JP2008298660A - Signal processing circuit for encoder - Google Patents

Signal processing circuit for encoder Download PDF

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JP2008298660A
JP2008298660A JP2007146419A JP2007146419A JP2008298660A JP 2008298660 A JP2008298660 A JP 2008298660A JP 2007146419 A JP2007146419 A JP 2007146419A JP 2007146419 A JP2007146419 A JP 2007146419A JP 2008298660 A JP2008298660 A JP 2008298660A
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JP4780038B2 (en
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Taro Kishibe
太郎 岸部
Takahiro Masuda
隆宏 増田
Hirozo Tagami
博三 田上
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Panasonic Corp
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal processing circuit for an encoder attaining accurate conversion from a sinusoidal wave signal into angle data, using easy arithmetic processings and which is high in position detection accuracy. <P>SOLUTION: A position data converting means 9 comprises a phase error detector 7 for generating a phase error signal; a conversion signal generating means 8 for generating a conversion auxiliary signal B2D signal and a conversion auxiliary signal A2D signal from the phase error signal; a signal-shaping means 6 for shaping waveform of a B2 signal into a 0-π radian region to generate a B3 signal and shaping waveform of an A2 signal into a -π/2 to π/2-radian region, to generate an A3 signal; and a data converting means 10 for carrying out inverse trigonometric function conversion of the A2 signal and B3 signal to carry out conversion from the A2 signal, B2 signal, A2D signal and B2D signal into angle data of 0-2π. The A2 signal is converted into angle data, by using the conversion auxiliary signal B2D signal, and the B2 signal is converted into angle data, by using the conversion auxiliary signal A2D signal. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

本発明は、直交する2相(A相とB相)の正弦波信号を内挿処理して高分解能を得るエンコーダにおいて、2相の正弦波信号から角度データに変換するエンコーダの信号処理回路に関するものである。   The present invention relates to an encoder signal processing circuit that converts two-phase sine wave signals into angle data in an encoder that obtains high resolution by interpolating two orthogonal sine wave signals (A phase and B phase). Is.

回転型(またはリニア型)のエンコーダの位置検出は、一般的に発光素子と受光素子と、その間に格子状のスリットを形成した回転体(または移動体)から形成され、格子状のスリット間隔によって分解能が決定される。従って分解能を上げるために、スリット間隔を小さくすることが行われてきたが、加工精度や光の回折現象が原因でこの手法で分解能を上げるのには限界があった。   The position detection of a rotary (or linear) encoder is generally made up of a light emitting element, a light receiving element, and a rotating body (or moving body) with a grid-like slit formed between them. Resolution is determined. Therefore, in order to increase the resolution, the slit interval has been reduced, but there is a limit to increasing the resolution by this method due to the processing accuracy and the light diffraction phenomenon.

そこで近年では、回転体(または移動体)のスリット間の信号と同期した90度位相差のあるA,B相の正弦波のアナログ信号を生成し、そのアナログ信号を内挿処理した信号と上記のスリットによって得られる信号を合成して分解能を上げる方法が一般的に行われている。   Therefore, in recent years, analog signals of A and B phases having a phase difference of 90 degrees synchronized with the signal between the slits of the rotating body (or moving body) are generated, and the signal obtained by interpolating the analog signal and the above-described signal A method of increasing the resolution by synthesizing signals obtained by the slits is generally performed.

図9を用いて内挿処理の方法を説明する。まず、エンコーダから出力される原信号でアナログのA0信号とB0信号をAD変換器2でディジタル信号A1信号とB1信号に変換し、A1信号とB1信号のピーク値を検出することで、オフセットと振幅の補正を行ったA2信号とB2信号に変換する。次にこのA2信号とB2信号を角度データに変換するために、arcsin及びarccosの演算可能な180度刻みのA3信号とB3信号に変換する信号整形を行うが、このA2信号とB2信号の位相差が90度からずれていると図9及び図10のように変換が正しく行われずに生成した角度データA4D信号とB4D信号に誤差を生じてしまう。   A method of interpolation processing will be described with reference to FIG. First, the analog A0 signal and B0 signal are converted from the original signal output from the encoder into the digital signal A1 signal and the B1 signal by the AD converter 2, and the peak value of the A1 signal and the B1 signal is detected. It converts into A2 signal and B2 signal which performed amplitude correction. Next, in order to convert the A2 signal and the B2 signal into angle data, signal shaping is performed to convert the arcsin and arccos into 180 degree A3 signals and B3 signals which can be calculated. If the phase difference deviates from 90 degrees, the conversion is not performed correctly as shown in FIGS. 9 and 10, and an error occurs in the generated angle data A4D signal and B4D signal.

この課題に対し、2相の正弦波信号の位相誤差を補正するため、例えば、A相とB相のオフセットを除去した後に、各信号の和と差の演算を行うことでA相とB相の位相差を90度にする方法が提案されている(例えば、特許文献1参照)。   In order to correct the phase error of the two-phase sine wave signal for this problem, for example, after the offset of the A phase and the B phase is removed, the sum and difference of each signal are calculated to calculate the A phase and the B phase. Has been proposed (see, for example, Patent Document 1).

また、A相とB相の交点から位相誤差を求め、求めた位相誤差から補正値を演算し、arcsin及びarccosで求めたそれぞれの角度データに対して、位相誤差の補正値を加減算によって処理する方法が提案されている(例えば、特許文献2参照)。
特開2001−296142号公報 特開2003−121207号公報
Further, a phase error is obtained from the intersection of the A phase and the B phase, a correction value is calculated from the obtained phase error, and the correction value of the phase error is processed by addition / subtraction for each angle data obtained by arcsin and arccos. A method has been proposed (see, for example, Patent Document 2).
JP 2001-296142 A JP 2003-121207 A

しかしながら、特許文献1の方法では、位相補正後のA相とB相は振幅が互いに変化するという課題がある。また、原信号のA相とB相の最大値と最小値を求めてオフセットを補正し、位相補正後の信号の最大値と最小値を求めて振幅を合わせる必要があり、演算処理に時間を要するという課題があった。   However, the method of Patent Document 1 has a problem that the amplitudes of the A phase and the B phase after phase correction change from each other. In addition, it is necessary to find the maximum and minimum values of the A phase and B phase of the original signal, correct the offset, find the maximum and minimum values of the signal after phase correction, and match the amplitude. There was a problem that it took.

一方、特許文献2の方法では、A相とB相の信号をarcsin及びarccosによって角度データに変換した後に位相を補正しているため、位相がずれた状態で角度データに変換すると図9、図10及び図11に示すように角度データに誤差が生じてしまうという課題があった。   On the other hand, in the method of Patent Document 2, since the phase is corrected after the A-phase and B-phase signals are converted into angle data by arcsin and arccos, if the phase is shifted, the phase data is converted into angle data. As shown in FIGS. 10 and 11, there is a problem that an error occurs in the angle data.

本発明は上記従来の課題を解決するものであり、位相誤差が大きく経年変化や温度変化が生じても、容易な演算処理で位相誤差を補正でき、位置検出精度が高いエンコーダ信号の信号処理回路を提供することを目的とする。   The present invention solves the above-described conventional problems, and even if a phase error is large and a secular change or a temperature change occurs, the phase error can be corrected by an easy calculation process, and a signal processing circuit for an encoder signal with high position detection accuracy. The purpose is to provide.

上記課題を解決するために本発明は、直交するA相とB相の正弦波信号をディジタルデータに変換してA1信号とB1信号を生成するAD変換手段と、A1信号とB1信号のピーク値を検出するピーク検出器と、前記ピーク検出器で検出したピーク値を用いてオフセットおよび振幅の誤差を補正してA2信号とB2信号を生成するオフセット/振幅補正手段と、前記A2信号とB2信号を角度データA4D信号とB4D信号に変換する位置データ変換手段と、前記位置データ変換手段で求めた角度データA4D信号とB4D信号を合成して、内挿データを生成するデータ合成手段とを有した位置検出器において、前記位置データ変換手段は、前記A2信号とB2信号の交点値から位相誤差信号を生成する位相誤差検出器と、前記位相誤差信号から前記A2信号との位相差が90度である変換補助信号B2D信号を生成し、前記B2信号との位相差が90度である変換補助信号A2D信号を生成する変換信号生成手段と、前記A2D信号を基準として前記B2信号を0〜πラジアンの領域に波形整形してB3信号を生成し、前記B2D信号を基準として前記A2信号を−π/2〜π/2ラジアンの領域に波形整形してA3信号を生成する信号整形手段と、前記A3信号とB3信号を逆三角関数変換し、前記A2信号とB2信号と前記A2D信号とB2D信号から0〜2πの角度データに変換するデータ変換手段とを備え、前記変換信号生成手段は、前記位相誤差信号から生成した補正係数を用いてA2信号とB2信号に乗算してA補正信号とB補正信号を生成し、さらに前記A2信号に前記B補正信号を加算してB2信号に対して位相が90度となる変換補助信号A2D信号を生成し、前記B2信号に前記A補正信号を加算してA2信号に対して位相が90度となる変換補助信号B2D信号を生成し、B2D信号を用いてA2信号を角度データに変換し、A2D信号を用いてB2信号を角度データに変換する。   In order to solve the above-mentioned problems, the present invention provides an AD conversion means for generating A1 and B1 signals by converting orthogonal A-phase and B-phase sine wave signals into digital data, and peak values of the A1 and B1 signals. A peak detector for detecting the offset, an offset / amplitude correction means for generating an A2 signal and a B2 signal by correcting an offset and amplitude error using the peak value detected by the peak detector, and the A2 signal and the B2 signal Position data converting means for converting angle data into A4D signals and B4D signals, and data synthesizing means for generating interpolation data by synthesizing the angle data A4D signals and B4D signals obtained by the position data converting means. In the position detector, the position data conversion means includes a phase error detector that generates a phase error signal from an intersection value of the A2 signal and the B2 signal, and the phase error signal. A conversion signal generating means for generating a conversion auxiliary signal B2D signal having a phase difference of 90 degrees with respect to the A2 signal, and generating a conversion auxiliary signal A2D signal having a phase difference of 90 degrees with respect to the B2 signal; Based on the signal, the B2 signal is shaped into a 0 to π radians region to generate a B3 signal, and the A2 signal is shaped into a -π / 2 to π / 2 radians region based on the B2D signal. Signal shaping means for generating the A3 signal, and data conversion means for performing inverse trigonometric function transformation on the A3 signal and the B3 signal and converting the A2 signal, the B2 signal, the A2D signal, and the B2D signal into angle data of 0 to 2π. And the conversion signal generation means multiplies the A2 signal and the B2 signal by using the correction coefficient generated from the phase error signal to generate an A correction signal and a B correction signal, and further converts the A2 signal to the previous A2 signal. The B correction signal is added to generate a conversion auxiliary signal A2D signal having a phase of 90 degrees with respect to the B2 signal, and the A correction signal is added to the B2 signal to have a phase of 90 degrees with respect to the A2 signal. A conversion auxiliary signal B2D signal is generated, the A2 signal is converted into angle data using the B2D signal, and the B2 signal is converted into angle data using the A2D signal.

また、前記データ合成手段は、B2D信号のゼロクロス点でのB2信号の位相ずれ量を検出し、A2D信号のゼロクロス点でのA2信号の位相ずれ量を検出し、位相ずれ量から角度誤差値を算出し、求めた角度誤差値をA相、またはB相の角度データから減算することで位相ずれを補正する。   Further, the data synthesizing means detects the phase shift amount of the B2 signal at the zero cross point of the B2D signal, detects the phase shift amount of the A2 signal at the zero cross point of the A2D signal, and calculates the angle error value from the phase shift amount. The phase shift is corrected by subtracting the calculated angle error value from the A phase or B phase angle data.

また、前記データ合成手段は、B2D信号のゼロクロス点でのB2信号の位相ずれ量を検出し、A2D信号のゼロクロス点でのA2信号の位相ずれ量を検出し、A相とB相の位相ずれ量の平均値から角度誤差値を算出し、求めた角度誤差値をA相、またはB相の角度データから減算することで位相ずれを補正する。   The data synthesizing means detects the phase shift amount of the B2 signal at the zero cross point of the B2D signal, detects the phase shift amount of the A2 signal at the zero cross point of the A2D signal, and detects the phase shift between the A phase and the B phase. An angle error value is calculated from the average value of the quantities, and the phase error is corrected by subtracting the obtained angle error value from the A-phase or B-phase angle data.

請求項1に記載のエンコーダ信号の信号処理回路によれば、A相とB相の位相に対し90度位相差の変換補助信号を生成して角度データを生成するため、経年変化や温度変化、製造上のばらつきによって位相誤差が生じた場合にも精度の高いエンコーダを得ることができる。   According to the signal processing circuit of the encoder signal according to claim 1, in order to generate angle data by generating a conversion auxiliary signal having a phase difference of 90 degrees with respect to the phases of the A phase and the B phase, Even when a phase error occurs due to manufacturing variations, a highly accurate encoder can be obtained.

また、請求項2に記載のエンコーダ信号の信号処理回路によれば、A2D信号とB2D信号の精度よく検出できるゼロクロス点でA2信号とB2信号の値から位相ずれ量を検出するため、検出値のダイナミックレンジが広いことから位相ずれの検出精度が高くなり、精度よく位相を補正することができる。   According to the signal processing circuit for the encoder signal according to claim 2, the phase shift amount is detected from the values of the A2 signal and the B2 signal at the zero cross point where the A2D signal and the B2D signal can be accurately detected. Since the dynamic range is wide, the phase shift detection accuracy is high, and the phase can be accurately corrected.

さらに、請求項3に記載のエンコーダ信号の信号処理回路によれば、A相とB相の位相
ずれ量の平均値から角度誤差を求めるため、ノイズに強い構成とすることができる。
Furthermore, according to the signal processing circuit of the encoder signal according to the third aspect, since the angle error is obtained from the average value of the phase shift amounts of the A phase and the B phase, it can be configured to be resistant to noise.

直交するA相とB相の正弦波信号をディジタルデータに変換してA1信号とB1信号を生成するAD変換手段と、A1信号とB1信号のピーク値を検出するピーク検出器と、前記ピーク検出器で検出したピーク値を用いてオフセットおよび振幅の誤差を補正してA2信号とB2信号を生成するオフセット/振幅補正手段と、前記A2信号とB2信号を角度データA4D信号とB4D信号に変換する位置データ変換手段と、前記位置データ変換手段で求めた角度データA4D信号とB4D信号を合成して、内挿データを生成するデータ合成手段とを有した位置検出器において、前記位置データ変換手段は、前記A2信号とB2信号の交点値から位相誤差信号を生成する位相誤差検出器と、前記位相誤差信号から前記A2信号との位相差が90度である変換補助信号B2D信号を生成し、前記B2信号との位相差が90度である変換補助信号A2D信号を生成する変換信号生成手段と、前記A2D信号を基準として前記B2信号を0〜πラジアンの領域に波形整形してB3信号を生成し、前記B2D信号を基準として前記A2信号を−π/2〜π/2ラジアンの領域に波形整形してA3信号を生成する信号整形手段と、前記A3信号とB3信号を逆三角関数変換し、前記A2信号とB2信号と前記A2D信号とB2D信号から0〜2πの角度データに変換するデータ変換手段とを備え、前記変換信号生成手段は、前記位相誤差信号から生成した補正係数を用いてA2信号とB2信号に乗算してA補正信号とB補正信号を生成し、さらに前記A2信号に前記B補正信号を加算してB2信号に対して位相が90度となる変換補助信号A2D信号を生成し、前記B2信号に前記A補正信号を加算してA2信号に対して位相が90度となる変換補助信号B2D信号を生成し、B2D信号を用いてA2信号を角度データに変換し、A2D信号を用いてB2信号を角度データに変換し、前記データ合成手段は、B2D信号のゼロクロス点でのB2信号の位相ずれ量を検出し、A2D信号のゼロクロス点でのA2信号の位相ずれ量を検出し、A相とB相の位相ずれ量の平均値から角度誤差値を算出し、求めた角度誤差値をA相、またはB相の角度データから減算することで位相ずれを補正する。以下、実施の形態について、図面を参照しながら説明する。
(実施の形態1)
本発明の実施の形態1によるエンコーダ信号の位相補正回路について、図1から図7を用いて説明する。図1は位相補正回路を含むエンコーダ信号処理回路のブロック図、図2から図5は位相回路ブロックの位相誤差検出回路の動作波形、図6と図7は位相補正回路の動作波形を示している。
A / D conversion means for generating A1 signal and B1 signal by converting orthogonal A-phase and B-phase sine wave signals into digital data, a peak detector for detecting peak values of A1 signal and B1 signal, and the peak detection Offset / amplitude correction means for generating an A2 signal and a B2 signal by correcting offset and amplitude errors using the peak value detected by the detector, and converting the A2 signal and the B2 signal into angle data A4D signal and B4D signal. In the position detector having position data converting means and data combining means for generating interpolation data by combining the angle data A4D signal and B4D signal obtained by the position data converting means, the position data converting means is A phase error detector that generates a phase error signal from the intersection value of the A2 signal and the B2 signal, and a phase difference between the phase error signal and the A2 signal is 90 degrees A conversion signal generating means for generating a conversion auxiliary signal B2D signal and generating a conversion auxiliary signal A2D signal having a phase difference of 90 degrees with respect to the B2 signal; and the B2 signal as 0 to π radians with the A2D signal as a reference A signal shaping means for generating a B3 signal by shaping the waveform into a region of A2 and generating an A3 signal by shaping the waveform of the A2 signal into a region of -π / 2 to π / 2 radians with reference to the B2D signal; Data conversion means for performing inverse trigonometric function conversion on the A3 signal and the B3 signal, and converting the A2 signal, the B2 signal, the A2D signal, and the B2D signal into angle data of 0 to 2π, and the conversion signal generation means includes: A correction signal generated from the phase error signal is used to multiply the A2 signal and the B2 signal to generate an A correction signal and a B correction signal. Further, the B correction signal is added to the A2 signal and the B2 signal is paired. Then, a conversion auxiliary signal A2D signal having a phase of 90 degrees is generated, and the A correction signal is added to the B2 signal to generate a conversion auxiliary signal B2D signal having a phase of 90 degrees with respect to the A2 signal, and B2D The A2 signal is converted into angle data using the signal, the B2 signal is converted into angle data using the A2D signal, and the data synthesizing means detects the phase shift amount of the B2 signal at the zero cross point of the B2D signal, The phase shift amount of the A2 signal at the zero cross point of the A2D signal is detected, the angle error value is calculated from the average value of the phase shift amounts of the A phase and the B phase, and the obtained angle error value is calculated for the A phase or the B phase. The phase shift is corrected by subtracting from the angle data. Hereinafter, embodiments will be described with reference to the drawings.
(Embodiment 1)
A phase correction circuit for an encoder signal according to the first embodiment of the present invention will be described with reference to FIGS. 1 is a block diagram of an encoder signal processing circuit including a phase correction circuit, FIGS. 2 to 5 are operation waveforms of a phase error detection circuit of the phase circuit block, and FIGS. 6 and 7 are operation waveforms of the phase correction circuit. .

図1において、エンコーダから出力される原信号でアナログのA0信号とB0信号は、90度位相差のあるA相とB相の正弦波信号である。一般的に発光素子と受光素子とスリット板から構成される。   In FIG. 1, analog A0 and B0 signals, which are original signals output from the encoder, are A-phase and B-phase sine wave signals having a phase difference of 90 degrees. Generally, it comprises a light emitting element, a light receiving element, and a slit plate.

発光素子として、LEDやレーザー光、受光素子として、フォトダイオードやフォトトランジスタが用いられる。スリット板は、光を透過するガラスや樹脂材でできており、スリット板上に光を遮断する格子状のマスクを設けている。発光素子からの光は、スリット板を介して受光素子が透過した光を受けるように配置し、スリット板はエンコーダの回転体に設置されているため、回転すると正弦波の波形が受光素子から出力するようにスリット板の格子状の形が形成されている。   An LED or laser light is used as the light emitting element, and a photodiode or phototransistor is used as the light receiving element. The slit plate is made of glass or a resin material that transmits light, and a lattice-like mask that blocks light is provided on the slit plate. The light from the light emitting element is arranged to receive the light transmitted by the light receiving element through the slit plate, and the slit plate is installed on the rotating body of the encoder. Thus, a lattice-like shape of the slit plate is formed.

AD変換手段としてのAD変換器2は、エンコーダから出力されるアナログ信号のA0信号、B0信号をディジタル信号に変換する。エンコーダから出力されるアナログ信号の振幅は数100mVであるため、増幅器などを用いて十数倍に増幅して、AD変換器2の入力レンジに合わせた電圧に変換して利用すれば、ディジタル信号の精度を高くすることができる。   The AD converter 2 as AD conversion means converts the analog signal A0 signal and B0 signal output from the encoder into digital signals. Since the amplitude of the analog signal output from the encoder is several hundred mV, the digital signal can be amplified by using an amplifier or the like by amplifying it by a factor of ten and converting it to a voltage suitable for the input range of the AD converter 2. Accuracy can be increased.

ピーク検出器15は、AD変換器2の出力信号であるA1信号、B1信号のピーク値を検出する。ピーク値の検出方法は、A1信号の前回サンプリングでの値と今回サンプリングでの値を比較し、今回サンプリングでの値が大きい場合にその値を保持し、この動作をA1信号の正弦波の0〜180度区間で行うことで最大値を検出することができる。   The peak detector 15 detects the peak values of the A1 signal and B1 signal that are output signals of the AD converter 2. The peak value is detected by comparing the value of the previous sampling of the A1 signal with the value of the current sampling. If the value of the current sampling is large, the value is retained, and this operation is performed as 0 of the sine wave of the A1 signal. The maximum value can be detected by performing the operation in the interval of ˜180 degrees.

最小値についても同様に、前回サンプリングでの値と今回サンプリングでの値を比較し、今回サンプリングでの値が小さい場合にその値を保持し、この動作をA1信号の180〜360度区間で行うことで最小値を検出することができる。90度位相のずれたB1信号についても検出動作区間を90度ずらせて同様な処理を行うことで最大値と最小値を検出することができる。   Similarly, the minimum value is compared with the value of the previous sampling and the value of the current sampling, and when the value of the current sampling is small, the value is retained, and this operation is performed in the 180 to 360 degree interval of the A1 signal. Thus, the minimum value can be detected. For the B1 signal whose phase is shifted by 90 degrees, the maximum value and the minimum value can be detected by performing the same processing while shifting the detection operation section by 90 degrees.

オフセット/振幅補正手段4は、ピーク検出器15で検出した最大値・最小値信号16を用いてA1信号、B1信号のオフセット除去と振幅の正規化を行う。   The offset / amplitude correction means 4 uses the maximum / minimum value signal 16 detected by the peak detector 15 to perform offset removal and amplitude normalization of the A1 signal and B1 signal.

A1信号とB1信号のオフセット(OS_DETa、OS_DETb)は、最大値・最小値信号16を用いて、式1から求めることができる。また、補正するオフセット値をOS_LEVEL、オフセット除去後の信号をA1D信号とB1D信号とすると、式2からオフセットを除去することができる。   The offsets (OS_DETa, OS_DETb) between the A1 signal and the B1 signal can be obtained from Equation 1 using the maximum value / minimum value signal 16. Further, when the offset value to be corrected is OS_LEVEL, and the signals after offset removal are the A1D signal and the B1D signal, the offset can be removed from Equation 2.

A1信号とB1信号の振幅値(PP_DETa、PP_DETb)についても最大値・最小値信号16を用いて、式3で求めることができる。また、振幅を正規化する大きさをKとすると、式4からオフセットと振幅の誤差を補正したA2信号とB2信号を求めることができる。 The amplitude values (PP_DETa, PP_DETb) of the A1 signal and the B1 signal can also be obtained by Expression 3 using the maximum value / minimum value signal 16. If the magnitude for normalizing the amplitude is K, the A2 signal and the B2 signal in which the offset and amplitude errors are corrected can be obtained from Equation 4.

次に、本発明の位置データ変換手段9の動作について説明する。位置データ回路9は、信号整形手段6と、位相誤差検出器7と、変換信号生成手段8と、データ変換手段10で
構成されており、この動作の詳細について、図2から図5を用いて説明する。
Next, the operation of the position data conversion means 9 of the present invention will be described. The position data circuit 9 includes a signal shaping unit 6, a phase error detector 7, a conversion signal generation unit 8, and a data conversion unit 10. Details of this operation will be described with reference to FIGS. explain.

最初に、位相誤差検出器7について説明する。図2は位相誤差がαラジアンの場合のA2信号、B2信号を表している。また、A2信号とB2(0)信号は位相誤差がない(位相差が90度)の場合を表している。位相誤差検出器7は、A2信号とB2信号の交点の大きさを表す交点信号13を検出する。   First, the phase error detector 7 will be described. FIG. 2 shows the A2 signal and the B2 signal when the phase error is α radians. Further, the A2 signal and the B2 (0) signal represent the case where there is no phase error (the phase difference is 90 degrees). The phase error detector 7 detects an intersection signal 13 indicating the size of the intersection of the A2 signal and the B2 signal.

位相誤差がない場合(つまりA2信号とB2(0)信号の場合)は、交点はπ/4ラジアン、5π/4ラジアンであり、その交点信号13は、Ksin(π/4)、Ksin(5π/4)となる。位相誤差がαラジアンの場合(つまりA2信号とB2信号の場合)は、交点は(π/4−α/2)ラジアン、(5π/4−α/2)ラジアンであり、その交点信号13は、C1=Ksin(π/4−α/2)、C2=Ksin(5π/4−α/2)となる。   When there is no phase error (that is, in the case of the A2 signal and the B2 (0) signal), the intersection is π / 4 radians and 5π / 4 radians, and the intersection signals 13 are Ksin (π / 4) and Ksin (5π / 4). When the phase error is α radians (that is, in the case of the A2 signal and the B2 signal), the intersection points are (π / 4-α / 2) radians and (5π / 4-α / 2) radians, and the intersection signal 13 is , C1 = Ksin (π / 4-α / 2) and C2 = Ksin (5π / 4-α / 2).

次に、変換信号生成手段8について説明する。変換信号生成手段8は、位相誤差検出器7で検出した交点信号13を用いて図3に示すように、A2信号とB2信号のそれぞれの信号に対して、位相差が90度となる変換補助信号B2D信号とA2D信号を生成する。A2信号、B2信号は、式5で表すことができるので、A2信号と位相差が90度となる信号を式6で求めることができる。   Next, the conversion signal generation means 8 will be described. As shown in FIG. 3, the conversion signal generation means 8 uses the intersection signal 13 detected by the phase error detector 7 to convert the phase difference to 90 degrees with respect to each of the A2 signal and the B2 signal. A signal B2D signal and an A2D signal are generated. Since the A2 signal and the B2 signal can be expressed by Expression 5, a signal having a phase difference of 90 degrees with respect to the A2 signal can be obtained by Expression 6.

この式6について詳細に説明する。A2信号と90度位相差となるB2D信号は式6から式7のように展開することができる。ここで、KS1=sinαとなるようにKS1を選定すると、cosαはαが分かれば係数となるので、B2D信号はA2信号に対して位相差が90度になる。 Formula 6 will be described in detail. A B2D signal having a 90-degree phase difference from the A2 signal can be developed as shown in Expression 6 to Expression 7. Here, when KS1 is selected so that KS1 = sin α, cos α becomes a coefficient if α is known, so that the B2D signal has a phase difference of 90 degrees with respect to the A2 signal.

同様にして、B2信号と90度位相差となるA2D信号は式6から式8のように展開することができる。ここで、KS2=sinαとなるようにKS2を選定すると、cosα
はαが分かれば係数となるので、A2D信号はB2信号に対して位相差が90度になる。位相誤差αは、交点信号13の大きさをC1、C2とすると式9から求めることができる。以上が変換補助信号A2D信号とB2D信号を生成する変換信号生成手段8の動作である。
Similarly, an A2D signal having a 90-degree phase difference from the B2 signal can be developed as shown in Equation 6 to Equation 8. Here, when KS2 is selected so that KS2 = sin α, cos α
Is a coefficient if α is known, the phase difference of the A2D signal is 90 degrees with respect to the B2 signal. The phase error α can be obtained from Equation 9 when the magnitude of the intersection signal 13 is C1 and C2. The above is the operation of the conversion signal generation means 8 that generates the conversion auxiliary signal A2D signal and the B2D signal.

次に、信号整形手段6とデータ変換手段10について説明する。図4はB2信号から角度データであるB4D信号を生成するまでの動作を図示している。また、図5はA2信号から角度データであるA4D信号を生成するまでの動作を示している。 Next, the signal shaping means 6 and the data conversion means 10 will be described. FIG. 4 illustrates the operation from the generation of the B2 signal to the generation of the B4D signal that is angle data. FIG. 5 shows an operation from generation of an A4D signal as angle data from the A2 signal.

この動作の詳細にについて説明する。信号整形手段6では、図4におけるB2信号を逆三角関数変換するために、角度領域を0〜πラジアンで表すB3信号を生成する。変換は変換信号生成手段8で生成したB2信号と、90度の位相差であるA2D信号を利用し、A2D信号が正の場合はB2信号はそのままの状態とし、A2D信号が負の場合はB2信号の符号を反転させることで、B3信号を生成する。   Details of this operation will be described. The signal shaping means 6 generates a B3 signal in which an angle region is represented by 0 to π radians in order to perform inverse trigonometric function conversion on the B2 signal in FIG. The conversion uses the B2 signal generated by the conversion signal generation means 8 and the A2D signal having a phase difference of 90 degrees. If the A2D signal is positive, the B2 signal is left as it is. If the A2D signal is negative, the B2 signal is used. The B3 signal is generated by inverting the sign of the signal.

次に、データ変換手段10では、B3信号を逆三角関数変換(arccos変換)し、0〜πラジアンまでの角度データB4信号に変換し、更にA2D信号が負の場合にはB4信号にπラジアンを加算することで、0〜2πラジアンまでの角度データB4Dを生成する。   Next, the data conversion means 10 performs inverse trigonometric function conversion (arccos conversion) on the B3 signal and converts it into angle data B4 signal of 0 to π radians. Further, when the A2D signal is negative, the B4 signal is converted to π radians. Are added to generate angle data B4D from 0 to 2π radians.

次に、A4D信号の生成について図5を用いて説明する。A2信号を逆三角関数変換するために、角度領域を−π/2〜π/2ラジアンで表すA3信号を生成する。変換は変換信号生成手段8で生成したA2信号と、90度位相差であるB2D信号を利用し、B2D信号が正の場合は、A2信号はそのままの状態とし、B2D信号が負の場合は、A2信号の符号を反転させることでA3信号を生成する。   Next, generation of an A4D signal will be described with reference to FIG. In order to perform inverse trigonometric function conversion on the A2 signal, an A3 signal in which the angle region is represented by −π / 2 to π / 2 radians is generated. The conversion uses the A2 signal generated by the conversion signal generation means 8 and the B2D signal having a phase difference of 90 degrees. When the B2D signal is positive, the A2 signal is left as it is, and when the B2D signal is negative, The A3 signal is generated by inverting the sign of the A2 signal.

次に、データ変換手段10では、A3信号を逆三角関数変換(arcsin変換)し、角度領域を−π/2〜π/2ラジアンまでの角度データA4信号に変換し、更にB2D信号が負の場合にはA4信号にπラジアンを加算し、B2D信号が正でかつA2D信号が負の場合にはA4信号に3π/2ラジアンを加算することで、0〜2πラジアンまでの角度データA4Dを生成する。   Next, in the data conversion means 10, the A3 signal is subjected to inverse trigonometric function conversion (arcsin conversion), the angle region is converted into angle data A4 signal of -π / 2 to π / 2 radians, and the B2D signal is negative. In this case, add π radians to the A4 signal, and if the B2D signal is positive and the A2D signal is negative, add 3π / 2 radians to the A4 signal to generate angle data A4D from 0 to 2π radians. To do.

以上が、A4D信号とB4D信号を生成する信号整形手段6とデータ変換手段10の動作である。   The above is the operation of the signal shaping means 6 and the data conversion means 10 that generate the A4D signal and the B4D signal.

次に、データ合成手段11について図6、図7を用いて説明する。図6は位相誤差がαラジアンであるA1信号とB1信号に対し、オフセット/振幅補正手段4により補正されたA2信号とB2信号、変換信号生成手段によって、A2信号とB2信号に対して位相差が90度であるB2D信号とA2D信号を表している。ここで、B2D信号がゼロのときのA2信号の値C3とC5を検出し、A2D信号がゼロのときのB2信号の値C4とC6を検出する。C3、C4、C5及びC6は、式10で表すことができる。   Next, the data synthesizing means 11 will be described with reference to FIGS. FIG. 6 shows a phase difference between the A2 signal and B2 signal corrected by the offset / amplitude correction means 4 and the A2 signal and B2 signal by the conversion signal generation means for the A1 signal and B1 signal having a phase error of α radians. Represents a B2D signal and an A2D signal with 90 degrees. Here, the values C3 and C5 of the A2 signal when the B2D signal is zero are detected, and the values C4 and C6 of the B2 signal when the A2D signal is zero are detected. C3, C4, C5 and C6 can be represented by Formula 10.

図6のように、A2信号に対してB2信号が進んでいる場合、C3とC6は負で、C4とC5は正となり、A2信号に対してB2信号が遅れている場合、C3とC6は正で、C4とC5は負となるので、式10を逆三角関数変換した式11から各交点での位相誤差を求めて、平均処理することで位相誤差αラジアンを求めることができる。また、A2信号に対してB2信号が進んでいるのか、遅れているのかを検出することができる。 As shown in FIG. 6, when the B2 signal is advanced with respect to the A2 signal, C3 and C6 are negative, C4 and C5 are positive, and when the B2 signal is delayed with respect to the A2 signal, C3 and C6 are Since C4 and C5 are positive and negative, the phase error α radians can be obtained by calculating the phase error at each intersection from the equation 11 obtained by inverse trigonometric function transformation of the equation 10 and averaging. Further, it can be detected whether the B2 signal is advanced or delayed with respect to the A2 signal.

図7は、角度データA4D信号とB4D信号が位相誤差αラジアンを含めた形で表している。位相誤差αラジアンは式11を平均処理することで求めることができるので、B4D信号にαラジアンを減算することで、A4D信号と位相誤差がゼロとなるB4DD信号を求めることができる。A4D信号とB4DD信号の信号を合成、例えば平均処理することで、内挿データθIP14を求めることができる。以上がデータ合成手段11の動作である。 FIG. 7 shows the angle data A4D signal and B4D signal in a form including the phase error α radians. Since the phase error α radians can be obtained by averaging the equation 11, the B4DD signal having a phase error of zero can be obtained by subtracting α radians from the B4D signal. Interpolation data θIP14 can be obtained by synthesizing, for example, averaging, the signals of the A4D signal and B4DD signal. The above is the operation of the data synthesizing means 11.

以上のように、位相誤差のない変換補助信号を用いて角度データを生成することで、位相誤差がある場合にも歪みのない角度データを生成することができる。また、変換補助信号A2D信号とB2D信号のゼロクロス点を用いることで、ダイナミックレンジの大きな領域で位相誤差を求めるため、検出精度が向上する。検出値は1周期あたり4回検出できるので、その結果を平均処理することでノイズに対しても影響を小さく抑えることができる。   As described above, by generating the angle data using the conversion auxiliary signal having no phase error, it is possible to generate angle data without distortion even when there is a phase error. In addition, by using the zero cross point of the conversion auxiliary signal A2D signal and the B2D signal, the phase error is obtained in a region having a large dynamic range, so that the detection accuracy is improved. Since the detection value can be detected four times per cycle, the influence on noise can be suppressed to a small extent by averaging the results.

本発明のエンコーダ信号の位相補正回路は、サーボモータ制御装置に限らず、高分解能の位置情報を得るためにエンコーダを搭載した装置に有用である。   The encoder signal phase correction circuit of the present invention is useful not only for servo motor control devices but also for devices equipped with an encoder for obtaining high-resolution position information.

本発明の実施の形態1におけるエンコーダ信号処理回路のブロック図Block diagram of an encoder signal processing circuit in Embodiment 1 of the present invention 実施の形態1の位相誤差検出器における信号波形の説明図Explanatory drawing of the signal waveform in the phase error detector of the first embodiment 実施の形態1の変換信号生成手段における信号波形の説明図Explanatory drawing of the signal waveform in the conversion signal production | generation means of Embodiment 1. 実施の形態1におけるB相信号変換の説明図Explanatory drawing of B phase signal conversion in Embodiment 1 実施の形態1におけるA相信号変換の説明図Explanatory drawing of A phase signal conversion in Embodiment 1 実施の形態1のデータ合成手段におけるAB相信号波形の説明図Explanatory drawing of AB phase signal waveform in the data synthesizing means of the first embodiment 実施の形態1における内挿データ生成の説明図Explanatory drawing of the interpolation data generation in Embodiment 1. 従来例におけるエンコーダ信号処理回路のブロック図Block diagram of an encoder signal processing circuit in a conventional example 従来例におけるB相信号変換の説明図Explanatory drawing of B phase signal conversion in the conventional example 従来例におけるA相信号変換の説明図Explanatory drawing of A phase signal conversion in the conventional example 従来例における内挿データ生成の説明図Explanatory drawing of interpolation data generation in a conventional example

符号の説明Explanation of symbols

2 AD変換手段(AD変換器)
4 オフセット/振幅補正手段
6 信号整形手段
7 位相誤差検出器
8 変換信号生成手段
9 位置データ変換手段
10 データ変換手段
11 データ合成手段
13 位相誤差補正量
14 内挿データ(内挿の角度データθIP)
16、16a 最大値・最小値信号
A0,B0 アナログ原信号(A相、B相)
A1,B1 ディジタル変換後の信号(A相、B相)
A2,B2 オフセット/振幅補正後の信号(A相、B相)
A2D,B2D 変換補助信号(A相、B相)
A3,B3 信号整形後の信号(A相、B相)
A4,B4 A相、B相の角度データ(0〜πラジアン)
A4D,B4D A相、B相の角度データ(0〜2πラジアン)
B4DD 位相補正後のB相の角度データ
C1,C2 A2信号とB2信号の交点
C3,C5 B2D信号のゼロクロス点におけるB2信号の大きさ
C4,C6 A2D信号のゼロクロス点におけるA2信号の大きさ
2 AD conversion means (AD converter)
4 Offset / amplitude correction means 6 Signal shaping means 7 Phase error detector 8 Conversion signal generation means 9 Position data conversion means 10 Data conversion means 11 Data synthesis means 13 Phase error correction amount 14 Interpolation data (angle data θIP for interpolation)
16, 16a Maximum value / minimum value signal A0, B0 Analog original signal (A phase, B phase)
A1, B1 Digital converted signal (A phase, B phase)
A2, B2 Offset / Amplitude corrected signal (A phase, B phase)
A2D, B2D conversion auxiliary signal (A phase, B phase)
A3, B3 Signal after shaping (A phase, B phase)
A4, B4 A phase and B phase angle data (0 to π radians)
A4D, B4D A phase and B phase angle data (0 to 2π radians)
B4DD B-phase angle data after phase correction C1, C2 Intersection of A2 signal and B2 signal C3, C5 Size of B2 signal at zero crossing point of B2D signal C4, C6 Size of A2 signal at zero crossing point of A2D signal

Claims (3)

直交するA相とB相の正弦波信号をディジタルデータに変換してA1信号とB1信号を生成するAD変換手段と、A1信号とB1信号のピーク値を検出するピーク検出器と、前記ピーク検出器で検出したピーク値を用いてオフセットおよび振幅の誤差を補正してA2信号とB2信号を生成するオフセット/振幅補正手段と、前記A2信号とB2信号を角度データA4D信号とB4D信号に変換する位置データ変換手段と、前記位置データ変換手段で求めた角度データA4D信号とB4D信号を合成して、内挿データを生成するデータ合成手段とを有した位置検出器において、前記位置データ変換手段は、前記A2信号とB2信号の交点値から位相誤差信号を生成する位相誤差検出器と、前記位相誤差信号から前記A2信号との位相差が90度である変換補助信号B2D信号を生成し、前記B2信号との位相差が90度である変換補助信号A2D信号を生成する変換信号生成手段と、前記A2D信号を基準として前記B2信号を0〜πラジアンの領域に波形整形してB3信号を生成し、前記B2D信号を基準として前記A2信号を−π/2〜π/2ラジアンの領域に波形整形してA3信号を生成する信号整形手段と、前記A3信号とB3信号を逆三角関数変換し、前記A2信号とB2信号と前記A2D信号とB2D信号から0〜2πの角度データに変換するデータ変換手段とを備え、前記変換信号生成手段は、前記位相誤差信号から生成した補正係数を用いてA2信号とB2信号に乗算してA補正信号とB補正信号を生成し、さらに前記A2信号に前記B補正信号を加算してB2信号に対して位相が90度となる変換補助信号A2D信号を生成し、前記B2信号に前記A補正信号を加算してA2信号に対して位相が90度となる変換補助信号B2D信号を生成し、B2D信号を用いてA2信号を角度データに変換し、A2D信号を用いてB2信号を角度データに変換することを特徴としたエンコーダの信号処理回路。 A / D conversion means for generating A1 signal and B1 signal by converting orthogonal A-phase and B-phase sine wave signals into digital data, a peak detector for detecting peak values of A1 signal and B1 signal, and the peak detection Offset / amplitude correction means for generating an A2 signal and a B2 signal by correcting offset and amplitude errors using the peak value detected by the detector, and converting the A2 signal and the B2 signal into angle data A4D signal and B4D signal. In the position detector having position data converting means and data combining means for generating interpolation data by combining the angle data A4D signal and B4D signal obtained by the position data converting means, the position data converting means is A phase error detector that generates a phase error signal from an intersection value of the A2 signal and the B2 signal, and a phase difference between the phase error signal and the A2 signal is 90 degrees. A conversion signal generating means for generating a conversion auxiliary signal B2D signal and generating a conversion auxiliary signal A2D signal having a phase difference of 90 degrees with respect to the B2 signal; and the B2 signal as 0 to π radians with the A2D signal as a reference A signal shaping means for generating a B3 signal by shaping the waveform into a region of A2 and generating an A3 signal by shaping the waveform of the A2 signal into a region of -π / 2 to π / 2 radians with reference to the B2D signal; Data conversion means for performing inverse trigonometric function conversion on the A3 signal and the B3 signal, and converting the A2 signal, the B2 signal, the A2D signal, and the B2D signal into angle data of 0 to 2π, and the conversion signal generation means includes: A correction signal generated from the phase error signal is used to multiply the A2 signal and the B2 signal to generate an A correction signal and a B correction signal. Further, the B correction signal is added to the A2 signal and the B2 signal is paired. Then, a conversion auxiliary signal A2D signal having a phase of 90 degrees is generated, and the A correction signal is added to the B2 signal to generate a conversion auxiliary signal B2D signal having a phase of 90 degrees with respect to the A2 signal, and B2D A signal processing circuit for an encoder, wherein an A2 signal is converted into angle data using a signal, and a B2 signal is converted into angle data using an A2D signal. 前記データ合成手段は、B2D信号のゼロクロス点でのB2信号の位相ずれ量を検出し、A2D信号のゼロクロス点でのA2信号の位相ずれ量を検出し、位相ずれ量から角度誤差値を算出し、求めた角度誤差値をA相、またはB相の角度データから減算することで位相ずれを補正することを特徴とした請求項1記載のエンコーダの信号処理回路。 The data synthesizing means detects a phase shift amount of the B2 signal at the zero cross point of the B2D signal, detects a phase shift amount of the A2 signal at the zero cross point of the A2D signal, and calculates an angle error value from the phase shift amount. The encoder signal processing circuit according to claim 1, wherein the phase shift is corrected by subtracting the obtained angle error value from the A-phase or B-phase angle data. 前記データ合成手段は、B2D信号のゼロクロス点でのB2信号の位相ずれ量を検出し、A2D信号のゼロクロス点でのA2信号の位相ずれ量を検出し、A相とB相の位相ずれ量の平均値から角度誤差値を算出し、求めた角度誤差値をA相、またはB相の角度データから減算することで位相ずれを補正することを特徴とした請求項1記載のエンコーダの信号処理回路。
The data synthesizing means detects the phase shift amount of the B2 signal at the zero cross point of the B2D signal, detects the phase shift amount of the A2 signal at the zero cross point of the A2D signal, and determines the phase shift amount between the A phase and the B phase. 2. The signal processing circuit for an encoder according to claim 1, wherein an angle error value is calculated from the average value, and the phase error is corrected by subtracting the obtained angle error value from the A-phase or B-phase angle data. .
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Cited By (4)

* Cited by examiner, † Cited by third party
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JP2013011629A (en) * 2012-10-16 2013-01-17 Denso Corp Rotation angle detection device and electric power steering device using the same
JP2013054007A (en) * 2011-09-06 2013-03-21 Hamamatsu Koden Kk Encoder device and correction method for encoder device
CN109000689A (en) * 2018-09-25 2018-12-14 中国科学院长春光学精密机械与物理研究所 A kind of data processing method of absolute photoelectric shaft encoder, system
KR102119847B1 (en) * 2018-12-07 2020-06-05 현대오트론 주식회사 Method and module of error compensation between the mr sensor output signal for an rotor position sensing of the electric motor

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2013054007A (en) * 2011-09-06 2013-03-21 Hamamatsu Koden Kk Encoder device and correction method for encoder device
JP2013011629A (en) * 2012-10-16 2013-01-17 Denso Corp Rotation angle detection device and electric power steering device using the same
CN109000689A (en) * 2018-09-25 2018-12-14 中国科学院长春光学精密机械与物理研究所 A kind of data processing method of absolute photoelectric shaft encoder, system
CN109000689B (en) * 2018-09-25 2021-05-04 中国科学院长春光学精密机械与物理研究所 Data processing method and system of absolute photoelectric shaft angle encoder
KR102119847B1 (en) * 2018-12-07 2020-06-05 현대오트론 주식회사 Method and module of error compensation between the mr sensor output signal for an rotor position sensing of the electric motor

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