FIG.

  The sixth embodiment includes a moving body 121, a light receiving unit 122, and a light emitting unit (not shown). The light emitting unit is composed of an LED or the like. The moving body 121 can move in the direction indicated by the arrow X1 or X2, and has an incremental pattern portion 125 in which light-on portions 123 and light-off portions 124 are alternately arranged in the moving direction. The moving body 121 has an index pattern forming portion 126 that is adjacent to the incremental pattern portion 125 in a direction orthogonal to the moving direction of the moving body 121. The index pattern forming unit 126 has one index slit 126A as an index pattern unit. The index slit 126A allows the light from the light emitting unit to pass to the light receiving unit 122 side. The light-on unit 123 allows light from the light-emitting unit to pass to the light-receiving unit 122 side, while the light-off unit 124 does not allow light from the light-emitting unit to pass to the light-receiving unit 122 side.

  In addition, the index slit 126A of the index pattern forming unit 126 has a width dimension that is a half of the moving direction dimension (width dimension) (1/2) P of the light ON part 123 and the light OFF part 124, that is, (3/4). P.

  The light receiving unit 122 includes one light receiving element 139 sandwiched between the first to eighth light receiving element rows 131 to 138 and the light receiving element rows 134 and 135.

  The eight light receiving element rows and one light receiving element 139 are arranged to receive light from the incremental pattern portion 125 of the moving body 121. The light receiving element arrays 131 and 132 have four (1/4) P width light receiving elements 131-1 to 131-4 and 132-1 to 132-4. 1/4) It has four light receiving elements 133-1 to 133-4 and 134-1 to 134-4 having a P width. The light receiving element arrays 135 and 136 have four (1/4) P width light receiving elements 135-1 to 135-4 and 136-1 to 136-4, and the light receiving element arrays 137 and 138 are ( 1/4) It has four light receiving elements 137-1 to 137-4 and 138-1 to 138-4 having a P width. The light receiving element 139 has a width dimension of (3/4) P.

  Further, the light receiving unit 122 includes a light receiving element 140. The light receiving element 140 is adjacent to the light receiving element 139 and the light receiving element 135-1 at a distance in a direction orthogonal to the arrangement direction of the light receiving element rows 131 to 138. The light receiving elements 140 and 139 are index pulse detection photodiodes. The light receiving elements included in the light receiving element rows 131 to 138 include photodiodes, and the photodiodes are arranged in the moving direction.

  In the moving body 121 and the light receiving unit 122 shown in FIG. 13A, the light transmitted through the incremental pattern portion 125 of the moving body 121 is incident on the light receiving element rows 131 to 138 and the light receiving element 139 of the light receiving unit 122. The light transmitted through the index pattern forming section 126 is arranged so as to enter the light receiving element 140.

  This sixth embodiment has an output section composed of first, second and third differential amplifiers 101, 102 and 103 shown in FIG. 13B.

  The eight light receiving signals A + output from the light receiving elements 131-4, 132-4, 133-4, 134-4 and the light receiving elements 135-1, 136-1, 137-1, and 138-1 are electrically added. Then, it is input to the positive phase input terminal of the first differential amplifier 101 shown in FIG. 13B via a current-voltage converter (not shown). The eight light receiving signals A− output from the light receiving elements 131-2, 132-2, 133-2, 134-2 and the light receiving elements 135-3, 136-3, 137-3, and 138-3 are electrically And input to the negative phase input terminal of the first differential amplifier 101 shown in FIG. 13B via a current-voltage converter (not shown). The output signal of the first differential amplifier 101 is an incremental channel signal A.

  The eight light receiving signals B + output from the light receiving elements 131-3, 132-3, 133-3, 134-3 and the light receiving elements 135-4, 136-4, 137-4, 138-4 are electrically connected. The signals are added and input to the positive-phase input terminal of the second differential amplifier 102 shown in FIG. 13B via a current-voltage converter (not shown). The eight light receiving signals B− output from the light receiving elements 131-1, 132-1, 133-1, 134-1 and the light receiving elements 135-2, 136-2, 136-2, and 138-1 are electrically supplied. And input to the negative phase input terminal of the second differential amplifier 102 shown in FIG. 13B via a current-voltage converter (not shown). The output signal of the second differential amplifier 102 is an incremental channel signal B.

  The light receiving signal I + output from the light receiving element 139 is input to the positive phase input terminal of the third differential amplifier 103 shown in FIG. 13B via a current-voltage converter (not shown). Further, the light reception signal I− output from the light receiving element 100 is input to the negative phase input terminal of the third differential amplifier 103 shown in FIG. 13B via a current-voltage converter (not shown). The output signal of the third differential amplifier 103 becomes the index channel signal ID.

  According to the sixth embodiment, movement information of the moving body 121 is obtained by the incremental channel signals A and B output from the first and second differential amplifiers 101 and 102. Further, the reference position information of the moving body 121 can be obtained from the index channel signal ID output from the third differential amplifier 103.

  Further, according to the sixth embodiment, as shown in FIG. 14, a cross point P1 between the light reception signal A + and the light reception signal A−, a cross point P2 between the light reception signal B + and the light reception signal B−, The phase of the cross point P3 between the light reception signal I + and the light reception signal I− is different from each other. Therefore, the incremental channel signal A, the incremental channel signal B, and the index channel signal ID have different phases.

  Therefore, according to this embodiment, mutual interference between the index channel signal ID and the incremental channel signals A and B can be suppressed even when the signal processing circuit of the output unit is configured by the same chip. Accordingly, the phase shift and distortion of the incremental channel signal can be suppressed, and malfunctions such as chattering and logic inversion can be avoided, and movement information and reference position information can be obtained with low cost and high accuracy.

  Further, according to this embodiment, the third differential amplifier 103 takes the difference between the light receiving signal I + output from the light receiving element 139 and the light receiving signal I− output from the light receiving element 140 to obtain an index channel signal. ID is output. In this way, by taking the differential between the light reception signals I + and I−, it is possible to suppress malfunction such as signal inversion due to disturbance light or the like.

(Seventh embodiment)
Next, with reference to FIGS. 15 and 16, a seventh embodiment of the optical encoder of the invention will be described.

  The seventh embodiment includes a moving body 301, a light receiving unit 302, and a light emitting unit (not shown). The light emitting unit is composed of an LED or the like. The moving body 301 can move in the direction indicated by the arrow X1 or X2, and has an incremental pattern portion 305 in which light-on portions 303 and light-off portions 304 are alternately arranged in the moving direction.

  Further, the moving body 301 has an index pattern forming section 306 that is adjacent to the incremental pattern section 305 in a direction orthogonal to the moving direction of the moving body 301. The index pattern forming unit 306 has one index slit 306A as an index pattern unit. The index slit 306A allows the light from the light emitting unit to pass to the light receiving unit 302 side. The light-on unit 303 allows light from the light-emitting unit to pass to the light-receiving unit 302 side, while the light-off unit 304 does not allow light from the light-emitting unit to pass to the light-receiving unit 302 side.

  Further, the index slit 306A of the index pattern forming unit 306 has a width dimension (width dimension) (1/2) P that is twice the moving direction dimension (width dimension) of the light-on part 303 and the light-off part 304, that is, one pitch.

  The light receiving unit 302 includes first to eighth eight light receiving element arrays 331 to 338 and one light receiving element 339 sandwiched between the light receiving element arrays 334 and 335.

  The light receiving element 339 is 1 pitch wide. Further, the eight light receiving element arrays 331 to 338 and one light receiving element 339 are arranged so as to receive light from the incremental pattern portion 305 of the moving body 301. The light receiving element rows 331 and 332 include four (1/4) P width light receiving elements 331-1 to 331-4 and 332-1 to 332-4, and the light receiving element rows 333 and 334 are ( 1/4) It has four light receiving elements 333-1 to 333-4 and 334-1 to 334-4 of P width. The light receiving element rows 335, 336, and 337 include four (1/4) P width light receiving elements 335-1 to 335-4, 363-1 to 336-4, and 337-1 to 337-4. The light receiving element array 338 includes four (1/4) P width light receiving elements 338-1 to 338-4.

  Further, the light receiving unit 302 includes a light receiving element 340 having a 1 pitch width. The light receiving element 340 is adjacent to the light receiving element 339 at a predetermined interval in a direction orthogonal to the arrangement direction of the light receiving element rows 331 to 338. The light receiving elements 340 and 339 have a pitch width of 1 and are index pulse detection photodiodes. The light receiving elements included in each of the light receiving element rows 331 to 338 are formed of photodiodes, and the photodiodes are arranged in the moving direction.

  The seventh embodiment has an output section composed of first, second, and third differential amplifiers 101, 102, and 103 shown in FIG. 13B, as in the sixth embodiment.

  In the seventh embodiment, eight light receiving signals output from the light receiving elements 331-4, 332-4, 333-4, 334-4 and the light receiving elements 335-4, 336-4, 337-4, 338-4. A + is electrically added and input to the positive-phase input terminal of the first differential amplifier 101 shown in FIG. 13B via a current-voltage converter (not shown). The eight light receiving signals A− output from the light receiving elements 331-2, 332-2, 333-2, 334-2 and the light receiving elements 335-2, 336-2, 337-2, and 338-2 are electrically And input to the negative phase input terminal of the first differential amplifier 101 shown in FIG. 13B via a current-voltage converter (not shown). The output signal of the first differential amplifier 101 is an incremental channel signal A.

  In the seventh embodiment, the light receiving elements 331-3, 332-3, 333-3, 334-3 and the light receiving elements 335-3, 336-3, 337-3, 338-3 output eight signals. The light reception signal B + is electrically added and input to the positive phase input terminal of the second differential amplifier 102 shown in FIG. 13B via a current-voltage converter (not shown). The eight light receiving signals B− output from the light receiving elements 331-1, 332-1, 333-1, 334-1 and the light receiving elements 335-1, 336-1, 337-1, 338-1 are electrically supplied. And input to the negative phase input terminal of the second differential amplifier 102 shown in FIG. 13B via a current-voltage converter (not shown). The output signal of the second differential amplifier 102 is an incremental channel signal B.

  In the seventh embodiment, the light receiving signal I + output from the light receiving element 339 is supplied to the positive phase input terminal of the third differential amplifier 103 shown in FIG. 13B via a current-voltage converter (not shown). Entered. The light receiving signal I− output from the light receiving element 340 is input to the negative phase input terminal of the third differential amplifier 103 shown in FIG. 13B via a current-voltage converter (not shown). The output signal of the third differential amplifier 103 becomes the index channel signal ID.

  Further, according to the seventh embodiment, the movement information of the moving body 301 is obtained by the incremental channel signals A and B output from the first and second differential amplifiers 101 and 102. Further, the reference position information of the moving body 301 can be obtained from the index channel signal ID output from the third differential amplifier 103.

  Further, according to the seventh embodiment, as shown in FIG. 16, a cross point P11 between the light reception signal A + and the light reception signal A−, a cross point P12 between the light reception signal B + and the light reception signal B−, The phase of the cross point P13 between the light reception signal I + and the light reception signal I− is different from each other. Therefore, the incremental channel signal A, the incremental channel signal B, and the index channel signal ID have different phases.

  Therefore, according to this embodiment, mutual interference between the index channel signal ID and the incremental channel signals A and B can be suppressed even when the signal processing circuit of the output unit is configured by the same chip. Accordingly, the phase shift and distortion of the incremental channel signal can be suppressed, and malfunctions such as chattering and logic inversion can be avoided, and movement information and reference position information can be obtained with low cost and high accuracy.

  Further, according to the seventh embodiment, as shown in FIG. 16, the light reception signal I + of the light receiving element 340 which is an index pulse detection photodiode has a direct current waveform. Therefore, it is possible to suppress the period fluctuation of the index channel signal ID which is a differential output between the light reception signal I + and the light reception signal I−. Further, by setting the width of the light receiving element 340 (the dimension in the moving direction) and the width of the light receiving element 339 (the dimension in the moving direction) to the same pitch, the parasitic capacitances of the photodiodes constituting the light receiving elements 340 and 339 are uniform. And malfunction due to power supply noise or the like can be suppressed.

  According to the seventh embodiment, the light receiving elements corresponding to the same order of the light reception signals B−, A−, B +, and A + may be arranged in each of the eight light receiving element arrays 331 to 338. Therefore, it is not necessary to change the arrangement order of the light receiving elements corresponding to the respective light receiving signals B−, A−, B +, and A + in each light receiving element array, so that the alignment of the light receiving elements can be ensured.

(Eighth embodiment)
Next, with reference to FIG. 17A and FIG. 17B, 8th Embodiment of the optical encoder of this invention is described. The eighth embodiment corresponds to a modification of the above-described seventh embodiment. Since the eighth embodiment differs from the seventh embodiment only in that the light receiving unit 330 is provided instead of the light receiving unit 302 in the seventh embodiment, and the configuration of the output unit is different from the seventh embodiment described above. Differences from the form will be mainly described.

  The light receiving unit 330 provided in the eighth embodiment is sandwiched between first to eighth light receiving element rows 331 to 338 and light receiving element rows 334 and 335, which are the same as the light receiving unit 302 of the seventh embodiment. One light receiving element 339 is provided. On the other hand, the light receiving unit 330 includes a pair of light receiving elements 341 and 342 adjacent to both sides in the moving direction of the light receiving element 340 having the same pitch as the light receiving unit 302. Similar to the light receiving element 340, the light receiving elements 341 and 342 have a moving direction dimension of one pitch width. The light receiving element 340 forms a first index light receiving element, and the pair of light receiving elements 341 and 342 forms a second index light receiving element.

  In addition, the eighth embodiment has an output section constituted by first to fifth differential amplifiers 105, 106, 107, 108, 109 and a NOR circuit 110 shown in FIG. 13D.

  In the eighth embodiment, eight light receiving signals output from the light receiving elements 331-4, 332-4, 333-4, 334-4 and the light receiving elements 335-4, 336-4, 337-4, 338-4. A + is electrically added and input to the positive phase input terminal of the first differential amplifier 105 shown in FIG. 13D via a current-voltage converter (not shown). The eight light receiving signals A− output from the light receiving elements 331-2, 332-2, 333-2, 334-2 and the light receiving elements 335-2, 336-2, 337-2, and 338-2 are electrically And is input to the negative-phase input terminal of the first differential amplifier 105 shown in FIG. 13D via a current-voltage converter (not shown). The output signal of the first differential amplifier 105 is an incremental channel signal A. The signal waveform of this incremental channel signal A is shown in FIG. 17B.

  In the eighth embodiment, the light receiving elements 331-3, 332-3, 333-3, 334-3 and the light receiving elements 335-3, 336-3, 337-3, 338-3 output eight signals. The light reception signal B + is electrically added and input to the positive phase input terminal of the second differential amplifier 106 shown in FIG. 13D via a current-voltage converter (not shown). The eight light receiving signals B− output from the light receiving elements 331-1, 332-1, 333-1, 334-1 and the light receiving elements 335-1, 336-1, 337-1, 338-1 are electrically supplied. And input to the negative phase input terminal of the second differential amplifier 106 shown in FIG. 13D via a current-voltage converter (not shown). The output signal of the second differential amplifier 106 becomes the incremental channel signal B. The signal waveform of this incremental channel signal B is shown in FIG. 17B.

  In the eighth embodiment, the light receiving signal I + output from the light receiving element 339 is supplied to the positive phase input terminal of the third differential amplifier 107 shown in FIG. 13D via a current-voltage converter (not shown). Entered. This received light signal I + becomes a reference incremental channel signal.

  The light receiving signal I− output from the light receiving element 340 is input to the negative phase input terminal of the third differential amplifier 107 shown in FIG. 13D via a current-voltage converter (not shown). The output signal of the third differential amplifier 107 becomes the index channel signal ID. A signal waveform of the index channel signal ID is shown in FIG. 17B.

  In the eighth embodiment, the light receiving signal I1- output from the light receiving element 341 passes through a current-voltage converter (not shown), and the positive phase input terminal of the fourth differential amplifier 108 shown in FIG. 13D. Is input. Further, the light receiving signal I + output from the light receiving element 339 is input to the negative phase input terminal of the fourth differential amplifier 108 shown in FIG. 13D via a current-voltage converter (not shown). The output signal of the fourth differential amplifier 108 becomes the first secondary index channel signal I1D. The signal waveform of the first secondary index channel signal I1D is shown in FIG. 17B.

  In the eighth embodiment, the light reception signal I2- output from the light receiving element 342 is supplied to the positive phase input terminal of the fifth differential amplifier 109 shown in FIG. 13D via a current-voltage converter (not shown). Is input. The light reception signal I + output from the light receiving element 339 is input to the negative phase input terminal of the fifth differential amplifier 109 shown in FIG. 13D via a current-voltage conversion unit (not shown). The output signal of the fifth differential amplifier 109 becomes the second secondary index channel signal I2D. The signal waveform of the second secondary index channel signal I2D is shown in FIG. 17B.

  In the eighth embodiment, the incremental channel signals A and B, the index channel signal ID, and the first and second sub index channel signals I1D and I2D output from the first to fifth differential amplifiers 105 to 109 are output. Are input to the NOR circuit 110. The NOR circuit 110 performs a logical operation on the negative OR of the five signals A, B, ID, I1D, and I2D and outputs an index channel signal Ir after the logical operation. As shown in the signal waveform diagram of FIG. 17B, the index channel signal Ir after this logical operation is at the H level only when the five signals A, B, ID, I1D, and I2D are all at the L level. When at least one of the five signals A, B, ID, I1D, and I2D is at H level, it is at L level.

  In the output section of the eighth embodiment, the NOR outputs of the three signals A, B, ID and the first and second sub index channel signals I1D, I2D are used as the index channel signal Ir. As a result, when light wraparound is large at the time of light reception by the light receiving element 339 or when the light amount is biased toward the index slit 306A, the level of the light reception signal I + shown in FIG. It is possible to suppress a malfunction such that a plurality of index pulses of the index channel signal Ir after the spreading logic operation are output.

  Further, according to the eighth embodiment, as shown in FIG. 17B, the cross point P21 between the light reception signal A + and the light reception signal A−, the cross point P22 between the light reception signal B + and the light reception signal B−, The phase of the cross point P23 between the light reception signal I + and the light reception signal I− is different from each other. Therefore, the incremental channel signal A, the incremental channel signal B, and the index channel signal ID have different phases.

  Therefore, according to this embodiment, mutual interference between the index channel signal ID and the incremental channel signals A and B can be suppressed even when the signal processing circuit of the output unit is configured by the same chip. Accordingly, the phase shift and distortion of the incremental channel signal can be suppressed, and malfunctions such as chattering and logic inversion can be avoided, and movement information and reference position information can be obtained with low cost and high accuracy.

  In the eighth embodiment, the third differential amplifier 107 has hysteresis characteristics, and as shown in the waveform diagram of FIG. 17B, the falling edge of the index channel signal ID and the first sub-index channel signal I1D. , And the rising phase of the index channel signal ID is shifted from the rising phase of the second sub-index channel signal I2D. This avoids chattering when the output of the index channel signal ID, the first sub index channel signal I1D, and the second sub index channel signal I2D fluctuates.

(Ninth embodiment)
Next, a ninth embodiment of the optical encoder of the present invention will be described. The ninth embodiment corresponds to a modification of the above-described seventh embodiment. Since the ninth embodiment is different from the seventh embodiment only in the configuration of the output unit, the difference from the seventh embodiment will be mainly described.

  The output section included in the ninth embodiment includes a NOR circuit 104 shown in FIG. 13C and a circuit shown in FIG. 19 in addition to the three differential amplifiers 101, 102, and 103 shown in FIG. 13B. As shown in FIG. 13C, the NOR circuit 104 includes the incremental channel signals A and B output from the first and second differential amplifiers 101 and 102 in FIG. 13B and the index output from the third differential amplifier 103. The channel signal ID is input. The NOR circuit 104 performs a logical operation on the negative logical sum of the incremental channel signals A and B and the index channel signal ID, and outputs an index channel signal Ir after the logical operation. The index channel signal Ir after this logical operation becomes H level only when the incremental channel signals A and B and the index channel signal ID are L level, as shown in the signal waveform diagram of FIG. When at least one of A, B, and ID is at H level, it is at L level.

  Then, the index channel signal Ir output from the NOR circuit 104 and the incremental channel signal A are input to the differential amplifier 141 shown in FIG. The output signal of the differential amplifier 141 is input to the differential amplifier 142. A reference voltage source 143 and a feedback resistor 144 are connected to the differential amplifier 142. In this differential amplifier 142, as shown in the waveform diagram of FIG. 18, the incremental channel signal A appears on one side (first voltage range exceeding the reference voltage) of the reference voltage by the reference voltage source 143, A composite signal (A + Ir) in which the index channel signal Ir after the logical operation appears on one side (second voltage range below the reference voltage) is output. Therefore, according to the ninth embodiment, the number of output signals can be reduced without reducing the amount of information.

  Therefore, according to the ninth embodiment, it is possible to suppress an increase in mounting area as compared with the two-phase output that outputs the incremental channel signals A and B but does not output the index channel signal. Can share production facilities with other things.

  By the way, the incremental channel signals A and B are generally two-phase signals having a phase difference of 90 °, and the moving direction is detected by the order of the two-phase incremental channel signals A and B. Therefore, if the two-phase incremental channel signals A and B are output to one side and the other side with respect to the reference voltage, the direction of movement cannot be detected, or the direction of movement is detected by lowering the resolution. There is a demerit that it is necessary. On the other hand, when the index channel signal and the incremental channel signal are combined, the above disadvantages do not occur.

  In the ninth embodiment, the index channel signal Ir and the incremental channel signal A are combined. However, the index channel signal Ir and the incremental channel signal B may be combined. Further, the incremental channel signal A or B and the index channel signal ID in any of the first to fourth embodiments described above may be input to the differential amplifier 141 shown in FIG.

  Further, in an electronic device that uses the composite signal (A + Ir) output from the differential amplifier 142, the composite signal (A + Ir) is converted into the incremental channel signal A and the index channel signal Ir by including the circuit shown in FIG. Can be disassembled. As shown in FIG. 20, this circuit has differential amplifiers 151 and 152, a voltage source 153 is connected to the inverting input terminal of the differential amplifier 151, and the non-inverting input terminal of the differential amplifier 152 is connected. A voltage reduction 154 is connected. The composite signal (A + Ir) is input to the non-inverting input terminal of the differential amplifier 151 and the inverting input terminal of the differential amplifier 152. Here, the voltage source 153 outputs a voltage slightly larger than the reference voltage generated by the reference voltage source 143. This slight value is a value that prevents the influence of the offset of the incremental signal A. The voltage source 154 outputs a voltage slightly smaller than the reference voltage generated by the reference voltage source 143. This slight value is a value that prevents the influence of the offset of the index channel signal Ir. With the circuit shown in FIG. 20, the differential amplifier 151 outputs the incremental channel signal A as a 1.0 logic signal, and the differential amplifier 152 outputs the index channel signal Ir as a 1.0 logic signal.

  Further, in the electronic apparatus including the optical encoders of the first to ninth embodiments described above, the movement information (incremental channel signal) and the reference position information (index channel signal) can be obtained with low cost and high accuracy.

1 is a diagram schematically illustrating a first embodiment of an optical encoder according to the present invention. It is a figure which shows typically 2nd Embodiment of the optical encoder of this invention. In the said 2nd Embodiment, it is a wave form diagram explaining the addition process of the light reception signal A + at the time of an incremental pattern passage. In the said 2nd Embodiment, it is a wave form diagram explaining the addition process of the light reception signal A + at the time of an index pattern passage. In the said 2nd Embodiment and the comparative example 2, it is a wave form diagram which shows the waveforms W24 and W224 after the addition process of the light reception signal A + at the time of index pattern passage and the waveform W14, W214 after the addition process of the light reception signal A + at the time of passage of the incremental pattern is there. It is a figure which shows typically 3rd Embodiment of the optical encoder of this invention. It is a figure which shows the 1st, 2nd differential amplifiers 54 and 55 which the output part of the said 3rd Embodiment has. It is a figure which shows the inverters 56 and 57 and the AND circuit 58 which the output part of the said 3rd Embodiment has. It is a figure which shows the differential amplifier as an output part with which 4th Embodiment of the optical encoder of this invention is provided. It is a figure which shows the structure of the output part with which 5th Embodiment of the optical encoder of this invention is provided. It is a figure which shows typically the comparative example 1 of the said 1st Embodiment. It is a figure which shows typically the comparative example 2 of the said 2nd Embodiment. In the said comparative example 2, it is a wave form diagram explaining the addition process of the light reception signal A + at the time of an incremental pattern passage. In the said comparative example 2, it is a wave form diagram explaining the addition process of the light reception signal A + at the time of index pattern passage. It is a figure which shows typically the optical encoder of 6th Embodiment of this invention. It is a figure which shows the structure of the output part with which the said 6th Embodiment is provided. It is a figure which shows the NOR circuit which the output part of 8th Embodiment of this invention has. It is a figure which shows the structure of the output part of the optical encoder of 8th Embodiment of this invention. It is a wave form diagram which shows the output signal waveform of the said 6th Embodiment. It is a figure which shows typically the optical encoder of 7th Embodiment of this invention. It is a wave form diagram which shows the output signal waveform of the said 7th Embodiment. It is a figure which shows typically the optical encoder of 8th Embodiment of this invention. It is a wave form diagram which shows each signal waveform in the said 8th Embodiment. It is a wave form diagram which shows the output signal waveform of the optical encoder of 9th Embodiment of this invention. It is a figure which shows the circuit which the output part of the said 9th Embodiment has. It is a figure which shows the circuit which an electronic device provided with the optical encoder of the said 9th Embodiment has.

Explanation of symbols

1, 2, 41, 121, 301 Moving object 2, 22, 42, 122, 302 Light receiving part 3, 23 Light emitting part 6, 26, 46, 123, 303 Light on part 7, 8, 27, 47, 124, 304 Light OFF part 10, 30, 50 Index pattern part 11-15 Light receiving element 31-1 to 31-4, 32-1 to 32-4, 33-1 to 33-4 Light receiving element 51-1 to 51-12,52 -1 to 52-12 Light receiving element 53-1 to 53-12 Light receiving element 131 to 138, 331 to 338 Light receiving element array 139, 140, 339, 340 Light receiving element 16, 17, 34, 35, 54, 55, 61 Difference Dynamic amplifier 101-103, 105-109, 141, 142, 151, 152 Differential amplifier 18 Amplifier 36, 58, 71, 72 AND circuit 44, 49 Index pattern side part 81-92 Current divider 12 , 305 incremental pattern portion 126,306 index pattern forming portion 126A, 306A index slit

Claims (15)

A light-receiving unit, and a light-receiving unit having a plurality of light-receiving elements arranged in one direction in a region where light from the light-emitting unit can reach, and when passing a predetermined position corresponding to the light-receiving element A light-on portion that causes the light to enter the light-receiving element; and a light-off portion that prevents the light from entering the light-receiving element when passing through a predetermined position corresponding to the light-receiving element. A photoelectric encoder that detects the movement of the moving body in which the light-on part and the light-off part alternately pass through the predetermined position when moving in a direction,
The moving body includes an index pattern portion arranged at a predetermined reference position,
Furthermore, the light on part and the light off part of the moving body pass through a predetermined position corresponding to the light receiving element, and the first light receiving signal output from the light receiving element and the index pattern part of the moving body are An output unit for inputting a second light receiving signal output from the light receiving element by passing through a predetermined position corresponding to the light receiving element;
The output section
Based on at least the first light reception signal of the first and second light reception signals, an incremental channel signal representing movement information of the moving body is output, and among the first and second light reception signals, An optical system that outputs an index channel signal representing the reference position of the moving body based on at least the second received light signal, and that the incremental channel signal and the index channel signal are out of phase. Encoder. The optical encoder according to claim 1,
The output section
An optical encoder characterized in that the incremental channel signal is output by electrically adding received light signals having different phases output by a plurality of light receiving elements. The optical encoder according to claim 1 or 2,
The output section
A logical operation unit that receives a light reception signal output from the first and second light reception elements of the plurality of light reception elements and outputs a result of logical operation of both light reception signals as an index channel signal;
The light incident state of the first and second light receiving elements when the index pattern portion passes through a predetermined position corresponding to at least one of the first light receiving element and the second light receiving element. Combination of light non-incident state and light incident state of the first and second light receiving elements when the light on part or light off part passes through a predetermined position corresponding to the first and second light receiving elements. And an optical encoder in which the combination of the light non-incident states is different. The optical encoder according to claim 1,
The light receiving unit outputs a plurality of independent movement information signals based on the light reception signals of the light receiving elements and is arranged corresponding to a predetermined number of light-on units, and the number of independent movement information signals and the number of the movement information signals An optical encoder comprising the number of the light receiving elements represented by a product of a power of the number of corresponding light-on portions. In the optical encoder according to any one of claims 1 to 4,
The optical encoder characterized in that the dimension of the index pattern portion of the moving body in the movement direction is shorter than the dimension of the light-on portion in the movement direction and the dimension of the light-off portion in the movement direction. The optical encoder according to claim 5, wherein
The moving body is
The index pattern side portions that are adjacent to both sides of the movement direction of the index pattern portion and that make the light not incident on the light receiving element when passing through a predetermined position corresponding to the light receiving element,
Two index pattern side portions adjacent to both sides of the movement direction of the index pattern portion are symmetric with respect to the index pattern portion,
The optical encoder, wherein the index pattern portion makes the light incident on the light receiving element when passing through a predetermined position corresponding to the light receiving element. The optical encoder according to claim 6, wherein
The product of the reciprocal of the natural number times the number of the light receiving elements corresponding to one light-on part at a predetermined position and the arrangement pitch of the light-on parts is the dimension of the index pattern part in the moving direction. An optical encoder characterized by that. The optical encoder according to claim 7, wherein
The light receiving part is
A first light receiving element group composed of a number of adjacent light receiving elements corresponding to one light-off portion of the moving body, and the same number of adjacent light receiving elements as the first light receiving element group, and the above And a second light receiving element group at a position corresponding to the light-off portion of the moving body when the index pattern part of the moving body and the index pattern side part are at a position corresponding to the first light receiving element group. ,
Further, when the light-off part of the moving body is at a position corresponding to the first light receiving element group, another light off part or the index pattern part of the moving body corresponds to the second light receiving element group. In position
The output section
A first addition signal obtained by adding a plurality of light receiving signals output from the first light receiving element group and a second addition signal obtained by adding a plurality of light receiving signals output from the second light receiving element group are input. And a differential amplifier for comparing and calculating the first addition signal and the second addition signal. The optical encoder according to claim 8, wherein
A first AND circuit to which a plurality of incremental channel signals having different phases are input;
An optical encoder comprising: a second AND circuit to which an AND signal output from the first AND circuit and an output signal of the differential amplifier are input. The optical encoder according to claim 1 or 2,
The index pattern part is
An optical encoder characterized by being adjacent to an incremental pattern portion formed by the light-on portion and the light-off portion in a direction orthogonal to the moving direction of the moving body. The optical encoder according to claim 10, wherein
The movement direction dimension of one pattern and the movement direction dimension of the index pattern part by the pair of adjacent light on part and light off part are the same,
The light receiving unit is
An optical encoder comprising: a light receiving element on which light from the index pattern portion is incident and whose moving direction size is the same as the moving direction size of the index pattern portion. The optical encoder according to claim 10, wherein
The light receiving part is
A first index light receiving element on which light from the index pattern portion is incident;
A second index light receiving element adjacent to the first index light receiving element in the moving direction and having the same moving direction dimension as the moving direction dimension of the first index light receiving element;
The output section
The first light receiving signal output from the first index light receiving element is larger than the reference incremental channel signal, and the second light receiving signal output from the second index light receiving element is the reference incremental channel signal. An optical encoder characterized in that the index channel signal is output only when it is smaller than the above. The optical encoder according to any one of claims 1 to 11,
The output section
The incremental channel signal and the index channel signal are combined, and the incremental channel signal is present in one voltage range of a first voltage range above a reference voltage and a second voltage range below the reference voltage. An optical encoder characterized in that the index channel signal outputs a composite signal existing in the other voltage range of the two voltage ranges. An optical encoder according to claim 13,
A first differential operation unit for performing a differential operation on the combined signal from the output unit with a first voltage shifted from the reference voltage to the one voltage range and outputting an incremental channel signal;
A second differential operation unit that differentially calculates the composite signal from the output unit with a second voltage shifted from the reference voltage to the other voltage range and outputs an index channel signal. And electronic equipment.   An electronic apparatus comprising the optical encoder according to any one of claims 1 to 13.

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