JP2010066054A - Indicator position detector, date detector, and moving body position detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indicator position detector, a date detector, and a moving body position detector for detecting indicator positions, a date, and a moving body position in real time. <P>SOLUTION: A minute hand 7 and an hour hand 6 have first and second light transmitting sections 21b, 22a, and are rotated. If the minute hand 7 and the hour hand 6 pass a plurality (60) of light receiving sections 24 in a first solar panel 13 disposed under the hour hand 6 and the minute hand 7, lights passing through the first and second light transmitting sections 21b, 22a are selectively received by a plurality of the light receiving section 24. The indicator positions of the minute hand 7 and the hour hand 6 are surely detected in real time in response to the state where the lights are received. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hand position detection device, a date detection device, and a moving body position detection device used for instruments such as a clock and a meter.

For example, in a timepiece hand position detection device, as described in Patent Document 1, a light transmission hole is provided in a gear of a train wheel mechanism that moves a pointer, and light from a light emitting element is irradiated on one surface of the gear. When the irradiated light is transmitted through the light transmission hole of the gear, the received light is received by the light receiving element, thereby detecting the position of the gear and determining the position of the pointer. It has been known.
JP 2006-46924 A

  However, in such a conventional needle position detection device, if the gear does not rotate by a predetermined angle, the light transmission hole of the gear does not correspond to the light emitting element, and the light from the light emitting element does not pass through the light transmission hole of the gear. There is a problem that the position of the pointer cannot be detected in real time.

  The problem to be solved by the present invention is to provide a needle position detecting device, a date detecting device, and a moving body position detecting device capable of detecting a hand position, a date, and a moving body position in real time.

In order to solve the above problems, the present invention includes the following components.
According to the first aspect of the present invention, there is provided a pointer that has a light transmitting portion and rotates around a pointer shaft, and a plurality of light receiving portions that are disposed below the pointer and are along a movement locus of the light transmitting portion. A solar panel having a light detection section divided into a plurality of light receiving sections, and a plurality of light receiving sections selectively receiving light transmitted through the light transmitting section, and determining the position of the pointer according to the light receiving state of the light And a needle position detecting device.

  According to a second aspect of the present invention, the light transmitting portion of the pointer and the light detecting portion of the solar panel are provided in the vicinity of the pointer shaft. It is a position detection device.

  According to a third aspect of the present invention, the pointer has at least a minute hand and an hour hand, and at least the minute hand and the hour hand are provided with the light transmission portions on mutually different rotation trajectories, and the solar The light detection part of the panel includes a plurality of first light receiving parts divided into a plurality corresponding to the rotation trajectory of the light transmission part of the minute hand, and a plurality of light detection parts corresponding to the rotation trajectory of the light transmission part of the hour hand The needle position detecting device according to claim 1, further comprising: a second light receiving unit divided into two.

  According to a fourth aspect of the present invention, there is provided a display rotator in which each light transmitting part having a different light transmission state is provided on each display part in which dates are sequentially displayed along the circumference, and an upper side of the display rotator. A dial having a display window corresponding to any one of the display units, and arranged below the display rotator in correspondence with the display window of the dial, and a light receiving unit. A solar panel having a plurality of light detection parts and light transmitted through the light transmission part of any one of the display parts corresponding to the display window part are light from each of the light transmission parts. A date detection apparatus comprising: a light receiving unit that receives light according to a transmission state; and a determination unit that determines the date according to a light reception state of the light.

  According to a fifth aspect of the present invention, there is provided a moving body having a light transmitting portion, and a light detecting portion arranged below the moving body and having a light receiving portion divided into a plurality along a movement locus of the light transmitting portion. A plurality of light receiving units that selectively receive light transmitted through the light transmitting unit and determine a position of the moving body according to a light receiving state of the light. This is a moving body position detecting device.

  According to the present invention, the solar panel can generate electric power, and a plurality of light receiving portions in the light detecting portion provided in the solar panel selectively receive the light transmitted through the light transmitting portion of the pointer, and this light The position of the pointer can be determined according to the light receiving state. As a result, the position of the pointer can be reliably detected in real time with a very simple configuration.

(Embodiment 1)
A first embodiment in which the present invention is applied to a pointer type timepiece will be described below with reference to FIGS.
This pointer-type timepiece includes a timepiece module 1 as shown in FIGS. The timepiece module 1 is accommodated in a timepiece case 2 as shown in FIG. A watch glass 3 is attached to the upper portion of the watch case 2, and a back cover 4 is attached to the lower surface of the watch case 2.

  As shown in FIG. 1, the timepiece module 1 moves the hour hand 6, the minute hand 7, and the second hand 8 above the dial 5 to indicate the time, and displays the date 10 on the display window portion 9 of the dial 5. It is configured as follows. In this case, the dial plate 5 is formed in a disk shape made of a transparent material, and a time character 11 is provided at the peripheral portion thereof as shown in FIG. A sub-scale unit 12 representing the second time is provided on the 6 o'clock side of the dial plate 5, and a display window unit 9 is provided near 4 o'clock of the dial plate 5. Further, on the inner periphery of the display window 9 on the lower surface of the dial plate 5, a first solar panel 13 that receives external light transmitted through the dial plate 5 and generates electric power is provided.

  As shown in FIGS. 2 and 8, a ring-shaped date display plate 14 having light transmission is rotatably disposed at a position located on the outer peripheral side of the first solar panel 13 below the dial 5. 2 and 9, a ring-shaped second solar that receives external light transmitted through the dial plate 5 and the date display plate 14 to generate power, as shown in FIGS. A panel 15 is provided. Further, as shown in FIG. 2, a timepiece movement 16 is provided below the second solar panel 15, and a circuit board 17 is disposed below the timepiece movement 16.

  Incidentally, the hour hand 6 and the minute hand 7 are attached to the pointer shaft 18 as shown in FIGS. As shown in FIGS. 1, 2, and 4, the pointer shaft 18 is inserted into a through hole 19a provided at substantially the center of the dial plate 5 and the first solar panel 13, and the date display plate 14, the second It is attached to the watch movement 16 through the inner periphery of the solar panel 15.

Further, the second hand 8 is attached to the second hand shaft 20 as shown in FIGS. 1 and 2. The second hand shaft 20 is located at the center of the sub-scale portion 12 of the dial plate 5 as shown in FIGS. 1, 2, and 4, and in this state, like the pointer shaft 18, the dial plate 5 and the first solar shaft 20. It is inserted into a through hole 19 b provided in the panel 13 and is attached to the timepiece movement 16 through the date display plate 14 and the second solar panel 15.

As shown in FIGS. 1 and 2, the timepiece movement 16 drives and rotates the pointer shaft 18 to move the hour hand 6 and the minute hand 7 above the dial 5 to indicate the hour, minute, and the second hand shaft. In addition to operating the second hand 8 to move the second hand 8 above the sub-scale portion 12 of the dial plate 5 to indicate the second time, the date display plate 14 is rotated to display the date on the date display plate 14. The date 10 is made to correspond to the display window portion 9 of the dial 5 so that the date 10 can be seen.

  In this case, as shown in FIG. 3A, a first light transmission selection unit 21 is provided at a location located in the vicinity of the pointer shaft 18 in the minute hand 7, and in the vicinity of the pointer shaft 18 in the hour hand 6. As shown in FIG. 3B, the second light transmission selection unit 22 is provided at the position where it is located. Moreover, the 1st light detection part 23 is provided in the location located in the vicinity of the pointer axis | shaft 18 in the 1st solar panel 13, as shown in FIG.3 (c).

  As shown in FIGS. 2 and 4, the first light detection unit 23 is separated from the power generation unit of the first solar panel 13, and as shown in FIG. It is arranged in a circular shape with a center. That is, the plurality of light receiving portions 24 are radially divided into 60 equal parts, each of which generates an electromotive force when receiving light, and is independently electrically connected to the circuit board 17 independently. ing.

  Moreover, the 1st light transmission selection part 21 of the minute hand 7 consists of the 1st light-shielding part 21a and the 1st light transmission part 21b, as shown to Fig.3 (a). The latter first light transmission part 21 b is provided at a position corresponding to the tip part (the upper end part in the figure) of the minute hand 7, and this first light transmission part 21 bb constitutes the first light detection part 23. A shape corresponding to any one of the plurality of light receiving portions 24 is formed.

Further, as shown in FIG. 3B, the second light transmission selection unit 22 of the hour hand 6 includes a second light shielding unit 22b and a second light transmission unit 22a. The former second light shielding part 22 b is provided at a position corresponding to the tip part (the upper end part in the figure) of the hour hand 6, and the second light shielding part 22 b includes a plurality of parts constituting the first light detection part 23. It is formed in a shape corresponding to any one of the light receiving portions 24.

As a result, as shown in FIG. 6A, when the hour hand 6 and the minute hand 7 overlap, the first light detection unit 23 includes all the light receiving units 24 divided into 60 first and second parts. Since it is covered with the light shielding portions 21a and 22b and none of the light receiving portions 24 receives light, no electromotive force is generated.
As shown in FIG. 6B, when the hour hand 6 and the minute hand 7 do not overlap, one of the 60 light receiving sections 24 receives light and generates an electromotive force. By detecting the position (that is, what number) of the light receiving unit 24 where power is generated, the position of the hour hand 6 and the minute hand 7 is determined to determine the current time.

  For example, as shown in FIG. 6 (a), the time when the hour hand 6 and the minute hand 7 overlap each other and all 60 light receiving parts 24 of the first light detecting part 23 cannot receive light is shown in FIG. As shown, 0:00, 1:05, 2:10, 3:16, 4:21, 5:27, 6:32, 7:38, 8:43, 9 Times 49, 10:54, and 11:59 (12 times are omitted in FIG. 12 when the light receiving unit 24 of the first light detecting unit 23 cannot receive light). ) Of the columns on the horizontal axis of the table portion of FIG. 12, “hour” is the hour digit indicated by the hour hand 6, “shadow” is the position of the shadow created by the hand, and “minute” is the minute digit indicated by the minute hand 7. , “Transmission” indicates the light transmission position created by the minute hand 7.

Further, as shown in FIG. 6B, the hour hand 6 and the minute hand 7 do not overlap with each other, and the second light-shielding portion 22b of the hour hand 6 corresponds to the 0th light receiving portion 24, that is, 0:00. At the time position, as shown in FIG. 12, the minute hand 7 sequentially advances clockwise one minute at a time, and the first light transmitting portion 21b of the minute hand 7 receives the eleventh light reception from the first light receiving portion 24. It can be seen that the first to eleventh light receiving sections 24 sequentially receive light with respect to the order of the section 24 from 0:01 to 0:11.

  Further, in the state where the second light-shielding portion 22b of the hour hand 6 corresponds to the first light receiving portion 24, that is, in the time zone of 0 o'clock, the minute hand 7 advances by one minute as shown in FIG. The light transmitting unit 21b sequentially receives light from the 12th to 23rd light receiving units 24 to the 23rd light receiving unit 24, so that the light transmitting unit 21b sequentially receives light. It turns out that it is 23 minutes.

Similarly, in the state where the second light-shielding part 22b of the hour hand 6 corresponds to the fourth light-receiving part 24, that is, in the time zone of 0 o'clock, the minute hand 7 advances one minute at a time, and the first light transmitting part 21b of the minute hand 7 Is from 0:48 to 0:59 by sequentially receiving light from the 48th light receiving unit 24 to the 59th light receiving unit 24 in order. I understand that.

  Then, as shown in FIG. 12, the second light-shielding portion 22b of the hour hand 6 corresponds to the fifth light-receiving portion 24, that is, in the time zone of 1 o'clock, the minute hand 7 advances by one minute, and the second hand 7 It can be seen that the 1-light transmitting portion 21b corresponds to the 0th light receiving portion 24, and the 0th light receiving portion 24 receives light, so that it is 1:00. Accordingly, the time between 1 o'clock represents the time when the second light shielding portion 22b of the hour hand 6 is in a state corresponding to the interval between the fifth light receiving portion 24 and the ninth light receiving portion 24.

Further, when the second light-shielding portion 22b of the hour hand 6 is in a state corresponding to the interval between the tenth light-receiving portion 24 and the fourteenth light-receiving portion 24, as shown in FIG. Similarly, when the second light-shielding part 22b of the hour hand 6 is in a state corresponding to the period from the 55th light-receiving part 24 to the 59th light-receiving part 24, the time zone at 11 o'clock is represented.

Incidentally, as shown in FIGS. 2 and 7A, the second light transmission portion 25 is provided in the vicinity of the second hand shaft 20 in the second hand 8. Moreover, in the location located in the vicinity of the second hand shaft 20 on the lower surface of the first solar panel 13 corresponding to the sub-scale portion 12 of the dial plate 5, as shown in FIGS. 2, 4, and 7 (b), A two-light detector 26 is provided. In the second light detection unit 26, as shown in FIG. 7B, a plurality of light receiving units 26a are arranged in a substantially circular shape with the second hand shaft 20 as the center.

  That is, the plurality of light receiving parts 26a are divided into 60 equal parts in a radial manner, like the first light detecting part 23, and each of them generates an electromotive force when receiving light, and each of them is independently and individually provided. The circuit board 17 is electrically connected. The third light transmission selection unit 25 of the second hand 8 includes a third light shielding unit 25a and a third light transmission unit 25b as shown in FIG. The latter third light transmission part 25 b is provided at a position corresponding to the tip part (the upper end part in the figure) of the second hand 8, and the third light transmission part 25 b constitutes the second light detection part 26. It is formed in a shape corresponding to any one light receiving part 26 a of the plurality of light receiving parts 24.

As a result, the second light detection unit 26 receives any of the light that has been transmitted through the third light transmission unit 25b of the third light transmission selection unit 25 into 60 pieces, and generates an electromotive force. By detecting the position (that is, what number) of the light receiving unit 26a that has generated and generated this electromotive force, the position of the second hand 8 is determined to determine the current second time, that is, the light receiving unit 26a that has generated the electromotive force. If it is the first, it is determined that it is 1 second, if it is the second, it is 2 seconds, and if it is the 59th, it is determined that it is 59 seconds.

  On the other hand, the date display board 14 is made of a transparent material, and as shown in FIG. 8, a date display section 27 displaying the dates 10 to 31 is provided along the circumference. As shown in FIG. 1 and FIG. 2, it is configured so that only the date 10 displayed on the date display unit 27 can be seen through the display window unit 9 by sequentially corresponding to the display window unit 9 of the dial plate 5. As shown in FIGS. 8 and 10A, the date display unit 27 is provided with a fourth light transmission selection unit 28 having a different light transmission state depending on the date 10.

As shown in FIGS. 2 and 9, the second solar panel 15 disposed below the date display board 14 is formed in a ring shape that is substantially the same size as the date display board 14, and is formed in the watch case 2. It is fixed to. A third light detection unit 29 is provided at a location corresponding to the display window portion 9 of the dial plate 5 in the second solar panel 15. As shown in FIGS. 9 and 10B, the third light detection unit 29 includes a plurality of light receiving units 30a to 30f corresponding to the fourth light transmission selection unit 28 provided in the date display unit 27. It is divided and provided.

That is, as shown in FIGS. 10A and 10B, the third light detection unit 29 includes two upper light receiving units 30a and 30b provided on the upper side of the date display unit 27, and a date display. It is divided into four lower light-receiving portions 30 c to 30 f provided on the lower side of the portion 27. In this case, the two upper light receiving portions 30a and 30b provided on the upper side portion of the date display portion 27 correspond to the tenth digit of the date 10, and the four lower light receiving portions provided on the lower side portion of the date display portion 27. 30 c to 30 f correspond to the first digit of the date 10.

  In addition, the fourth light transmission selection unit 28 of the date display unit 27 is the fourth corresponding to the upper light receiving units 30a and 30b of the third light detection unit 29, as shown in FIGS. 10 (a) and 10 (b). The light transmission unit 28 a is divided into a fourth light transmission unit 28 b corresponding to the lower light receiving units 30 c to 30 f of the third light detection unit 29. In this case, the fourth light transmitting portion 28a corresponding to the upper light receiving portions 30a and 30b of the third light detecting portion 29 is a portion representing the tenth digit of the date 10, and the lower light receiving portion 30c of the third light detecting portion 29. The fourth light transmission part 28b corresponding to ˜30f is a part representing the first digit of the date 10.

  For example, when the date 10 is “28 days”, the second digit “2” can be represented by “0010”, the first digit “8” can be represented by “1000”, and the date 10 can be represented by “10”. 14th ", the tenth digit" 1 "can be represented by" 0001 "and the first digit" 4 "can be represented by" 0100 ". Can be expressed in four divisions. For this reason, the fourth light transmitting portion 28a corresponding to the upper light receiving portions 30a and 30b of the third light detecting portion 29 is divided into two, and the fourth light receiving portions 30c to 30f corresponding to the lower light receiving portions 30c to 30f of the third light detecting portion 29 are divided. The light transmission part 28b is divided into four parts.

  Thus, for example, when the date 10 is “28th”, as shown in FIG. 10A, one of the four divided light transmitting portions 28a, that is, of the upper light receiving portions 30a and 30b, A portion corresponding to the upper light receiving portion 30a located on the left side of the figure is formed in the light shielding portion 31a, and one of the four light transmitting portions 28b divided into four, that is, among the lower light receiving portions 30c to 30f, Then, a portion corresponding to the lower light receiving portion 30c located at the left end is formed in the light shielding portion 31b.

Therefore, when “28th”, which is date 10, corresponds to the display window 9 of the dial plate 5, the external light transmitted through the fourth light transmission selection unit 28 is connected to the light shielding unit 31 a of the fourth light transmission unit 28 a. The light is shielded by the light shielding part 31b of the fourth light transmitting part 28b, passes through the other fourth light transmitting part 28a and the fourth light transmitting part 28b, and receives the upper light receiving part 30b and the lower light receiving part of the third light detecting part 29. It is understood that the date 10 is “28 days” by receiving the light at the parts 30d to 30f.

  Accordingly, the third light detection unit 29 is configured such that the fourth light transmission selection unit 28 provided in the date display unit 27 changes the light transmission state according to the date 10, and thus the fourth light transmission selection unit 28 is changed. The transmitted light is selectively received by the upper light receiving units 30a and 30b and the lower light receiving units 30c to 30f of the third light detection unit 29, so that the date 10 can be recognized according to the light receiving state of the light. Yes.

Next, with reference to the block diagram of FIG. 11, a circuit configuration of the pointer type timepiece will be described.
This circuit configuration includes a CPU (Central Processing Unit) 35 that controls the entire circuit, a ROM (Read Only Memory) 36 that stores a predetermined program, a RAM (Random Access Memory) 37 that stores processing data, and a CPU 35. And a frequency dividing circuit 39 for converting the pulse generated by the transmitting circuit 38 to an appropriate frequency (appropriate frequency for operating the CPU 35). In this case, the ROM 36 stores the time comparison data shown in FIG.

  In addition, this circuit configuration includes a timepiece movement 16 that drives and rotates the hands (hour hand 6, minute hand 7, second hand 8, and date display plate 14), and first and second solar panels 13 that receive external light and generate electric power. , 15. In this case, the first solar panel 13 includes a first light detection unit 23 corresponding to the minute hand 7 and the hour hand 6, and a second light detection unit 26 corresponding to the second hand 8. Further, the second solar panel 15 receives the light transmitted through the fourth light transmission selection unit 28 provided in the date display unit 27 of the date display plate 14 according to the date 10 and detects the date 10. A detection unit 29 is provided.

  Further, in addition to the above, this circuit configuration includes a power supply unit 40 such as a battery, an antenna 41 for receiving standard time radio waves, a detection circuit 42 for detecting received standard time radio waves, a display unit 43 for displaying time, A display driving circuit 44 for driving the display unit 43, a speaker 45 for reporting sound, a buzzer circuit 46 for driving the speaker 45, and a plurality of push button switches SW for selecting and switching various modes are provided.

Next, a second hand position detection process for detecting the position of the second hand 8 in the pointer type timepiece will be described with reference to FIG.
This second hand position detection process is a basic process for determining the second time of the second hand 8, and the time comparison data of the second is stored in the ROM 36 in advance. When the second hand position detection process starts, the CPU 35 searches all the light receiving parts 26a in the second light detection part 26 of the first solar panel 13 (step S1), receives the light, and outputs the voltage. It is determined whether there is 26a (step S2).

At this time, when the voltage is not output from all of the light receiving parts 26a, it is determined that the outside of the watch case 2 is dark, and the process returns to step S1 until the voltage is output from any of the light receiving parts 26a. Search all. When a voltage is output from any of the light receiving units 26 a in step S 2, the output light receiving unit 26 a stores the number (number) in the RAM 37 (step S 3), and the light reception stored in the RAM 37. The number of the unit 26a is compared with the time comparison data stored in the ROM 36 in advance to determine whether the number of the light receiving unit 26a that has output the voltage and the time of the second hand 8 are the same.

At this time, if the number of the light receiving unit 26a that has output the voltage and the time of the second hand 8 are the same, it is determined that the second hand 8 is correct, and this determined current time is displayed on the display unit 43 (step S40). S5) The needle position detection process is terminated. If the number of the light receiving unit 26a that has output the voltage and the time of the second hand 8 are not the same, it is determined that the second hand 8 does not match, and the second hand 8 is moved to correct the position of the second hand 8 (step S6). This needle position detection process is terminated.

Next, the hour / minute hand position detecting process for detecting the positions of the hour hand 6 and the minute hand 7 in the pointer type timepiece will be described with reference to FIG.
This hour / minute hand position detection process is a basic process for discriminating the time of the minute hand 7 and the hour hand 6, and the time comparison data of the hour / minute shown in FIG.

When the hand position detection process starts, the CPU 35 searches all the light receiving parts 24 in the first light detecting part 23 of the first solar panel 13 (step S11), receives the light, and outputs the voltage. It is determined whether there is 24 (step S12). At this time, if the hour hand 6 and the minute hand 7 are overlapped with the outside of the watch case 2 being bright, no voltage is output from all of the light receiving parts 24 because the first light detecting part 23 is not irradiated with light.

The time at this time is 0:00, 1:05, 2:10, 3:16, 4:21, 5:27, 6:32, 7:38, 8:43 9:49, 10:54, or 11:59. For this reason, it returns to step S11 and detects all the light receiving parts 24 until there is a voltage output from any of the light receiving parts 24.

  When a voltage is output from one of the light receiving units 24 in step S12, the output number (number) of the light receiving unit 24 is stored in the RAM 37 (step S13), and the light receiving stored in the RAM 37 is stored. By comparing the number of the unit 24 with the time comparison data stored in advance in the ROM 36, first, the number of the light receiving unit 24 that receives light and outputs a voltage is determined as a minute time.

At this time, the time when no voltage is output from all of the light receiving units 24 is 0:00, 1:05, 2:10, 3:16, 4:21, 5:27, and 6:00. Since it is any of 32 minutes, 7:38, 8:43, 9:49, 10:54, and 11:59, the number of the light receiving unit 24 that next received light and output a voltage. Is 0:01 if it is 1st, 1: 6 if it is 6th, 2:11 if it is 11th, and so on, if it is 55th, it will be 10:55, if it is 0th Judge that it is 0:00.

  As a result, the number of the light receiving unit 24 that receives the light and outputs the voltage after the time when the voltage is not output from all the light receiving units 24 is stored in the RAM 37 as any time zone from 0 o'clock to 11 o'clock. As a result, the time zone and the number of the light receiving unit 24 stored in the RAM 37 are compared with the time comparison data stored in the ROM 36 in advance (step S14).

If the time zone and the number of the light receiving unit 24 stored in the RAM 37 are the same as the current time in step S14, it is determined that the minute hand 7 and the hour hand are in alignment, and the determined current time is displayed on the display unit 43. Is displayed (step S15), and the needle position detection process is terminated. Further, if the time zone stored in the RAM 37 and the number of the light receiving unit 24 are not the same as the current time, it is determined that the minute hand 7 and the hour hand 6 do not match, and the minute hand 7 and the hour hand 6 are moved to move the minute hand 7, The position of the hour hand 6 is corrected (step S16), and this hand position detection process is terminated.

Next, a date detection process for detecting the date 10 in the pointer type timepiece will be described with reference to FIG.
This date detection process is a basic process for determining the date 10 displayed on the date display board 14, and date comparison data is stored in the ROM 36 in advance. When this date detection process starts, the CPU 35 searches all the light receiving units 30a to 30f in the third light detecting unit 29 of the second solar panel 15 (step S21), receives the light, and receives the voltage output. It is determined whether or not there are units 30a to 30f (step S22).

At this time, when no voltage is output from all of the light receiving units 30a to 30f, it is determined that the outside of the watch case 2 is dark, and the process returns to step S21 until a voltage is output from any of the light receiving units 30a to 30f. All of the light receiving units 30a to 30f are searched. When a voltage is output from any of the light receiving units 30a to 30f in step S22, the output light receiving state of the light receiving units 30a to 30f is stored in the RAM 37 (step S23).

In step S23, the light receiving states of the light receiving units 30a to 30f stored in the RAM 37 are compared with the numbers of the date comparison data stored in the ROM 36 in advance, and the light receiving states of the light receiving units 30a to 30f that output the voltage are compared. It is determined whether or not the date contrast data is the same (step S24). For example, when “28th” which is the date 10 corresponds to the display window portion 9 of the dial plate 5, the external light transmitted through the fourth light transmission selection unit 28 is connected to the light shielding unit 31 a of the fourth light transmission unit 28 a and The light is shielded by the light shielding part 31b of the four light transmitting part 28b, passes through the other fourth light transmitting part 28a and the fourth light transmitting part 28b, and the upper light receiving part 30b and the lower light receiving part of the third light detecting part 29. By receiving light at 30d to 30f, it can be seen that the date 10 is "28 days".

At this time, if the light receiving states of the light receiving units 30a to 30f that output the voltage are the same as the date comparison data, it is determined that the date 10 is correct, and the determined current date is displayed on the display unit 43. (Step S25) and the date detection process is terminated. If the light receiving states of the light receiving units 30a to 30f that output the voltage are not the same as the date comparison data, it is determined that the date 10 is not correct, and the date 10 is rotated by rotating the date display board 14 (step 10). S26), this date detection process is terminated.

Thus, according to this pointer-type timepiece, the second hand 8 having the third light transmitting portion 25b and the light receiving portion disposed on the lower side of the second hand 8 along the movement locus of the third light transmitting portion 25b. A plurality of light receiving parts 26a selectively receive light transmitted through the first solar panel 13 having the second light detection part 26 into which a part 26a is divided and the third light transmission part 25b of the second hand 8, and the light And determining means (CPU 35) for determining the position of the second hand 8 in accordance with the light receiving position of the first hand, so that the CPU 35 sets the position of the second hand 8 in accordance with the light receiving position at which the plurality of light receiving portions 26a selectively receive light. The position of the second hand 8 can be determined accurately and reliably in real time.

In addition, according to the pointer type timepiece, the minute hand 7 having the first light transmitting portion 21b and the hour hand 6 having the second light transmitting portion 22a are disposed below the minute hand 7 and the hour hand 6, and the first, first The first solar panel 13 having the first light detection unit 23 in which the light receiving unit 24 is divided into a plurality along the movement locus of each of the two light transmission units 21b and 22a, and the first and first of the minute hand 7 and the hour hand 6 When the plurality of light receiving parts 24 selectively receive the light transmitted through the two light transmitting parts 21b and 22a, the judging means (CPU 35) judges the positions of the minute hand 7 and the hour hand 6 according to the light receiving state of the light. ) Can be determined in real time.

That is, in this hand position detecting device in the pointer type timepiece, the first light provided in the first solar panel 13 with the light transmitted through the first and second light transmitting portions 21b and 22a of the minute hand 7 and the hour hand 6 is provided. When the plurality of light receiving sections 24 in the detection section 23 selectively receive light, the positions of the minute hand 7 and the hour hand 6 can be easily determined by the CPU 35 according to the light receiving state of the light, and therefore the minute hand 7 in real time. And the position of the hour hand 6 can be accurately and reliably determined.

In this case, the first and second light transmitting portions 21 b and 22 a of the minute hand 7 and hour hand 6 and the first light detecting portion 23 of the first solar panel 13 are in the vicinity of the pointer shaft 18 of the minute hand 7 and hour hand 6. By being provided, the first and second light transmitting portions 21b and 22a of the minute hand 7 and hour hand 6 and the first light detecting portion 23 of the first solar panel 13 can be brought close to the rotation center. Therefore, the positions of the minute hand 7 and the hour hand can be accurately determined.

Further, in the second hand 8 as well as the minute hand 7 and the hour hand 6, the third light transmitting portion 25b and the second light detecting portion 26 of the first solar panel 13 are provided in the vicinity of the second hand shaft 20, The third light transmission part 25b of the second hand 8 and the second light detection part 26 of the first solar panel 13 can be brought close to the center of rotation, thereby enabling a compact configuration and accurately positioning the second hand 8. Can judge

In addition, according to the date detection device in the pointer type timepiece, the fourth light transmission selection unit in which the light transmission state is different for each date 10 is displayed on each date display unit 27 in which the date 10 is sequentially displayed along the circumference. A date display board 14 provided with 28, a dial 5 having a display window 9 disposed on the upper side of the date display board 14 and corresponding to any of the date display sections 27, and a lower side of the date display board 14. Corresponding to the display window portion 9 and the second solar panel 15 having the third light detection portion 29 in which the light receiving portions 30a to 30f are divided into a plurality of portions. When the plurality of light receiving units 30a to 30f receive the light transmitted through the fourth light transmission selection unit 28 of any date display unit 27 according to the light transmission state of the fourth light transmission selection unit 28, Judgment means for judging the date 10 according to the light receiving state ( It is provided with the PU35) and can be simply and easily determine the date 10 corresponding to the display window 9.

  That is, in this date detection device, the third light detection unit 29 of the second solar panel 15 includes two upper light receiving units 30 a and 30 b provided on the upper side of the date display unit 27 and the lower side of the date display unit 27. Are divided into four lower light receiving units 30c to 30f, the upper light receiving units 30a and 30b correspond to the 10th digit of the date 10, and the lower light receiving units 30c to 30f correspond to the first digit of the date 10. The fourth light transmission selection unit 28 of the date display unit 27 is divided into a fourth light transmission unit 28a corresponding to the upper light receiving units 30a and 30b and a fourth light transmission unit 28b corresponding to the lower light receiving units 30c to 30f. Since the fourth light transmission part 28a represents the tenth digit of the date 10 and the fourth light transmission part 28b represents the first digit of the date 10, the fourth light transmission parts 28a, 28b of the date display part 27 represent the date 10. Depending on the light transmission state. Ri, by receiving light of different the transmission state by the light receiving portion 30a~30f of the third light detector 29, it is possible to accurately and reliably determine the date 10 in accordance with a light receiving state of the light.

(Embodiment 2)
Next, a second embodiment of the pointer type timepiece to which the invention is applied will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected and demonstrated to the same part as Embodiment 1 shown by FIGS.
This pointer-type timepiece is different from the first embodiment in the first light transmission selection unit 50 of the minute hand 7, the second light transmission selection unit 51 of the hour hand 6, and the first light detection unit 52 of the first solar panel 13. The configuration is the same as that of the first embodiment except for this.

  That is, as shown in FIGS. 17A to 17C, the first light detection unit 52 of the first solar panel 13 is positioned in the vicinity of the pointer shaft 18 and the inner ring unit positioned on the center side. And a double ring shape having an outer ring portion located on the outer peripheral side thereof. In this case, as shown in FIGS. 17 (a) and 17 (b), the first light receiving portion 52a is divided into 60 equal parts and formed on the ring portion on the center side. As shown in FIGS. 17A and 17C, the second light receiving portion 52b is divided into 12 equal parts.

As shown in FIG. 16A, the first light transmission selection unit 50 of the minute hand 7 is a part of the first light-shielding unit 50a corresponding to the ring portion on the center side in the first light detection unit 52, that is, A first light transmitting portion 50 b is provided at a position corresponding to the tip portion (upper end portion in the figure), and this first light transmitting portion 50 b corresponds to any one first light receiving portion 52 a of the first light detecting portion 52. It is formed to do.

Further, as shown in FIG. 16B, the second light transmission selection unit 51 of the hour hand 6 is a part of the second light shielding unit 51a corresponding to the ring portion on the outer peripheral side in the first light detection unit 52, that is, the hour hand. 6 is provided at a position corresponding to the tip end portion (upper end portion in FIG. 6), and the second light transmission portion 51b is a second light receiving portion 52b of any one of the first light detection portions 52. It is formed to correspond to.

  Accordingly, as shown in FIGS. 16 and 17, the first light detection unit 52 is caused by the light transmitted through the first light transmission unit 50b of the minute hand 7 being applied to any one of the first light reception units 52a. By generating electric power, the minute time is determined, and light transmitted through the second light transmitting portion 51b of the hour hand 6 is irradiated to any one of the second light receiving portions 52b to generate an electromotive force. It is configured to determine the time.

That is, as shown in FIG. 18, the first light detection unit 52 generates an electromotive force when the light transmitted through the second light transmission unit 51 b of the hour hand 6 is irradiated first in the second light reception unit 52 b. If it is determined that it is the 1 o'clock time zone, and the light transmitted through the second light transmitting portion 51b is irradiated secondly from the second light receiving portion 52b to generate an electromotive force, it is determined that it is the 2 o'clock time zone. Similarly, when the light transmitted through the second light transmitting portion 51b is irradiated to the 12th light of the second light receiving portion 52b to generate an electromotive force, it is determined that the time zone is 12 o'clock (0 o'clock).

  Further, as shown in FIG. 18, the first light detection unit 52 generates an electromotive force when the light transmitted through the first light transmission unit 50b of the minute hand 6 is irradiated first in the first light reception unit 52a. It is determined that it is 1 minute, and when the light transmitted through the first light transmitting unit 50b is irradiated secondly from the first light receiving unit 52a to generate an electromotive force, it is determined that it is 2 minutes, and so on. When the light transmitted through the one light transmitting portion 50b is irradiated to the 59th light of the first light receiving portion 52a to generate an electromotive force, it is determined that it is 59 minutes.

Next, referring to FIG. 19, a description will be given of a hand position detection process for detecting the positions of the minute hand 7 and the hour hand 6 in the pointer type timepiece.
This hand position detection process is a process for detecting the positions of the hour hand 6 and the minute hand 7, and the time comparison data for the hour shown in FIG. When the hand position detection process starts, the CPU 35 searches all the first light receiving parts 52a in the first light detecting part 52 of the first solar panel 13 (step S31), and the light transmitted through the first light transmitting part 50b. It is determined whether or not there is a first light receiving portion 52a that receives the voltage and outputs a voltage (step S32).

At this time, if no voltage is output from all of the first light receiving parts 52a, it is determined that the outside of the watch case 2 is dark, and the process returns to step S31 until the voltage is output from any of the first light receiving parts 52a. All the detection of one light receiving part 52a is repeated. If any of the first light receiving parts 52a receives the light transmitted through the first light transmitting part 50b and outputs a voltage in step S32, the number of the first light receiving part 52a (whatever ) Is stored in the RAM 37 (step S33), and the current minute time is determined by comparing the number of the first light receiving unit 52a stored in the RAM 37 with the time comparison data of the ROM 36 (step S34).

That is, when a voltage is output from the first first light receiving unit 52a in step S32, by comparing the output number of the first first light receiving unit 52a with the time comparison data of the ROM 36, When it is determined that the current minute time is 1 minute and a voltage is output from the 12th first light receiving unit 52a, the number of the output 12th first light receiving unit 52a and the time of the ROM 36 are output. By comparing the comparison data, it is determined that the current minute time is 12 minutes.

  Then, all the second light receiving parts 52b in the first light detecting part 52 of the first solar panel 13 are searched (step S35), the light transmitted through the second light transmitting part 51b is received, and the voltage is output. It is determined whether or not there is the two light receiving parts 52b (step S36). At this time, when the voltage is not output from all of the second light receiving parts 52b, the process returns to step S35 and the detection of all of the second light receiving parts 52b is repeated until a voltage is output from any of the second light receiving parts 52b.

If any of the second light receiving parts 52b receives the light transmitted through the second light transmitting part 51b and outputs a voltage in step S36, the number of the output second light receiving part 52b (whatever The second time) is stored in the RAM 37 (step S37), and the current time is determined by comparing the number of the second light receiving unit 52b stored in the RAM 37 with the time comparison data of the ROM 36 (step S38).

That is, when a voltage is output from the first second light receiving unit 52b in step S36, by comparing the output number of the first second light receiving unit 52b with the time comparison data of the ROM 36, It is determined that the current time is 1 o'clock. In step S36, when the sixth second light receiving unit 52b receives the light transmitted through the second light transmitting unit 51b and outputs a voltage, the output of the output sixth second light receiving unit 52b. By comparing the number with the time comparison data in the ROM 36, it is determined that the current time is 6 o'clock.

Then, it is determined whether or not the numbers of the first and second light receiving portions 52a and 52b stored in the RAM 37 are the same as the time comparison data in the ROM 36 (step S38). Then, it is determined that the hour hand 6 is correct and displayed on the display unit 43 (step S40), and this date detection process is terminated. If the numbers of the first and second light receiving portions 52a and 52b stored in the RAM 37 and the time comparison data in the ROM 36 are not the same, it is determined that the minute hand 7 and the hour hand 6 do not match, The hour hand 6 is moved to correct the minute hand 7 and the hour hand 6 (step S41), and this hand position detection process is terminated.

  Thus, according to this pointer-type timepiece, the same effects as in the first embodiment are obtained, and the first and second light beams provided on the different rotation trajectories of the minute hand 7 and the hour hand 6 are provided. 1st light-receiving part provided with the transmission parts 50b and 51b, and the 1st light detection part 52 of the 1st solar panel 13 divided | segmented into plurality corresponding to the rotation locus | trajectory of the 1st light transmission part 50b of the minute hand 7 52a and the second light receiving part 52b divided into a plurality of parts corresponding to the rotation trajectory of the second light transmitting part 51b of the hour hand 7, the minute hand 7, the first and second of the hour hand 6 are provided. The light transmitted through the light transmitting parts 50b and 51b is selectively received by the first and second light receiving parts 52a and 52b in the first light detecting part 52 of the first solar panel 13, thereby receiving the light. The CPU 35 can easily determine the position of the minute hand 7 and the hour hand 6 according to the state. It can, thereby determining the position of the pointer in real time.

  That is, in this hand position detecting device, the light that has passed through the first light transmitting portion 50b of the minute hand 7 is received by the first light receiving portion 52a divided into 60 equal parts of the first detecting portion 52, whereby the current minute time is determined. The CPU 35 can promptly determine the current time by receiving the light transmitted through the second light transmitting portion 51b of the hour hand 6 by the second light receiving portion 52b divided into 12 equal parts of the first detecting portion 52. The CPU 35 can quickly determine the time. For this reason, since the minute time and the hour time can be individually compared with the time comparison data, the minute time and the hour time can be easily determined, thereby easily and accurately determining the current time in real time. Can be determined.

(Embodiment 3)
Next, a third embodiment of the pointer type timepiece to which the invention is applied will be described with reference to FIGS. Also in this case, the same portions as those in the first embodiment shown in FIGS.
This pointer-type timepiece has a three-needle type structure in which an hour hand 6, a minute hand 7 and a second hand 8 are attached to a pointer shaft 18, a first light transmission selection unit 60 is provided on the second hand 8, and a second light transmission selection is performed on the minute hand 7. The portion 61 is provided, the third light transmission selection portion 62 is provided on the hour hand 6, and the first light detection portion 63 is provided on the first solar panel 13, and the other configurations are substantially the same as those in the first embodiment. .

  That is, as shown in FIGS. 22A to 22D, the first light detection unit 63 of the first solar panel 13 is located in the vicinity of the pointer shaft 18 and located on the center side. And a third ring part having a second ring part located on the outer peripheral side and a third ring part located further on the outer peripheral side of the second ring part. In this case, the first light receiving part 63a is divided into 60 equal parts in the first ring part on the center side, and the second light receiving part 63b is also divided into 60 equal parts in the second ring part. In the third ring portion, a third light receiving portion 63c is divided into 12 equal parts.

  As shown in FIGS. 20 and 21B, the first light transmission selection unit 60 of the second hand 8 is a part of the first light shielding unit 60a corresponding to the first ring unit on the center side in the first light detection unit 63. In other words, the first light transmission part 60 b is provided at a position corresponding to the tip part (the upper end part in the figure) of the second hand 8, and the first light transmission part 60 b of the first light detection part 63 a of the first light detection part 63 is provided. It is formed to correspond to either one.

Further, the second light transmission selection unit 61 of the minute hand 7 is, as shown in FIGS. 20 and 21C, a part of the second light shielding unit 61a corresponding to the second ring unit in the first light detection unit 63, That is, the second light transmission part 621b is provided at a position corresponding to the tip part (the upper end part in the figure) of the minute hand 7, and this second light transmission part 61b is one of the second light receiving parts 63b of the first light detection part 63. It is formed to correspond to one.

Further, the third light transmission selection unit 62 of the hour hand 6 includes a part of the third light shielding unit 62a corresponding to the third ring unit in the first light detection unit 63, as shown in FIGS. That is, the third light transmitting portion 62b is provided at a position corresponding to the tip portion (the upper end portion in the figure) of the hour hand 6, and this third light transmitting portion 62b is one of the third light receiving portions 63c of the first light detecting portion 63. It is formed to correspond to one.

  As a result, as shown in FIGS. 21 and 22, the first light detection unit 63 is caused by the light transmitted through the first light transmission unit 60b of the second hand 8 being applied to one of the first light reception units 63a. By generating electric power, the second time is determined, and light transmitted through the second light transmitting portion 61b of the minute hand 7 is irradiated to any one of the second light receiving portions 63b to generate an electromotive force. The time is determined, and the light transmitted through the third light transmitting portion 62b of the hour hand 6 is irradiated on any one of the third light receiving portions 63c to generate an electromotive force, thereby determining the time and time. ing.

That is, the first light detection unit 63 is in a time zone of 1 o'clock when the light transmitted through the third light transmission unit 62b of the hour hand 6 is irradiated to the first light of the third light reception unit 63c to generate an electromotive force. If the light transmitted through the third light transmitting portion 62b is irradiated secondly from the third light receiving portion 63c to generate an electromotive force, it is determined that it is a time zone of 2 o'clock, and so on. When the light transmitted through the light transmitting part 62b is irradiated to the 12th light of the third light receiving part 63c to generate an electromotive force, it is determined that the time zone is 12 o'clock (0 o'clock).

  Further, the first light detection unit 63 determines that it is 1 minute when the light transmitted through the second light transmission unit 61b of the minute hand 7 is irradiated to the first light of the second light reception unit 63b to generate an electromotive force. When the light transmitted through the second light transmitting portion 61b is irradiated secondly from the second light receiving portion 63b to generate an electromotive force, it is determined that it is 2 minutes, and similarly, the light is transmitted through the second light transmitting portion 61b. When the generated light is applied to the 59th light of the second light receiving unit 63b to generate an electromotive force, it is determined that it is 59 minutes.

  Further, the first light detection unit 63 determines that it is 1 second when the light transmitted through the first light transmission unit 60b of the second hand 8 is irradiated to the first light of the first light reception unit 63a to generate an electromotive force. When the light transmitted through the first light transmitting unit 60b is irradiated secondly from the first light receiving unit 63a to generate an electromotive force, it is determined that it is 2 seconds, and similarly, the light is transmitted through the first light transmitting unit 60b. When the generated light is applied to the 59th light of the first light receiving unit 63a to generate an electromotive force, it is determined that it is 59 seconds.

  Thus, also in this hand position detection device, the light transmitted through the first to third light transmitting portions 60b to 62b of the second hand 8, the minute hand 7, and the hour hand 6 is the same as in the first and second embodiments. The first to third light receiving parts 63a to 63c in the first light detecting part 63 of the panel 13 selectively receive light, whereby the position of the second hand 8, the minute hand 7, and the hour hand 6 according to the light receiving state of the light. Thus, the position of the pointer can be determined in real time.

  That is, in this hand position detecting device, the light transmitted through the first light transmitting portion 60b of the second hand 8 is received by the first light receiving portion 63a divided into 60 equal parts of the first detecting portion 63, so that the current second time is obtained. It is possible to determine the current minute time by receiving the light transmitted through the second light transmitting portion 61b of the minute hand 7 with the second light receiving portion 63b divided into 60 equal parts of the first detecting portion 63. The current time can be determined by receiving the light transmitted through the third light transmitting portion 62b of the hour hand 6 with the third light receiving portion 63c of the first detecting portion 63 divided into 12 equal parts. it can.

For this reason, the second time, the minute time, and the hour time can be individually compared with the time comparison data, so the second time, the minute time, and the hour time can be easily determined. It can be easily and accurately determined.

In the first to third embodiments, the case where the present invention is applied to a pointer-type timepiece has been described. However, the present invention is not necessarily a timepiece, and can be widely applied to instruments such as a meter.

1 is an enlarged front view showing Embodiment 1 of a timepiece module in a pointer-type timepiece to which the invention is applied. FIG. 2 is an enlarged cross-sectional view illustrating a state in which the timepiece module of FIG. 2 shows the minute hand, hour hand, and first light detection portion of the first solar panel of FIG. 2, (a) is an enlarged front view of the minute hand, (b) is an enlarged front view of the hour hand, and (c) is the first light detection. It is an enlarged front view of a part. It is the expanded sectional view which showed the principal part in the dial plate of FIG. 2, and a 1st solar panel. It is the front view which expanded and showed the 1st photon detection part of FIG.3 (c) further. FIG. 3 shows the operating state of the minute hand and hour hand shown in FIG. 3, (a) is a front view showing a state in which the minute hand and hour hand are overlapped, and (b) shows a state in which the minute hand and hour hand are displaced from each other. FIG. The second hand of FIG. 2 and the 2nd light detection part of a 1st solar panel are shown, (a) is an enlarged front view of the second hand, (b) is an enlarged front view of a 2nd light detection part. It is the enlarged front view which showed the date display board of FIG. It is the enlarged front view which showed the 2nd solar panel of FIG. The date display part of the date display board corresponding to the display window part of the dial plate of FIG. 1 is shown, (a) is the enlarged front view of the date display part, (b) is the 2nd solar panel corresponding to this date display part. It is the enlarged front view which showed the 2nd light detection part. FIG. 2 is a block diagram illustrating a circuit configuration of the timepiece of FIG. 1. FIG. 6 is a table showing a correspondence relationship from 0:00 to 11:59 in the relationship between the light reception state by the first light detection unit of FIG. 5 and the current time. FIG. 12 is a diagram illustrating a flow of second hand position detection processing in the circuit configuration of FIG. 11. It is the figure which showed the flow of the hour / minute hand position detection process in the circuit configuration of FIG. It is the figure which showed the flow of the date detection process in the circuit structure of FIG. In the second embodiment in which the present invention is applied to a pointer type timepiece, a minute hand and an hour hand are shown, (a) is an enlarged front view of the minute hand, and (b) is an enlarged front view of the hour hand. FIG. 16 shows a first light detection portion of the first solar panel corresponding to the minute hand and hour hand of FIG. 16, (a) is an enlarged front view showing the first light detection portion, and (b) is a view of the first light detection portion. The enlarged front view which showed the 1st light-receiving part, (c) is the enlarged front view which showed the 2nd light-receiving part of the 1st light detection part. It is the figure which showed the relationship between the light reception state by the 1st light detection part of FIG. 17, and the present time with a table | surface. It is the figure which showed the operation | movement flow of the needle | hook position detection process in FIG. 16 and FIG. FIG. 6 is an enlarged front view of a timepiece module according to a third embodiment in which the present invention is applied to a pointer type timepiece. The second hand, the minute hand, and the hour hand of FIG. 20 are shown, (a) is an enlarged front view of the second hand, (b) is an enlarged front view of the minute hand, and (c) is an enlarged front view of the hour hand. FIG. 20 shows a first light detection portion of the first solar panel corresponding to the second hand, the minute hand, and the hour hand of FIG. 20, (a) is an enlarged front view, (b) is an enlarged front view showing the first light receiving portion, c) is an enlarged front view showing the second light receiving portion, and (d) is an enlarged front view showing the third light receiving portion.

Explanation of symbols

1 Clock Module 5 Dial 6 Hour Hand 7 Minute Hand 8 Second Hand 9 Display Window 10 Date 13 First Solar Panel 14 Date Display Board 15 Second Solar Panel 16 Clock Movement 18 Pointer Shaft 20 Second Hand Axis 21, 50, 60 First Light Transmission Selection part 21a, 50a, 60a 1st light shielding part 21b, 50b, 60b 1st light transmission part 22, 51, 61 2nd light transmission selection part 22a, 51b, 61b 2nd light transmission part 22b, 51a, 61a 2nd light shielding Units 23, 52, 63 First light detection unit 24, 26a, 30a-30f Light reception unit 25, 62 Third light transmission selection unit 25a, 62a Third light transmission unit 25b, 62b Third light transmission unit 26 Second light detection unit 27 Date display section 28 Fourth light transmission selection section 28a, 28b Third light transmission section 29 Third light detection section 35 CPU
52a, 63a 1st light-receiving part 52b, 63b 2nd light-receiving part 63c 3rd light-receiving part

Claims (5)

A pointer that has a light transmission part and rotates around the pointer axis;
A solar panel having a light detection unit arranged below the pointer and divided into a plurality of light receiving units along the movement trajectory of the light transmission unit,
A needle position comprising: a light receiving portion selectively receiving light transmitted through the light transmitting portion, and determining means for determining a position of the pointer according to a light receiving state of the light Detection device.   The needle position detecting device according to claim 1, wherein the light transmitting portion of the pointer and the light detecting portion of the solar panel are provided in the vicinity of the pointer shaft. The pointer has at least a minute hand and an hour hand, and at least the minute hand and the hour hand are respectively provided with the light transmission portions on mutually different rotation trajectories,
The light detecting unit of the solar panel corresponds to a first light receiving unit divided into a plurality corresponding to a rotation locus of the light transmitting portion of the minute hand and a rotation locus of the light transmitting portion of the hour hand. The needle position detecting device according to claim 1, further comprising a second light receiving portion divided into a plurality of portions. A display rotator provided with each light transmission portion having a different light transmission state on each display portion in which dates are sequentially displayed along the circumference;
A dial having a display window portion arranged on the upper side of the display rotator and corresponding to any one of the display portions;
A solar panel having a light detection unit disposed below the display rotator in correspondence with the display window of the dial and having a light receiving unit divided into a plurality of portions;
The plurality of light receiving portions receive light transmitted through the light transmitting portion of any one of the display portions corresponding to the display window portion according to the light transmitting state of each light transmitting portion, and the light receiving state is A date detecting device comprising: a determination unit configured to determine the date in response. A moving body having a light transmission portion;
A solar panel having a light detection unit arranged on the lower side of the moving body and divided into a plurality of light receiving units along the movement trajectory of the light transmission unit;
A plurality of light-receiving units that selectively receive light transmitted through the light-transmitting unit, and a determination unit that determines a position of the moving body according to a light-receiving state of the light. Body position detection device.

Images