Patent Document

BACKGROUND OF THE INVENTION 
     The present invention relates to a detector and a method for detecting the rotational speed of a rotative member. More particularly, the present invention pertains to a detector and method for detecting a rotational angle of a vehicle steering shaft. 
     A typical rotational angle detector includes a rotor attached to a steering shaft. Slits are formed along a single circumference on the rotor. Luminous elements are arranged at one side of the rotor. Photodetectors, each of which corresponds to one of the luminous elements, are arranged at the opposite side of the rotor. When receiving light from the corresponding luminous element, each photodetector outputs a signal of H level. When light from the luminous element does not reach the photodetector, the photodetector outputs a signal of L level. A combination of signals of H level and signals of L level from the photodetectors represents a single reflective code. 
     The rotational angle detector has a memory. The memory previously stores data representing the relationship between reflective codes and rotational angles of the rotor. When a reflective code is generated based on signals from the luminous elements and the photodetectors, a pattern of reflective code that corresponds to the generated reflective code is retrieved from the memory. The rotational angle of the steering wheel is obtained based on the retrieved pattern data, which corresponds to the generated reflective code. 
     However, the above described rotational angle detector stores pattern data that correspond to all the reflective codes, which requires an increased memory capacity. Therefore, the manufacturing of the detector is costly. 
     SUMMARY OF THE INVENTION 
     Accordingly, it is an objective of the present invention to provide a rotational angle detector that reduces required memory capacity. 
     Other aspects and advantages of the present invention will become apparent from the following description, taken in conjunction with the accompany drawing, illustrating by way of example the principles of the invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The features of the present invention that are believed to be a novel are set forth with particularity in the appended claims. The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which: 
     FIG. 1 is a perspective view illustrating a rotational angle detector; 
     FIG. 2 is a plan view showing the rotor of FIG. 1; 
     FIG. 3 is an enlarged plan view showing the rotor of FIG. 2; 
     FIG. 4 is a schematic circuit diagram of the detector of FIG. 1; 
     FIG. 5 is a chart showing reflective codes; 
     FIG. 6 is a chart showing a table storing reflective codes; 
     FIGS.  7 ( a ) and  7 ( b ) are charts used for calculating a rotational angle when a reflective code is not on the table of FIG. 6; and 
     FIGS.  8 ( a ) and  8 ( b ) are charts used for calculating a rotational angle when a reflective code is not on the table of FIG.  6 . 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     A rotational angle detector for a vehicle steering wheel according to one embodiment of the present invention will now be described. 
     As shown in FIGS. 1 and 2, a rotor  12  is fixed to a rotative member, which is a steering shaft  11  in this embodiment. The rotor  12  rotates integrally with the steering shaft  11  about an axis L of the steering shaft  11 . 
     Outer slit regions A 1  to A 5  are defined along a circle having a radius R 1  about the axis L. The circle having the radius R 1  will hereafter be referred to a first track T 1 . The outer regions A 1  to A 5  are defined by evenly dividing the first track T 1  by five. Each of the outer slit regions A 1  to A 5  therefore corresponds to a segment having an angle of 72°(360°/5). Each outer slit region A 1  to A 5  has six outer slits  13 , which are formed along the first track T 1 . The pattern of sizes of the outer slits  13  and the spaces between adjacent slits  13  are the same for each of the outer slit regions A 1  to A 5 . 
     Inner slit regions B 1  to B 14  are defined along a circle having a radius R 2  (R 2 &lt;R 1 ) about the axis L. The circle of the radius R 2  will hereafter be referred to a second track T 2 . The inner slit regions B 1  to B 14  are defined by evenly dividing the second track T 2  by fourteen. Each of the inner slit regions B 1  to B 14  therefore corresponds to a segment having an angle of 25.714°(360°/14). Each inner slit region B 1  to B 14  has three inner slits  14 , which are formed along the second track T 2 . The pattern of sizes of the inner slits  14  and the spaces between adjacent slits  14  are the same for each of the inner slit regions B 1  to B 14 . 
     As shown in FIGS. 1 to  3 , a light emitter  18  and a light receiver  19  are arranged to face each other with the rotor  12  in between. The light emitter  18  includes first to seventh outer luminous elements  20   a  to  20   g  and first to fifth inner luminous elements  21   a  to  21   e . The luminous elements  20   a  to  20   g  and  21   a  to  21   e  each include a light emitting diode. The light receiver  19  includes first to seventh outer photodetectors  22   a  to  22   g  and first to fifth inner photodetectors  23   a  to  23   e . The photodetectors  22   a  to  22   g  and  23   a  to  23   e  each include a photodiode. 
     Each outer luminous element  20   a  to  20   g  faces a corresponding one of the outer photodetectors  20   a  to  20   g . Also, each inner luminous element  21   a  to  21   e  faces a corresponding one of the inner photodetectors  23   a  to  23   e . The outer and inner luminous elements  20   a  to  20   g  and  21   a  to  21   e  and the outer and inner photodetectors  22   a  to  22   g  and  23   a  to  23   e  are arranged on a limited arcuate region of the rotor  12 . 
     The outer luminous elements  20   a  to  20   g  and the outer photodetectors  22   a  to  22   g  form an outer sensor. The inner luminous elements  21   a  to  21   e  and the inner photodetectors  23   a  to  23   e  form an inner sensor. 
     The outer luminous elements  20   a  to  20   g  and the outer photodetectors  22   a  to  22   g  are located along the first track T 1  and are spaced apart by equal angular intervals. That is, as shown in FIG. 3, the outer luminous elements  20   a  to  20   g  and the outer photodetectors  22   a  to  22   g  are spaced apart by approximately 10.29°(the angle θ1 of FIG.  3 ). The angle θ1 is obtained by dividing 72°, which is the angular range of each outer region A 1  to A 5 , by seven (72°/7). 
     The inner luminous elements  21   a  to  21   e  and the inner photodetectors  23   a  to  23   e  are located along the second track T 2  and are spaced apart by equal angular intervals. That is, as shown in FIG. 3, the inner luminous elements  21   a  to  21   e  and the inner photodetectors  23   a  to  23   e  are spaced apart by 5.14° (the angle θ2 of FIG.  3 ). The angle of θ2 is obtained by dividing 25.714°, which is the angular range of each inner region B 1  to B 14 , by five (25.714°/5). The angular interval (5.14°) between each pair of the inner photodetectors  23   a  to  23   e  is half of the angular interval (10.29°) between each pair of the outer photodetectors  22   a  to  22   g.    
     The circuit construction of the rotational angle detector will now be described. As shown in FIG. 4, a central processing unit (CPU)  30  controls devices in the detector. A read only memory (ROM)  31  stores various control programs. A random access memory (RAM)  32  temporarily stores data obtained through performing the control programs. The CPU  30  serves as judging means, selecting means and computing means. The ROM  31  serves as memory. 
     The first to seventh outer luminous elements  20   a  to  20   g , the first to fifth inner luminous elements  21   a  to  21   e , the first to seventh outer photodetectors  22   a  to  22   g  and first to fifth inner photodetectors  23   a  to  23   e  are connected to the CPU  30 . 
     When each outer photodetector  22   a  to  22   g  receives light from the corresponding outer luminous element  20   a  to  20   g  through the outer slits  13  of the rotor  12 , the photodetector  22   a  to  22   b  sends a signal of H level to the CPU  30 . When light from each outer luminous element  20   a  to  20   g  is blocked and the corresponding outer photodetector  22   a  to  22   g  does not receive the light, the photodetector  20   a  to  22   g  sends a signal of L level to the CPU  30 . The CPU  30  obtains a seven-bit reflective code (see FIG. 5) in accordance with the combination of H level signals and L level signals from the outer photodetectors  22   a  to  22   g . H level is represented by one, and L level is represented by zero. Reflective code is a modified binary code in which sequential numbers are represented by expressions that differ only in one bit. In the example of FIG. 5, in an outer reflective code  35 , the fourth digit from the right is changed from zero to one, or from L level to H level. 
     When each inner photodetector  23   a  to  23   e  receives light from the corresponding inner luminous element  21   a  to  21   e  through the inner slits  14  of the rotor  12 , the photodetector  23   a  to  23   e  sends a signal having an H level to the CPU  30 . When light from each inner luminous element  21   a  to  21   e  is blocked and the corresponding inner photodetector  23   a  to  23   e  does not receive the light, the photodetector  23   a  to  23   e  sends a signal of L level to the CPU  30 . The CPU  30  obtains a five-bit reflective code (see FIG. 5) in accordance with the combination of H level signals and L level signals from the inner photodetectors  23   a  to  23   e . In the example of FIG. 5, the third digit from the right of an inner reflective code  36  is changed from H level to L level. 
     The seven-bit outer reflective code  35  and the five-bit inner reflective code  36  form a twelve-bit reflective code, or combined code. As described above, when the twelve-bit reflective code changes to a subsequent code, one bit, or digit, of each of the outer reflective code  35  and the inner reflective code  36  is changed. Therefore, as shown in FIG. 5, the second, subsequent twelve-bit reflective code differs by two bits. 
     The ROM  31  stores a table  37  shown in FIG.  6 . The table  37  defines the relationship between the outer and inner reflective codes  35 ,  36  and the rotational angle of the steering shaft  11 . The table  37  includes eighty-four outer reflective codes  35 . The eighty-four outer reflective codes  35  correspond to eighty-four angular subdivisions of a given outer slit region A 1  to A 5 . The table  37  also includes thirty inner reflective codes  36 . The thirty inner Areflective codes  36  correspond to thirty subdivisions of a given inner slit region B 1  to B 14 . 
     For example, in the eleventh row (combined code No.  10 ) in the table  37 , the outer reflective code is 1001001 and the inner reflective code is 11010. In this state, the rotational angle data is 8.57°. The rotational angle data has increments of 0.86°. That is, the resolution of the rotational angle detector is 0.86°. 
     The operation of the rotational angle detector will now be described. The CPU  30  performs the following operation based on control programs stored in the ROM  31 . 
     First, a case where a twelve-bit reflective code from the light receiver  19  is in the table  37  will be described. 
     When the ignition switch is turned on, power is supplied to the rotational angle detector. Then, the luminous elements  20   a  to  20   g  and  21   a  to  21   e  emit light toward the photodetectors  22   a  to  22   g  and  23   a  to  23   e . Accordingly, the photodetectors  22   a  to  22   g  and  23   a  to  23   e  output H level signals and L level signals. The combination of the signals defines the outer and inner reflective codes  35 ,  36 . The CPU  30  judges whether the resulting reflective codes are in the table  37 . 
     For example, if the outer reflective code  35  is 1001001 and the inner reflective code  36  is 11010, the twelve-bit reflective code is 100100111010, which is represented by the eleventh row (code No.  10 ) of the table  36 . Combination code No.  10  corresponds to an 8.57° angle of the steering wheel. 
     A case where a twelve-bit reflective code from the light receiver  19  is not in the table  37  will now be described. 
     If the outer reflective code  35  is 0000001 and the inner reflective code  36  is 00111, the twelve-bit reflective code 000000100111 does not match any of the combined codes in the table  37 . In this case, the rotational angle of the steering shaft  11  is separately computed based on the outer reflective code  35  and the inner reflective code  36 . 
     That is, the outer reflective code  35 , which is 0000001, corresponds to the twenty-fifth row (code No.  24 ) of FIG. 24, which is 20.57°. Since the sizes and arrangement of the outer slits  13  are common to all the outer slit regions A 1  to A 5 , the outer reflective code  35  corresponds to a certain position in one of the outer regions A 1  to A 5 . Therefore, as shown in FIG.  7 ( a ), the rotational angle computed based on the outer reflective code  35  is expressed by a formula 20.57°+72.00°i, where i is one of the values 0, 1, 2, 3 and 4. 
     As shown in FIGS.  7 ( a ) and  7 ( b ), the program is performed assuming that a one-bit reading error might occur in the outer reflective code  35  and the inner reflective code  36 . This is because the detecting accuracy of the outer photodetectors  22   a  to  22   g  and the inner photodetector  23   a  to  23   e  can cause errors. Therefore, when the outer reflective code  35  has a value 0000001, the CPU  30  prepares the following tentative reflective codes, which correspond to expected errors. With the value 0000001, the tentative codes of the outer reflective code  35  are 1000001, 01000001, 0100001, 0001001, 0000101, 0000011 and 0000000. 
     The CPU  30  selects pattern data, or codes, corresponding to the tentative reflective codes from the table  37 . In the case of FIG.  7 ( a ), the CPU  30  selects code No.  11  (1000001), code No.  25  (0100001), code No.  49  (0000101) and code No.  23  (0000011). The rotational angle that corresponds to the tentative reflective code of 1000001 is 9.43°+72.00°i. The rotational angle that corresponds to the tentative reflective code of 0100001 is 21.43°+72.00°i. The rotational angle that corresponds to the tentative reflective code of 0000101 is 42.00°+72.00°i. The rotational angle that corresponds to the tentative reflective code of 0000011 is 19.71°+72.00°i. 
     On the other hand, the rotational angle data corresponding to the inner reflective code  36  having a value “00111” is 0.00° as shown by code No.  0  of FIG.  6 . Since the sizes and arrangement of the inner slits  14  are common to all the inner slit regions B 1  to B 14 , the inner reflective code  36  corresponds to a certain position in one of the inner regions B 1  to B 14 . Therefore, as shown in FIG.  7 ( b ), a rotational angle computed based on the inner reflective code  36  is expressed by a formula 0.00°+25.714°j, wherein j is one of the values 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13. 
     As shown in FIG.  7 ( b ), the program is performed assuming that a one-bit reading error might occur in the inner reflective code  36 . Therefore when the inner reflective code  36  has a value 00111, the CPU  30  prepares the following tentative reflective codes, which correspond to expected errors. With the value 00111, the tentative codes of the inner reflective code  36  are 10111, 01111, 00011, 00101 and 00110. 
     The CPU  30  selects codes corresponding to the tentative reflective codes from the table  37 . In the case of FIG.  7 ( b ), the CPU  30  selects code No.  29  (10111), No.  5  (01111), No.  1  (00011), No.  15  (000101) and No.  7  (00110). A rotational angle that corresponds to the tentative reflective code of 10111 is 24.85°+25.714°j. A rotational angle that corresponds to the tentative reflective code of 01111 is 4.29°+25.714°j. A rotational angle that corresponds to the tentative reflective code of 00011 is 0.86°+25.714°j. A rotational angle that corresponds to the tentative reflective code of 00101 is 12.86°+25.714°j. A rotational angle that corresponds to the tentative reflective code of 00110 is 6.00°+25.714°j. 
     The resolution of the rotational angle detector is 0.86°. Thus, as shown in FIG.  7 ( a ), the angles 19.71°+72.00°i, 20.57°+72.00°i and 21.43°+72.00°i are consecutive angles. Among these angles, the angle 20.57°+72.00°i is the middle. 
     As shown in FIG.  7 ( b ), the angles 0.00°+25.714°j, 0.86°+25.714°j and 24.86°+25.714°j are consecutive angles. Among these angles, the angle 0.00°+25.714°j is the middle. 
     Judging from the characteristics of reflective codes, the middle values (20.57°+72.00°i and 0.00°+25.714°j) represent the rotational angle of the steering shaft  11 . That is, the rotational angle of the steering shaft  11  is 20.57°+72.00°i according to outer reflective code  35  and is 0.00°+25.714°j according to the inner reflective code  36 . Then, the angle value 20.57°+72.00°i is calculated with i replaced with 0, 1, 2, 3 and 4. Also, the value 0.00°+25.714°j is calculated with j replaced with 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13. As a result, when i is replaced with 4 and j is replaced with 12, the values 20.57°+72.00°i and the value 0.00°+25.714°j are both 308.57°, or equal to each other. In this manner, when the outer reflective code  35  is 0000001 and the inner reflective code 00111, the combination of which is not on the table  37 , the CPU  30  determines that the rotational angle of the drive shaft  11  is 308.57°. 
     Next, a case where the combination of the reflective codes  35 ,  36  is not on the table  37  and the rotational angle of the steering shaft  11  is below the resolution will be described. 
     For example, if the outer reflective code  35  is 0000001 and the inner reflective code  36  is 10111, the combined twelve-bit reflective code is 000000110111. The CPU  30  judges that the value 000000110111 is not in the table  37 . The CPU  40  therefore computes the rotational angle of the steering shaft  11  based separately on the outer reflective code  35  and the inner reflective code  36 . 
     FIG.  8 ( a ) shows a case in which the rotational angle of the drive shaft  11  is such that the outer reflective code  35  from the light receiver  19  is 0000001. This is the same as the case of FIG.  7 ( a ). Therefore, the rotational angle of the outer reflective code  35  is computed as 20.57°+72.00°i. 
     On the other hand, the rotational angle data according to the inner reflective code  36  of 10111 is 24.86° as shown by code No.  29  of FIG.  6 . Therefore, as shown in FIG.  8 ( b ), the rotational angle of the steering shaft  11  computed based on the inner reflective code  36  has a value 24.86°+25.714°j, in which j is one of the values 0 to 13. 
     Also, as shown in FIG.  8 ( b ), assuming that the inner reflective code  36  might have a one-bit reading error, the attentive inner reflective codes  36  having values 00111, 11111, 10011, 10101 and 10110 are prepared. 
     Then, the CPU  30  selects values that are in the table  37  among the expected inner reflective codes. In the case of FIG.  8 ( b ), code No.  0  (00111), code No.  24  (10011), code No.  16  (10101) and code No.  28  (10110) are selected. When the inner reflective code is 00111, the rotational angle is 0.00°+25.714°j. When the inner reflective code is 10011, the rotational angle is 20.57°+25.714°j. When the inner reflective code is 10101, the rotational angle is 13.71°+25.714°j. When the inner reflective code is 10110, the rotational angle is 24.00°+25.714°j. 
     The resolution of the rotational angle detector is 0.86°. Thus, as shown in FIG.  8 ( b ), the angles 24.00°+25.714°j, 24.86°+25.714°j and 0.00°+25.714°j are consecutive angles. Among these angles, the angle of 24.86°+25.714°i is the middle value. As described above, the middle value represents the actual rotational angle of the steering wheel  11 . Thus, the rotational angle of the steering shaft  11  computed based on the inner reflective code  36  is expressed by a value 24.86°+25.714°j. 
     Next, the value 24.86°+25.714°j is computed by replacing j with 0 to 13. Accordingly, tentative rotational angles of the steering shaft  11  are obtained. The tentative angles are 24.86°, 76.29°, 102.00°, 127.71°, 153.43°, 179.14°, 204.86°, 230.57°, 256.29°, 282.00°, 307.71°, 333.43° and 359.14°. 
     The rotational angle of the steering shaft  11  computed based on the outer reflective code  35  is 20.570+72.00°i. The symbol i is replaced with 0 to 4. Accordingly, tentative steering shaft angles are 20.57°, 92.57°, 236.57° and 308.57°. 
     Thus, the angle computed based on the inner reflective code  36  and the angle computed based on the outer reflective code  35  do not match. In this case, the CPU  30  judges that there is a difference of 0.86° between the angle based on the outer reflective code  35  and the angle based on the inner reflective code  36 . Therefore, the rotational angle computed based on the inner reflective code  36  is 307.71° and the rotational angle computed based on the outer reflective code  35  is 308.57°. That is, the actual rotational angle of the steering shaft  11  is between 307.71° and 308.57°. 
     If the rotational angle of the steering shaft  11  cannot be computed by the above process, the CPU  30  judges that the outer and inner reflective codes  35 ,  36  have erroneous values. In this case, the rotational angle of the steering shaft  11  is not computed. 
     The illustrated embodiment has the following advantages. 
     (1) The ROM  31  stores the table  37 , which includes the pattern data of the reflective codes  35 ,  36  and the corresponding rotational angle data. If a combined reflective code appears in the table  37 , the CPU  30  judges that the rotational angle of the steering shaft  11  is represented by the pattern data. When a combined reflective code is not on the table  37 , the CPU  30  computes the rotational angle of the steering shaft  11  based on the reflective codes  35 ,  36 . 
     Although, the resolution of the detector is 0.86°, the ROM  31  does not have to store 420 (420=360°/0.86°) patterns of data, codes. That is, as for the outer reflective code  35 , the ROM  31  stores eighty-four codes, which correspond eighty-four positions within a given outer slit region A 1  to A 5 . As for the inner reflective code  36 , the ROM  31  stores thirty patterns of data, or codes, which correspond to thirty positions within a given inner slit region B 1  to B 14 . In other words, there is no need for the ROM  31  to store all the pattern data corresponding to all the regions A 1  to A 5  and B 1  to B 14 , which minimizes the required memory capacity of the ROM  31 . 
     (2) The rotational angle of the steering shaft  11 , or rotative member, is separately computed based on the outer reflective code  35  and the inner reflective code  36 . Even if the rotational angle computed based on the outer reflective code  35  does not match the rotational angle computed based on the inner reflective code  36 , the actual angle of the steering shaft  11  is inferred within an error of 0.86°. 
     (3) It is assumed that the outer and inner reflective codes  35 ,  36  may have a one-bit reading error. The rotational angle of the steering shaft  11  is computed based on the tentative reflective codes. Therefore, the rotational angle of the steering shaft  11  is computed based on the wide variety of data, which improves the detection accuracy of the rotational angle. 
     (4) The outer luminous elements  20   a  to  20   g , the inner luminous elements  21   a  to  21   e , the outer photodetectors  22   a  to  22   g  and the inner photodetectors  23   a  to  23   e  are concentrated on a limited arcuate segment of the rotor  12 , which adds to the flexibility of the design and facilitates changes of the specifications and design. 
     It should be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention. Particularly, it should be understood that the invention may be embodied in the following forms. 
     In the illustrated embodiment, a single array of the inner slits  14  is formed radially inside the outer slits  13 . However, the inner slits  14  may be formed on circles having different radiuses. 
     In the illustrated embodiment, the outer and inner luminous elements  20   a  to  20   g  and  21   a  to  21   e  and the outer and inner photodetectors  22   a  to  22   g  and  23   a  to  23   e  are located in a limited arcuate segment of the rotor  12 . However, the luminous elements  20   a  to  20   g  and  21   a  to  21   e  and the photodetectors  22   a  to  22   g  and  23   a  to  23   e  may be evenly arranged along the entire circumference of the rotor  12 . 
     The present invention is used to detect the rotational angle of the steering shaft  11  in the illustrated embodiment. However, the present invention may be embodied in other devices. 
     The ROM  31  does not have to store all the rotational angle data, which reduces the required memory capacity of the ROM  31 . Also, the rotational angle of the steering shaft  11  is detected with an error within the resolution, which improves the detection accuracy of the rotational angle detector. 
     The present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.

Technology Category: 3