Timepiece and method of controlling a timepiece.

专利摘要:
The object of the invention is to provide a timepiece and a control method of a timepiece, which allow the driving of an indicator needle with a low power consumed even if the timepiece requires a high speed treatment. The timepiece (1), according to the invention in which an indicator needle (60) is driven by a motor (48) and a high speed processing is required to drive a load other than the indicator needle, comprises a main control circuit (204) which gives the moment of activation of the motor for driving the load and which is actuated by an operating frequency acting as a first frequency, and an engine control unit (40) which generates a driving pulse to activate the motor and which is actuated by an operating frequency acting as a second frequency which is lower than the first frequency.
公开号:CH713092A2
申请号:CH01274/17
申请日:2017-10-18
公开日:2018-04-30
发明作者:Kato Kazuo
申请人:Seiko Instr Inc；
IPC主号:

专利说明:

Description TECHNICAL FIELD [0001] The present invention relates to a timepiece and a method for controlling a timepiece.
PRIOR ART [0002] In recent years, an electronic timepiece with an analogue display has been proposed, constituted so as to include an engine control circuit and a processor (also called a central processing unit) intended to control the motor control circuit. For example, patent document 1 discloses an architecture in which a central processor controls a motor driven indicator needle control circuit. In addition to the motor driven indicator needle control circuit, the central processor also controls an input control circuit.
In addition, in recent years, there is a timepiece that transmits and receives information by communicating with a mobile terminal such as a smartphone or communicating with a satellite such as a satellite (GPS) . Thus, in recent years, the objects controlled by a processor have increased, as well as there has been an increase in the functions of the processors.
Patent Document 1: JP-T-2012-516 996 Summary of the Invention
Problem that the invention intends to solve [0004] However, in the related prior art, in the case where the timepiece is transformed into an electronic terminal for communicating with a smartphone, the necessary processing time increases and the number of objects to be processed increases, resulting in a heavy processing load. In the case where the timepiece thus converted into an electronic terminal requires high speed processing during the heavy processing load, the current consumption tends to increase due to the high speed processing of the processor. Therefore, in the related prior art, even if the processor is intended to maneuver the needles as in the past, the power consumed has increased due to other processing tasks of the processor.
The present invention has been made in view of the problem described above and an object of this invention is to provide a timepiece and a control method of a timepiece, which allow the training of an indicator needle with a low power consumed even if the timepiece requires treatment at high speed.
Means for solving the problem [0006] In order to achieve the above purpose, a timepiece (electronic device 1, 1A, 1B) according to one aspect of the invention, wherein an indicator needle (60) is driven by a motor (48) and a high speed processing is required to drive a load other than the indicator hand, includes a main control circuit (204, 204B) which gives the moment of activation of the motor to drive the load. and which is driven by an operating frequency acting as a first frequency, as well as a motor control unit (engine control unit 40, engine control unit 40B) which generates a driving pulse for activate the motor and which is actuated by an operating frequency acting as second frequency which is lower than the first frequency.
For example, the load other than the indicator hand is a display driving circuit and a communication circuit. In addition, the first frequency is, for example, 100 MHz. The second frequency is, for example, 32 kHz.
In addition, in the timepiece according to the aspect of the present invention, a clock signal forming the base of the first frequency and a clock signal forming the base of the second frequency can be desynchronized. one with respect to the other.
In addition, in the timepiece according to the aspect of the present invention, on the basis of the first frequency, the main control circuit can emit an instruction signal indicating the moment of activation of the motor. , to the engine control unit. Based on the first frequency, the main control circuit may output a timing definition signal provided to define the time that allows the instruction signal to be applied to the motor control unit. The motor control unit may generate the driving pulse, based on the second frequency, at the time selected in response to the instruction signal.
For example, the instant definition signal is a GATE hold signal. In addition, the first level is, for example, a high level or a low level. The second level is a high level in the case where the first level is a low level, while it is a low level in the case where the first level is a high level.
In addition, in the timepiece according to the aspect of the present invention, the instruction signal may comprise an instruction pulse. The motor control unit may include a determining circuit (normal / inverse rotation determining circuit 45, needle operation class determining circuit 451) which counts the number of received instruction pulses included in the signal method while receiving the instant definition signal, and which determines at least two types of needle actuation class to actuate the indicator hand by means of the motor, in response to the number of instruction pulses. . Based on a result determined by the determining circuit, the motor control unit can actuate the indicator needle by means of the motor, in response to the needle actuation class.
In addition, in the timepiece according to the aspect of the present invention, the instruction signal can be configured to include the instruction pulses, the number of which varies according to the class of needle actuation, for a duration of the instant definition signal, whenever two or more types of operation are performed.
In addition, in the timepiece according to the aspect of the present invention, the main control circuit can change the level of the instant definition signal from a first level to a second level. . After passing the instant definition signal to the second level, the main control circuit can change the level of the instruction signal from the first level to the second level. After passing the instruction signal to the second level, the main control circuit can pass the instruction signal to the first level. After passing the instruction signal to the first level, the main control circuit can move the instant definition signal from the second level to the first level.
In addition, in the timepiece according to the aspect of the present invention, the class of needle operation may include at least one type of a first type in which the indicator needle is made to perform a first actuation by means of the motor, a second type in which the indicator needle is made to perform a second actuation different from the first actuation by means of the motor, a third type in which the indicator needle is made to perform a third actuation different from the first. actuation and second actuation by means of the motor, and a fourth type in which the indicator needle is made to perform a fourth actuation different from the first actuation, the second actuation and the third actuation by means of the motor.
In addition, in the timepiece according to the aspect of the present invention, the first type may be an actuation intended to cause the indicator needle to perform a normal rotation by means of the motor, and the number of signals instruction is equal to 1 while the instant definition signal is received. The second type may be an actuation intended to cause the indicator hand to reverse rotation by means of the motor, and the number of the instruction signals to be 2 while the instant setting signal is received. The third type may be an actuation intended to cause the indicator needle to be actuated by means of the motor so as to indicate a reduced battery voltage to a user when the voltage value of a battery supplying the timepiece is small, and the number of the instruction signals is 3 while the instant setting signal is received. The fourth type may be an actuation to cause the indicator hand to operate differently from that which occurs when the time is displayed by the motor, and the number of the instruction signals is 4 while the signal instant definition is received.
In addition, in the timepiece according to the aspect of the present invention, the motor may comprise a first motor for driving a first indicator needle, and a second motor for driving a second indicator needle. The main control circuit can change the level of the instant definition signal from a first level to a second level. After passing the instant definition signal to the second level, the main control circuit can cause the level of a first instruction signal to be set to specify the activation of the first motor and the level of a second signal. instruction to specify activation of the second engine, from a first level to a second level. After passing the first instruction signal and the second instruction signal to the second level, the main control circuit can pass the first instruction signal and the second instruction signal to the first level. After passing the first instruction signal and the second instruction signal at the first level, the main control circuit can cause the instant definition signal from the second level to the first level.
In addition, in the timepiece according to the aspect of the present invention, the indicator hand can indicate the time.
In addition, in the timepiece according to the aspect of the present invention, the number of transmission lines through which the instruction signal passes to give instructions to the motor to drive the indicator needle to generate the driving pulse can be the same as the number of engines. The number of signals addressed to the main control unit for controlling the motor, including the instruction signal, can be obtained by adding one to the number of the motors.
In order to achieve the above purpose, a method of controlling a timepiece according to one aspect of the present invention, wherein an indicator needle is driven by a motor and a high speed processing is required to drive a load other than the indicator needle, comprises a step which is actuated by an operating frequency acting as a first frequency, and in which a main control circuit for driving the load emits the moment of driving of the motor, and a step wherein a motor control unit operated by an operating frequency acting as a second frequency which is lower than the first frequency generates a driving pulse to activate the motor. The step of specifying the piloting time comprises a step of passing the level of an expected time definition signal to define the moment of driving the engine from a first level to a second level, on the basis of a rate of the first frequency, a step of passing the level of an intended instruction signal to specify the control of the motor from a first level to a second level, after passing the signal of second-level time definition, a step of passing the instruction signal to the first level, after passing the instruction signal to the second level, and a step of passing the time-defining signal. from the second level to the first level, after passing the instruction signal to the first level.
In addition, the control method of a timepiece according to one aspect of the present invention may further comprise a step in which the engine control unit counts the number of instruction pulses present in the instruction signal during a period during which the instant definition signal is at the second level, and a step in which the motor control unit determines, from the number of steps counted, a class of needle actuator provided for actuation of the indicator needle by means of the motor, and generates, according to the determined needle actuation class, a driving pulse provided for driving the motor.
Advantages of the invention [0021] According to the present invention, an indicator needle can be driven with a low power consumption even if the timepiece requires high speed processing.
Brief description of the drawings [0022]
Fig. 1 is a block diagram showing an exemplary architecture of an electronic device according to a first embodiment.
Fig. 2 is a view showing an example in which a charging terminal, a charge control circuit, an auxiliary battery, a main control unit and a support body are arranged on a base according to a first embodiment.
Fig. 3 is a view showing an exemplary chronology of a GATE hold signal, an instruction signal (MOFR), a drive pulse, and a RDYB signal, according to the first embodiment.
Fig. 4 is a view showing an exemplary chronology of a GATE hold signal, instruction signals (MOFR and M1FR), a drive pulse and a RDYB signal, according to the first embodiment.
Fig. 5 is a view for describing a period of operation of a main control circuit according to the first embodiment.
Fig. 6 is a block diagram of a process taking place when the main control circuit according to the first embodiment outputs the instruction signal.
Fig. 7 is a block diagram of a method of a motor control unit when the instruction signal according to the first embodiment is received.
Fig. 8 is a block diagram of a method of a main control circuit which according to a comparative example does not use the GATE hold signal.
Fig. 9 is a block diagram showing an exemplary configuration of an electronic device according to a second embodiment.
Fig. 10 is a block diagram showing an exemplary configuration of an electronic device according to a third embodiment.
Fig. 11 is a view showing an example of each of a plurality of instruction signals ranging from a first type needle actuation to a fourth type needle actuation, according to the third embodiment.
Fig. 12 is a view showing each signal example in the third type needle actuation according to the third embodiment.
Fig. 13 is a view showing each signal example in the fourth type needle actuation according to the third embodiment.
Fig. 14 is a block diagram of a method of a motor control unit when an instruction signal according to the third embodiment is received.
BEST MODE FOR CARRYING OUT THE INVENTION [0023] In the following, embodiments of the present invention will be described with reference to the drawings. A timepiece according to the embodiments is an electronic device such as a timepiece with an analogue display, a smart watch and a portable terminal which have an indicator needle. Hereinafter, in the embodiments, the example described is that in which the timepiece is an electronic device such as a smart watch.
First Embodiment [0024] FIG. 1 is a block diagram showing an exemplary architecture of an electronic device 1 according to a first embodiment.
As shown in FIG. 1, the electronic device 1 comprises a charging terminal 11, a charging control circuit 12, an auxiliary battery 13, a switch SW, a main control unit 20, a support body 50, a first indicator needle 60, a second indicator hand 60B, a third indicator hand 60C, a display unit 70, an operation unit 75, a sensor 80 and an alarm 85. When it is not specified whether it is the first indicator needle 60A, the second indicator hand 60B or the third indicator hand 60C, all of which are collectively called an indicator hand 60.
The main control unit 20 comprises a crystal oscillator 201, an oscillator circuit 202, a frequency divider circuit 203, a main control circuit 204, a display driver 205 and a driver circuit. For example, a load other than the indicator hand is constituted by the display driver 205 and the communication circuit 206.
A crystal oscillator 30, a motor control unit 40, a first motor 48A, a second motor 48B, a third motor 48C, a wheel 49A, a wheel 49B and a wheel 49C are attached to the main body 50. When it is not specified whether it is the first motor 48A, the second motor 48B or the third motor 48C, all of these are collectively called a motor 48. Moreover, when it is not It is not specified whether it is the gear train 49A, the gear train 49B or the gear train 49C, all of which are collectively a gear train 49. The support body 50 is removably attached to the electronic device 1 and is handled in as a semi-finished product or intermediate product in the case where the electronic device 1 is a finished product. However, the constitution is not limited to that.
The control control unit 40 comprises a voltage-reducing circuit 41, an input control circuit 42, an oscillator circuit 43, a frequency divider circuit 44, a normal rotation determination circuit. inverse 45 (determining circuit), a driving pulse generation circuit 46 and a driving circuit 47. In addition, the normal / inverse rotation determining circuit 45 comprises a normal / inverse rotation determining circuit 45A (FIG. determination circuit), a normal / inverse rotation determining circuit 45B (determining circuit) and a normal / inverse rotation determining circuit 45C (determining circuit). The drive pulse generation circuit 46 includes a drive pulse generation circuit 46A, a drive pulse generation circuit 46B, and a drive pulse generation circuit 46C. The control circuit 47 comprises a control circuit 47A, a control circuit 47B and a control circuit 47C.
In the embodiment, a combination of the normal / inverse rotation determining circuit 45A, the driving pulse generation circuit 46A and the driving circuit 47A, a combination of the normal / inverse rotation determining circuit. 45B, the pilot pulse generation circuit 46B and the driver circuit 47B, and a combination of the normal / inverse rotation determining circuit 45C, the driving pulse generation circuit 46C and the driving circuit 47C are respectively called a motor control unit. The first motor control unit is constituted by one of the combinations that are the combination of the normal / inverse rotation determination circuit 45A, the pilot pulse generation circuit 46A and the control circuit 47A, the combination of normal / inverse rotation determining circuit 45B, the driving pulse generation circuit 46B and the driving circuit 47B, as well as the combination of the normal / inverse rotation determining circuit 45C, the pulse generating circuit of steering 46C and control circuit 47C. In addition, the second motor control unit is constituted by the combination of a normal / inverse rotation determining circuit 45n (n being selected from A, B and C), a driving pulse generation circuit 46n and a control circuit 47n, other than the first motor control unit. In addition, the third motor control unit is constituted by the combination of the normal / inverse rotation determining circuit 45n (n being selected from A, B and C), the driving pulse generation circuit 46n and the circuit 47n, this combination not being that of the first motor control unit nor that of the second motor control unit.
The electronic device 1 displays the time by means of the first, second and third indicator hands 60A to 60C, during operation to measure the time. The electronic device 1 communicates with a terminal 90, by means of a wired or wireless network, so as to send and receive information. For example, the electronic device 1 sends a detection value detected by the sensor 80 and a remaining charge information indicating the remaining charge of the auxiliary battery 13 to the terminal 90 via the network. For example, the electronic device 1 receives time information from the terminal 90 and corrects the measured time based on the received time information. In addition, from the terminal 90, the electronic device 1 receives an operating instruction and controls the driving of the first indicator needle 60A to the third indicator hand 60C, in accordance with the received operating instruction.
The terminal 90 is a device having a function to communicate, such as a smartphone, a terminal in tablet form, a portable game machine and a computer. For example, the terminal 90 is arranged to include an operation unit, a display unit, a control unit, a geo-location system (GPS), a communication unit and a battery. The terminal 90 sends collected time information by using the GPS, an operating instruction, remaining charge information from the terminal's battery itself, to the electronic device 1, via the network. In addition, the terminal 90 receives the detection value transmitted by the electronic device 1 and the remaining charging information, via the network, and displays the information received on the display unit.
A circuit board 10 (substrate) (base) is a base to which are attached the main control unit 20 and the support body 50. The charging terminal 11, the charging control circuit 12, the auxiliary battery 13, the main control unit 20 and the support body 50 are attached to the circuit board 10.
The charging terminal 11 receives the power supply from the outside and it is a universal serial bus connector (USB connector). The charging terminal 11 supplies the load control circuit 12 with the received power.
The charging control circuit 12 charges the auxiliary battery 13 with the power supplied from the charging terminal 11. The charging control circuit 12 supplies the energy stored in the auxiliary battery 13 to the charging unit. main control 20 and the engine control unit 40 attached to the support body 50.
The auxiliary battery 13 is, for example, a lithium-ion polymer battery.
The main control unit 20 controls each constituent element forming part of the electronic device 1. The main control unit 20 displays information to the display unit 70. The information to be displayed is, for example , the charge remaining in the auxiliary battery 13. In addition, the main control unit 20 becomes aware of an actuation result obtained by a user actuating the actuating unit 75 and controls each constituent element forming part of it. of the electronic device 1 according to the actuation result received. In addition, the main control unit 20 becomes aware of a detection value emitted by the sensor 80.
The crystal oscillator 201 is a passive element used for a first frequency to be produced from the mechanical resonance using the quartz piezoelectric phenomenon. Here, the first frequency is, for example, 100 MHz.
The oscillator circuit 202 forms an oscillator in combination with the crystal oscillator 201 and transmits a signal made of the first frequency generated, to the frequency divider circuit 203. The frequency divider circuit 203 divides, at a desired frequency, the signal is the first frequency transmitted by the oscillator circuit 202, and sends the divided signal to the main control circuit 204.
The main control circuit 204 is operated at the rate of a signal transmitted by a control frequency, based on the first frequency. The main control circuit 204 is a processor (CPU, in English) for mobile terminal or portable terminal, for example, and it is a processor with an ARM architecture. In addition, the main control circuit 204 internally comprises a storage unit and stores a correspondence relation between the instruction signal and the motor 48 (described below) and the definition of the instruction signal (the instruction to perform a normal rotation using an instruction pulse, or the instruction to perform a reverse rotation using two instruction pulses). The main control circuit 204 may separately include the storage unit. In the present embodiment, an instruction to cause pointer 60 to perform a normal one-step rotation by means of motor 48 is called a first-type needle actuation, while an instruction to perform An indicator needle 60 reverse rotation of one step by means of the motor 48 is called a second type needle actuation.
The main control circuit 204 sends the instruction signal to drive the motor 48 to the engine control unit 40, at the rate of the signal transmitted by the frequency divider circuit 203. The control circuit main 204 and the motor control unit 40 are connected to each other by means of two control lines (GATE and RDYB) and three transmission lines (MOFR, M1FR and M2FR).
The main control circuit 204 controls each constituent element of the electronic device 1, on the basis of an actuation result emitted by the actuating unit 75. For example, the actuation result is an operation setting the time or an operation with alarm. In the case of a time setting operation, for example, the main control circuit 204 causes the third indicator hand 60C to move to the twelve o'clock position and immobilizes the third indicator hand 60C. In addition, the main control circuit 204 controls that the first indicator hand 60A and the second indicator hand 60B perform fast forward operation or perform fast rewind operation. During the operation with alarm, the main control circuit 204 counts the signals transmitted by the frequency divider circuit 203 and transmits a signal from the alarm 85 when the set time is reached or when the set time reaches its term.
The main control circuit 204 controls the power supply state of the motor control unit 40 by switching between a start state and a stop state of the switch SW. For example, in the case where the remaining charge of the auxiliary battery 13 is smaller than a predetermined capacitance, the main control circuit 204 can perform a control so as to reduce the power supply intervals of the control unit. motor control 40 or to stop the power supply. Alternatively, the main control circuit 204 may provide control to reduce the power supply intervals of the motor drive control unit 40 or to shut down the power supply, based on a control instruction. operation received by the communication circuit 206. The switch SW can be configured to include a MOS transistor.
In addition, the main control circuit 204 controls an operating mode of the electronic device 1, on the basis of an actuation result emitted by the actuating unit 75 or on the basis of an instruction of operation received by the communication circuit 206. Here, the operating mode includes a clock mode (normal operating mode), a stopwatch mode, a time setting mode, an alarm setting mode, an operating mode of the alarm and an external command mode. In the external control mode, at least one of the first to third motors 48A to 48C is driven in response to an operation command outputted from the terminal 90 to actuate the corresponding indicator hand. For example, in the case where the terminal 90 transmits the remaining battery charge of the terminal 90 as an operating instruction, the main control circuit 204 can assign 0% to the twelve o'clock position, 10% to the one o'clock position. and 100% at the ten o'clock position, and can command the third indicator hand to indicate the remaining battery charge of the terminal 90.
In addition, the main control circuit 204 can detect the remaining charge of the auxiliary battery 13. The main control circuit 204 can display to the display control circuit 205 the information as to the remaining measured charge of the auxiliary battery 13, on the display unit 70. The main control circuit 204 can transmit the information as to the remaining measured charge of the auxiliary battery 13, to the terminal 90, via the communication circuit 206 and the network .
The display control circuit 205 causes the display unit 70 to display the display information transmitted by the main control circuit 204. The display control circuit 205 can be part of the unit. 70.
The communication circuit 206 transmits and receives information to and from the terminal 90, via the network, in accordance with the control of the main control circuit 204. For example, the communication circuit 206 uses a communication procedure using the Wi-Fi standard or the low-power Bluetooth (registered mark) standard, designated by its acronym BLE in English in the following, to transmit and receive instructions or information to and from the terminal 90. In addition, the communication 206 can receive information from the GPS.
The crystal oscillator 30 is a passive element used to produce a second frequency by oscillation. Here, the second frequency is lower than the first frequency and is, for example, 32 kHz.
The motor control unit 40 is operated (driven to operate) at the rate of a signal based on the second frequency. For example, the engine control control unit 40 is a motor driver IC. The motor control unit 40 determines whether a control signal from the main control circuit 204 is a control signal to cause the motor 48 to perform a normal rotation or a control signal to bring the motor 48 forward. to reverse rotation. On the basis of the determined result, the motor control control unit 40 generates a driving pulse and drives (operates) the motor 48 by outputting the generated driving pulse. In the present embodiment, an actuation to cause the indicator hand 60 to perform a normal rotation of a pitch by means of the motor 48 is called a first actuation, while an actuation to cause the indicator hand 60 to perform a reverse rotation of one step by means of the motor 48 is called a second actuation.
The voltage-reducing circuit 41 reduces, for example to 1.57 V, the voltage supplied by the charge control circuit 12 and supplies, with the lowered voltage, each element of constituent constitution of the control control unit of the driver. 40 engine.
A GATE hold signal is sent to the input control circuit 42. The input control circuit 42 sends, to the normal / inverse rotation determining circuit 45, a signal indicating a period during which the signal of GATE hold is at a H level (high).
The oscillator circuit 43 forms an oscillator in combination with the crystal oscillator 30 and sends a signal to the second frequency generated, to the frequency divider circuit 44.
The frequency divider circuit 44 divides, up to the desired frequency, a signal at the second frequency emitted by the oscillator circuit 43 and sends the divided signal to the pilot pulse generation circuit 46.
A MOFR signal serving as a first instruction signal is sent to the normal / inverse rotation determination circuit 45A. The normal / inverse rotation determining circuit 45A counts the number of periods during which the input control circuit 42 outputs a signal indicating the level H and the number of periods during which the MOFR signal is at the level H. In this manner , the normal / inverse rotation determining circuit 45A determines whether the MOFR signal is a signal with the instruction to perform a normal rotation or a signal with the instruction to perform a reverse rotation. The normal / inverse rotation determination circuit 45A concludes that a signal equal to or greater than a threshold value is a signal H. When the hold signal GATE is made to pass from the level H to the level L which is the low level, the Normal / inverse rotation determination circuit 45A sends the determination result to the pilot pulse generation circuit 46A. The determination result is information indicating either normal rotation or reverse rotation, or a signal indicating either normal rotation or reverse rotation. In the present embodiment, the level H is selected as a first level and the level L is selected as a second level.
A signal M1FR acting as second instruction signal is sent to the normal / inverse rotation determination circuit 45B. The normal / inverse rotation determining circuit 45B counts the number of periods during which the input control circuit 42 emits a signal indicating the level H and the number of periods during which the signal M1FR is at the level H. In this manner , the normal / inverse rotation determining circuit 45B determines whether the signal M1FR is the signal with the instruction to perform a normal rotation or the signal with the instruction to perform a reverse rotation. When the hold signal GATE is caused to go from the H level to the L level, the normal / inverse rotation determining circuit 45B sends the determination result to the driving pulse generating circuit 46B.
An M2FR signal acting as a third instruction signal is sent to the normal / inverse rotation determining circuit 45C. The normal / inverse rotation determining circuit 45C counts the number of periods during which the input control circuit 42 outputs the signal indicating the level H and the number of periods during which the signal M2FR is at the level H. In this manner , the normal / inverse rotation determining circuit determines whether the signal M2FR is the signal with the instruction to perform a normal rotation or the signal with the instruction to perform a reverse rotation. When the hold signal GATE is caused to go from the H level to the L level, the normal / inverse rotation determining circuit 45C sends the determination result to the driving pulse generating circuit 46C.
On the basis of the determination result issued by the normal / inverse rotation determining circuit 45A, the driving pulse generation circuit 46A generates a pulse signal provided to cause the first motor 48A to rotate. a step or reverse rotation of one step and sends the generated pulse signal to the driving circuit 47A.
On the basis of the determination result issued by the normal / inverse rotation determining circuit 45B, the driving pulse generation circuit 46B generates a pulse signal provided to cause the second motor 48B to rotate. a step or reverse rotation of one step and sends the generated pulse signal to the driving circuit 47B.
On the basis of the determination result emitted by the normal / inverse rotation determining circuit 45C, the driving pulse generating circuit 46C generates a pulse signal provided to cause the third motor 48C to rotate. normal step or a reverse rotation of one step and it sends the generated pulse signal to the driver circuit 47C.
On the basis of the pulse signal emitted by the piloting pulse generation circuit 46A, the control circuit 47A generates control signals M00 and M01 intended to drive the first motor 48A, and the control signals M00 and M01 generated operate the first motor 48A.
On the basis of the pulse signal emitted by the control pulse generation circuit 46B, the control circuit 47B generates control signals M10 and M11 intended to drive the second motor 48B, and the control signals M10 and M11 generated operate the second motor 48B.
On the basis of the pulse signal emitted by the driving pulse generation circuit 46C, the control circuit 47C generates control signals M20 and M21 intended to drive the third motor 48C, and the control signals M20 and M21 generated operate the third motor 48C.
The first motor 48A, the second motor 48B and the third motor 48C are each a step-by-step motor.
The first motor 48A drives the first indicator pointer 60A via the gear train 49A, in response to the control signals M00 and M01 emitted by the control circuit 47A. The second motor 48B drives the second indicator hand 60B via the gear 49B, in response to the control signals M10 and M11 emitted by the
Pilot circuit 47B. The third motor 48C drives the third indicator hand 60C through the gear train 49C, in response to the control signals M20 and M21 transmitted by the control circuit 47C.
Each of the wheels 49A, 49B and 49C is configured to include at least one gear.
For example, the first indicator needle 60A is an hour hand and is rotatably carried by the support body 50. For example, the second indicator hand 60B is a minute hand and is rotatably worn. by the support body 50. For example, the third indicator needle 60C is a second hand and is rotatably carried by the support body 50.
By way of example, the display unit 70 is a liquid crystal display (LCD). For example, the display unit 70 displays the information as to the remaining charge of the auxiliary battery 13, under the control of the main control circuit 204. For example, the display unit 70 may display a mode of operation of the electronic device 1, under the control of the main control circuit 204.
The actuating unit 75 is constituted to include at least one button or a ring. The actuating unit 75 detects an actuation result performed by a user and sends the detected actuation result to the main control circuit 204. The actuating circuit 75 may be a touch panel sensor disposed within the control circuit. display unit 70 or the glass on the dial. In addition, the actuating unit 75 can detect that the alarm 85 is pressed and the actuating unit 75 can use the detection result as an actuation result. A signal applied to alarm 85, which is a piezoelectric element, is detected using the method of the invention disclosed in JP-A 2014-139542, for example.
The sensor 80 is at least one of the following sensors: an accelerometer, a geomagnetic sensor, an atmospheric pressure sensor, a temperature sensor and an angular speed sensor. The sensor 80 sends the detection value to the main control circuit 204. The main control circuit 204 uses the detection value of the accelerometer so as to detect the inclination of the electronic device 1. For example, the accelerometer is a three-axis sensor, which detects gravitational acceleration. The main control circuit 204 uses a sensing value of the geomagnetic sensor to sense an orientation of the electronic device 1. The main control circuit 204 uses a sensing value of the atmospheric pressure sensor for a barometer or altimeter. The main control circuit 204 uses a detection value of the angular velocity sensor (gyro sensor) so as to detect the rotation of the electronic device 1.
The alarm 85 is a piezoelectric element, which emits an alarm according to the control of the main control circuit 204.
The first frequency serving as operating frequency of the main control circuit 204 described above is, for example, 100 MHz and is used to control the load by means of a high speed processing. The second frequency serving as the operating frequency of the motor control unit 40 is, for example, 32 kHz. In addition, for example, in the control frequency of the main control circuit 204, the 7.5 ms interval control of the BLE is 133 Hz. For example, the control frequency of the control unit motor control 40 is 32 Hz for a fast forward drive of the indicator needle, and a second needle actuation drive is 1 Hz. In this way, the operating frequency represents the operating frequency (frequency of operation). clock) provided by the frequency divider circuit 203 to the main control circuit 204, and the operating frequency (clock frequency) provided by the crystal oscillator 30 to the motor control control unit 40. The frequency The operating mode is different from a control frequency (frequency for control) which controls the engine acting as a controlled unit. In addition, the clock signal forming a base of the first frequency generated by the oscillations of the oscillator circuit 202 and the clock signal forming a basis of the second frequency generated by the oscillations of the oscillator circuit 43 are out of synchronization. relative to each other.
Description of the Control Line and the Transmission Line [0071] Now, the control line and the transmission line will be described.
The two command lines are the lines GATE and RDYB, while the three transmission lines are the lines MOFR, M1 FR and M2FR. The command line GATE is the command line through which the main control circuit 204 outputs the hold signal GATE and the hold signal GATE specifies a time limit for sending the instruction signals (MOFR, M1FR and M2FR) to each motor 48. In other words, the GATE hold signal is an instant determination signal (cadence determination signal) which defines (defines or delimits or demarcates) the driving instant of each motor 48, distinguishing between the moment of piloting each motor 48 of the other instants of triggering (other cadences). The MOFR transmission line is the transmission line through which the main control circuit 204 outputs the MOFR signal which acts as the first instruction signal and which is the instruction signal causing the first motor 48A to perform a normal rotation or reverse rotation. The transmission line M1 FR is the transmission line through which the main control circuit 204 transmits the signal M1 FR which acts as a second instruction signal and which is the instruction signal causing the second motor 48B to rotate. normal or reverse rotation. The transmission line M2FR is the transmission line through which the main control circuit 204 transmits the signal M2FR which acts as a third instruction signal and which is the instruction signal causing the third motor 48C to perform a normal rotation or reverse rotation. The command line RDYB is the command line through which the engine control unit 40 transmits the signal RDYB, and is a signal indicating a period during which the engine control unit 40 produces the instruction .
In the example shown in FIG. 1, it has been described the example of three indicator hands and three motors 48. However, the constitution of the electronic device 1 is not limited thereto. For example, in the case of two indicator hands and two motors, the engine control unit 40 may comprise the normal / inverse rotation determining circuits 45A and 45B, the driving pulse generation circuits 46A and 46B, as well as control circuits 47A and 47B. In this case, the main control circuit 204 and the motor control unit 40 can be connected to each other by means of two control lines (GATE and RDYB) and two transmission lines ( MOFR and M1 FR). Furthermore, in the case of a single indicator hand and a single motor 48, the motor control unit 40 may comprise the normal / inverse rotation determining circuit 45A, the pulse generating circuit 46A and the control circuit 47A. In this case, the main control circuit 204 and the motor control control circuit 40 can be connected to each other by means of two control lines (GATE and RDYB) and a transmission line ( MOFR).
Description of an architecture of the circuit board [0074] In the following, an example will be described in which the charging terminal 11, the charging control circuit 12, the auxiliary battery 13, the charging unit main control 20 and the support body 50 are arranged on the circuit board 10. The architecture example shown in FIG. 2 is only an example and the arrangement on the circuit board 10 in the electronic device 1 is not limited thereto.
FIG. 2 is a view showing an example in which the charging terminal 11, the charging control circuit 12, the auxiliary battery 13, the main control unit 20 and the supporting body 50 are arranged on the circuit board 10 according to the present embodiment. In fig. 2, the positions A to D around the timepiece centered on the line AB are respectively called the twelve o'clock position, the three o'clock position, the six o'clock position and the nine o'clock position. As shown in FIG. 2, on the circuit board 10, the support body 50 is disposed generally in the center, the main control unit 20 is arranged at approximately the nine o'clock position and the display unit 70 is disposed approximately at the eleven position. hours. The main control circuit 204 and the motor control unit 40 are connected to each other by two control lines (GATE and RDYB) and three transmission lines (MOFR, M1 FR and M2FR) such as designated by the reference number 501. In the example shown in FIG. 2, the support body 50 comprises a connector 511, to which the main control circuit 204 and five transmission lines are connected. In this case, the connector 511 and the motor control unit 40 are connected to each other by wires arranged on the support body 50.
In addition, the actuating units 75A to 75C are disposed approximately at the two o'clock to four o'clock positions on the right side of the circuit board 10. The auxiliary battery 13 is disposed approximately at the seven o'clock position, on the lower left side of the circuit board 10. The charge control circuit 12 and the charging terminal 11 are arranged approximately at the eight o'clock position.
In addition, the engine control unit 40, the first motor 48A, the second motor 48B, the third motor 48C, the gear 49A, the gear 49B and the gear 49C are attached to the support body 50 In addition, the first indicator hand 60A, the second indicator hand 60B and the third indicator hand 60C are attached to the support body 50.
In the example shown in FIGS. 1 and 2, the example described is that in which three copies of motor control unit (normal / inverse rotation determination circuit, pilot pulse generation circuit and control circuit) and three motors 48 are arranged. on the support body 50. However, the constitution is not limited to that.
For example, the first support body 50 may comprise the crystal oscillator 30, the voltage step-down circuit 41, the input control circuit 42, the oscillator circuit 43, the frequency divider circuit 44 two exemplary engine control units (the normal / reverse rotation determining circuits 45A and 45B, the piloting pulse generating circuits 46A and 46B, and the driving circuits 47A and 47B). The second support body 50 may comprise the crystal oscillator 30, the voltage step-down circuit 41, the input control circuit 42, the oscillator circuit 43, the frequency divider circuit 44, a unit copy motor control circuit (the normal / inverse rotation determining circuit 45C, the driving pulse generating circuit 46C and the driving circuit 47C). In this case, the main control circuit 204 and the first support body can be connected to each other by two control lines (GATE and RDYB) and two transmission lines (MOFR and M1 FR). The main control circuit 204 and the second support body can be connected to each other by two control lines (GATE and RDYB) and a transmission line (M2FR). Even in this case, the total number of control lines and transmission lines between the main control circuit 204 and the support body 50 is 5. According to this architecture, the indicator hand is arranged more freely on the dial ( not shown).
Description of an exemplary chronology of each signal Now, an exemplary chronology of the GATE hold signal, the instruction signal (MOFR), the driving pulse and the RDYB signal according to the present will be described. embodiment.
In FIG. 3, the horizontal axis represents the time and the vertical axis represents the level of each signal among the level H and the level L. In addition, a waveform g1 is a signal waveform of the sustain signal GATE, a waveform g2 is a signal waveform of the MOFR signal, a waveform g3 is a signal waveform of the driving signal M00, a waveform g4 is a form of signal wave of the driving signal M01 and a waveform g5 is a signal waveform of the signal RDYB. Further, a period from time t1 to time t10 is an example in which motor 48 is made to perform a normal rotation, while a period from time T11 to time T28 is a example in which the motor 48 is made to perform a reverse rotation.
The main control circuit 204 passes the GATE hold signal from the level L to the level H at time t1. Then, the main control circuit 204 passes the MOFR signal from the L level to the H level at time t2 and passes the MOFR signal from the H level to the L level at time t3. The period (time t2 at time t3) during which the MOFR signal is at the level H is 10 ns, for example. Then, the main control circuit 204 passes the hold signal GATE from level H to level L at time t4. The period (time t1 to time t4) during which the GATE hold signal is at the level H is 30 ns, for example.
As the number of periods during which the MOFR signal is at the level H is equal to 1 (an instruction pulse) during the period during which the GATE hold signal is at the level H, the normal rotation determination circuit / reverse 45A determines that the signal gives as instruction a normal rotation of the motor 48. Next, the control circuit 47A passes the control signal MOO from the level H to the level L at time t4, and passes the control signal MOO from level L to level H at time t5. On the basis of what the normal / inverse rotation determining circuit 45A and the driving circuit 47A emit, the motor driving control unit 40 defines that the signal RDYB must be at the level H in the period from the instant t4 at time t5. The period from time t4 to time t5 during which the MOO control signal is at the level L is, for example, from 5 to 6 ms.
The main control circuit 204 controls the GATE hold signal and the MOFR signal in a similar way in the period ranging from the instant t6 to the instant t.9 and in the period from the instant t1 to the instant t1. moment t4.
As the number of periods during which the MOFR signal is at the level H is equal to 1 in the period during which the hold signal GATE is at the level H, the normal / inverse rotation determination circuit 45A determines that the signal gives as instruction a normal rotation of the motor 48. Next, the control circuit 47A switches the control signal M01 from the level H to the level L at the instant t9, and switches the control signal M01 from the level L to the level H at the moment t10. On the basis of what the normal / inverse rotation determining circuit 45A and the driving circuit 47A emit, the motor driving control unit 40 defines that the signal RDYB must be at the level H in the period from the instant t9 at time t10. The period from time t9 to time t10 during which the control signal M01 is at the level L is, for example, from 5 to 10 ms.
The main control circuit 204 passes the GATE hold signal from the level L to the level H at time t11. Then, the main control circuit 204 passes the MOFR signal from the L level to the H level at time t12, passes the MOFR signal from the H level to the L level at time t13, passes the MOFR signal from the Lau level. H level at time t14 and pass the MOFR signal from H level to L level at time t15. Then, the main control circuit 204 passes the GATE hold signal from level H to level L at time t16. The period (from time t11 to time t16) during which the GATE hold signal is at level H is, for example, 50 ns.
As the number of periods during which the MOFR signal is at the level H is equal to 2 (two instruction pulses) during the period during which the GATE hold signal is at the level H, the normal rotation determination circuit / reverse 45A determines that the signal gives as instruction a reverse rotation of the motor 48. Then, the control circuit 47A passes the control signal MOO H level L level at time t16. Then, the control circuit 47A sends the control signal MOO from the level L to the level H at the instant t17, and passes the control signal M01 from the level H to the level L. Then, the control circuit 47A passes the control signal MOO from level H to level L at time t18, and sends the control signal M01 from level L to level H. Then, control circuit 47A switches the control signal MOO from level L to level H at time t19. On the basis of what the normal / inverse rotation determining circuit 45A and the driving circuit 47A emit, the motor driving control unit 40 defines that the signal RDYB must be at the level H during the period from the instant t16 at time t19.
The main control circuit 204 controls the GATE hold signal and the MOFR signal, in a similar manner in the period from time t20 to time t25 and in the period from time t11 to the moment t16. Since the number of periods during which the MOFR signal is at the level H is equal to 2 in the period during which the hold signal GATE is at the level H, the normal / inverse rotation determining circuit 45A determines that the signal gives as instruction a reverse rotation of the motor 48. Next, the control circuit 47A switches the control signal M01 from the level H to the level L at time t25. Then, the control circuit 47A sends the control signal MOO from the level H to the level L at the instant t26, and passes the control signal M01 from the level L to the level H. Then, the control circuit 47A passes the MOO control signal from level L to level H at time t27, and sends the control signal M01 from level H to level L. Then, control circuit 47A switches control signal M01 from level L to level H at time t28. On the basis of what the normal / inverse rotation determining circuit 45A and the driving circuit 47A emit, the motor driving control unit 40 defines that the signal RDYB must be at the level H during the period from the instant t25 at time t28.
In the present embodiment, each period during which the MOFR signal is at the level H (second level) is called an instruction signal. In fig. 3, each of the periods ranging from time t2 to time t3, time t7 to time t8, time t12 to time t13, time t14 to time t15, from time t21 to time t22 and time t23 to time t24 is an instruction pulse. Therefore, in the period from time t1 to time t5 during which the hold signal GATE acting as instant definition signal is at level H, the instruction pulse number is equal to 1. In the period from time t11 to time t16 during which the GATE hold signal acting as the time definition signal is at level H, the instruction pulse number is 2.
[0090] Although FIG. 3 shows an example of the MOFR signal, the relationship between the GATE hold signal, the M1FR signal and the M10 and M11 control signals is the same as that described above, and the relationship between the GATE hold signal, the signal M2FR and the control signals M20 and M21 is also the same as that described above.
In addition, in the example shown in FIG. 3, the example has been described in which a normal rotation is performed when there is an instruction instruction pulse and a reverse rotation is performed when there are two instruction pulses. However, the configuration is not limited to this. The actuation corresponding to the number of instruction pulses can be determined in advance by the main control circuit 204 and the motor control unit 40. In addition, the number of instruction pulses can be determined in advance. be greater than or equal to 3. The actuation corresponding to the number of instruction pulses can be stored beforehand in the main control circuit 204 and in the motor control unit 40.
In the example shown in FIG. 3, the example described is that in which the first motor 48A is controlled. However, the main control circuit 204 can control several motors 48 at the same time. In this case, for example, in the period during which the GATE hold signal is at the H level, the main control circuit 204 passes the MOFR signal and the M1FR signal at each of the H and L levels of the M2FR signal. For example, the motor control unit 40 to which the instruction signal is addressed can command the first motor 48A to perform a normal rotation, the second motor 48B to perform a reverse rotation and the third motor 48C. perform a normal rotation.
FIG. 4 is a view showing an example of the timing of the GATE hold signal, the instruction signals (MOFR and M1FR), the driving pulse, and the RDYB signal according to the present embodiment. In fig. 4, the horizontal axis represents the time and the vertical axis represents the level of each signal among the signal H and the signal L. The waveforms g1 to g5 are the same as those represented in FIG. 3. A waveform g6 is the signal waveform of the signal M1FR, a waveform g7 is the signal waveform of the driving signal M10, and a waveform g8 is the form of the signal. signal wave of the control signal M11.
The main control circuit 204 passes the GATE hold signal from the level L to the level H at time t31. Then, the main control circuit 204 passes each of the MOFR and M1 FR signals from the L level to the H level at time t32, and passes the MOFR signal and the M1FR signal from the H level to the L level at the instant t33. . Then, the main control circuit 204 passes the GATE hold signal from level H to level L at time t34.
As the number of periods during which the MOFR signal is at the level H is equal to 1 in the period during which the GATE hold signal is at the level H, the normal / inverse rotation determination circuit 45A determines that the signal gives as instruction a normal rotation of the motor 48. Then, the control circuit 47A sends the control signal MOO from the H level L to the instant t34, and the control signal M00 from the L level to the H level at the moment t35.
As the number of periods during which the signal M1FR is at the level H is equal to 1 in the period during which the hold signal GATE is at the level H, the normal / inverse rotation determination circuit 45B determines that the signal gives as instruction a normal rotation of the motor 48. Next, the control circuit 47B switches the control signal M10 from the level H to the level L at the instant t34, and switches the control signal M10 from the level L to the level H at the moment t35.
On the basis of what the reverse / normal rotation determination circuit 45A emits, the normal / inverse rotation determination circuit 45B, the control circuit 47A and the control circuit 47B, the control unit 40 is fixed that the signal RDYB must be at the level H in the period from time t34 to time t35.
In a similar manner to the period from time t31 to time t34, the main control circuit 204 controls the hold signal GATE, the signal MOFR and the signal M1 FR in the period from the instant t36 at time t39.
The control circuit 47A causes the control signal M01 to move from the level H to the level L at the instant t39, and to move the control signal M01 from the level L to the level H at the instant t40.
The control circuit 47B switches the control signal M11 from the level H to the level L at the instant t39, and switches the control signal M11 from the level L to the level H at the instant t40.
On the basis of what the normal / inverse rotation determining circuit 45A emits, the normal / inverse rotation determining circuit 45B, the driving circuit 47A and the driving circuit 47B, the control unit 40 is fixed that the signal RDYB must be at the level H in the period from time t39 to time t40.
Description of the operating period of the main control circuit 204 [0102] Now, a period of operation of the main control circuit 204 will be described.
[0103] FIG. 5 is a view for describing the operating period of the main control circuit 204 according to the present embodiment. In fig. 5, the horizontal axis represents the time and the vertical axis represents the level of each signal among the levels H and L.
In addition, a waveform g11 designates the control signal M00, a waveform g12 designates the control signal M01 and a waveform g13 designates a period of operation of the main control circuit according to a comparative example that does not use the GATE hold signal. A g14 waveform designates an operating period of the main control circuit 204 according to the present embodiment that uses the GATE hold signal. The example shown in FIG. 5 is an example in the case where a normal rotation is made to the motor 48.
The region surrounded by g10 is an example of the waveform of the GATE hold signal and the MOFR signal in the period from time t101 to time t102 of waveform g14. As described with reference to FIG. 3, the duration of the MOFR signal in the case where the motor is brought to perform a normal rotation is 10 ns, and the duration of the GATE hold signal is 30 ns. This time presents the case where the oscillation frequency of the crystal oscillator 201 is 100 MHz. In the present embodiment, the main control circuit 204 is operated during the period during which the hold signal GATE is at level H, i.e. for 30ns.
In the case where the motor 48 is activated without using the GATE hold signal, the main control circuit must be continuously activated in the period from time t102 to time t103 during which the driving pulse is addressed to the motor 48. The period from time t102 to time t103 for a normal rotation of the motor 48 is, for example, a duration of 6 ms.
As described above, according to the present embodiment, the operating period of the main control circuit 204 when the motor is driven for a normal rotation can be reduced to approximately 1/200 (= 6 ms / 30 ns ), compared to the comparative example not using a GATE hold signal. In this way, according to the present embodiment, the energy consumption of the main control circuit 204 while the motor is driven to perform a normal rotation can be reduced to 1/200, compared to the comparative example not employing GATE hold signal.
Now, we will describe a processing procedure when the main control circuit 204 transmits the instruction signal.
[0109] FIG. 6 is a block diagram of a process that occurs when the main control circuit 204 according to the present embodiment outputs the instruction signal. For example, the main control circuit 204 implements the following method at each clock tick given every 10 ns using 100MHz.
Step S1: The main control circuit fixes that the GATE hold signal to be emitted by the GATE command line must be at level H.
Step S2: The main control circuit 204 sets that the MmFR signal to be sent to the transmission line MmFR must be at the level H (m is an integer chosen from 0.1 and 2).
Step S3: The main control circuit 204 sets that the signal MmFR sent to the transmission line MmFR must be at the level L (m is an integer chosen from 0.1 and 2).
Step S4: The main control circuit 204 sets that the GATE hold signal to be sent to the GATE command line must be at the level L.
By means of the steps described above, the method for transmitting the instruction signal of the main control circuit 204 is carried out.
Now, we will describe a processing procedure of the motor control unit 40 when the instruction signal is issued.
[0116] FIG. 7 is a block diagram of a method of the motor control unit 40 when the instruction signal according to the present embodiment is received. The motor control unit 40 implements the following method, for example on the basis of a 32 kHz clock.
Step S11: The input control circuit 42 detects a period during which the GATE hold signal to be sent to the GATE command line is at the level H. Then, the input control circuit 42 detects that the GATE hold signal goes from level H to level L.
Step S12: The normal / inverse rotation determining circuit counts the number of the instruction pulses in the level H of the signal MmFR during a period during which the GATE hold signal is at the level H. On the basis of the number of counted instruction pulses, the normal / inverse rotation determining circuit 45 determines whether the instruction is an instruction to perform a normal rotation or an instruction to perform a reverse rotation.
Step S13: On the basis of the determination result emitted by the normal / inverse rotation determining circuit 45, the driving pulse generation unit 46 generates a pulse signal provided to bring the motor 48 to make a normal rotation of a step or a reverse rotation of a step.
Step S14: On the basis of the pulse signal emitted by the pilot pulse generation circuit 46, the control circuit 47 generates a control signal for driving the motor 48, and drives (activates) the motor. 48 using the generated control signal.
By the steps described above, the method of the motor control unit 40 is performed when the instruction signal is received.
Now, we will describe an example of a processing procedure of the main control circuit not using the GATE maintenance signal according to a comparative example.
[0123] FIG. 8 is a block diagram of the method of the main control circuit not employing the GATE hold signal, according to a comparative example. In a similar way to FIG. 6, the main control circuit implements the following method at each clock tick occurring every 10 ns, using 100 MHz, for example.
Step S901: The main control circuit fixes that the signal MmFR to be sent to the transmission line MmFR must be at the level H. Then, the main control circuit starts a countdown.
Step S902: The main control circuit determines whether 6 ms have elapsed or not, based on the value measured by means of the count. In the case where the main control circuit determines that 6 ms have not elapsed (NO at step S902), step S902 is repeated. In the case where the main control circuit determines that 6 ms have elapsed (YES at step S902), the method proceeds to step S903.
Step S903: The main control circuit fixes that the MmFR signal to be sent to the transmission line MmFR must be at the level L.
By means of the steps described above, the method for transmitting the instruction signal of the main control circuit is carried out.
As described with reference to FIG. 8, according to the comparative example, the main control circuit is operated continuously for 6 ms during which the motor 48 is activated, which consumes energy.
On the other hand, in the present embodiment, the main control circuit 204 is operated only for a duration of 40 ns during which the GATE hold signal is at the level H. As a result, the energy consumption can be reduced, compared to the comparative example.
As described above, in the present embodiment, the number of levels H of the signal MmFR (m is an integer selected from 0.1 and 2) in the period during which the GATE hold signal is at level H is counted.
In this way, the driving pulse is generated by determining whether the instruction is an instruction to perform a normal rotation or an instruction to perform a reverse rotation. As a result, according to the present embodiment, in the case of three motors 48 to be driven, the main control circuit 204 and the motor control control circuit 40 can be connected to each other by means of two control lines and three transmission lines, the number of which is the same as the number of motors 48. The signal RDYB indicates the period during which the engine control unit 40 controls the motor 48 and the instruction is not received. As a result, after the hold signal GATE and the signal MmFR are output from the main control circuit, the instruction can not be sent for a predetermined period of time necessary to drive the motor 48. In this case, in the case of three motors 48, the main control circuit 204 and the motor control unit 40 may be connected to each other by means of a control line and three transmission lines, excluding from the RDYB command line.
As described above, in the present embodiment, a motor 48 is provided with a transmission line (MOFR, M1 FR or M2FR) controlling each motor 48, and the line 48 is furthermore provided. command for the GATE hold signal. Therefore, the number of inputs of the motor control unit 40 present in the electronic device 1 according to the present embodiment is obtained by adding 1 to the number of motors.
In addition, the instruction signal (any of the MOFR signals, M1FR and M2FR) provided to give the instruction as to the moment of operating the motor 48 (any of the first to third 48A to 48C), according to the present embodiment, comprises an instruction pulse in the period during which the GATE hold signal is continuously at the level H in normal rotation times, and comprises two instruction pulses, times of reverse rotation.
In addition, according to the present embodiment, the operating time of the main control circuit 204 during a normal rotation of the motor can be reduced by approximately 1/200 (= 6 ms / 30 ns), compared to the case where the GATE hold signal is not used. As a result, according to the present embodiment, the power consumed by the main control circuit 204 when the motor is activated to perform a normal rotation can be reduced by 1/200, compared to the case in which it is not makes use of the GATE hold signal.
Second Embodiment [0135] In the first embodiment, the example in which the electronic device 1 comprises the charging terminal 11, the charge control circuit 12 and the auxiliary battery 13 has been described. In the present embodiment, the example will be described in which the electronic device 1A comprises a solar cell and an auxiliary battery. In the present embodiment, the level H is called the first level and the level L is called the second level.
Lafig. 9 is a block diagram showing an exemplary architecture of an electronic device 1A according to the present embodiment. The same reference numerals will be used for the constitution elements having the same functions as those of the electronic device 1 (Fig. 1) described as the first embodiment.
As shown in FIG. 9, the electronic device 1A comprises a solar cell G, a diode D, an auxiliary battery E, a switch SW, a main control unit 20A, the support body 50, the first indicator needle 60A, the second indicator hand 60B, the third indicator needle 60C, the display unit 70, the operating unit 75, the sensor 80 and the alarm 85. The solar cell G, the diode D, the auxiliary battery E, the control unit main 20A and the support body 50 are subject to a circuit board 10A.
The main control unit 20A comprises the crystal oscillator 201, the oscillator circuit 202, the frequency divider circuit 203, the main control circuit 204, the display control circuit 205, the circuit 206, the charge control circuit 207 and the power supply circuit 208.
The solar cell G is, for example, a solar panel. The solar cell G converts the light energy into electrical energy, and supplies the converted electrical energy to the auxiliary battery E and to the main control unit 20A.
The diode D is inserted between the solar cell G and the auxiliary battery E so as to prevent reverse circulation of the auxiliary battery E to the solar cell G.
The auxiliary battery E is a storage battery designed to store the electrical energy supplied by the solar cell G. The auxiliary battery E supplies, to the main control unit 20A, the stored energy.
The charge control circuit 207 controls the charged auxiliary battery E by virtue of the electric power produced by the solar cell G. The charge control circuit 207 detects the charge level of the auxiliary battery E. In the case where the charge level of the auxiliary battery is detected and where this charge level is equal to or greater than a predetermined threshold value, the charge control circuit 207 performs a control which is such that no current flows from the cell solar G to the auxiliary battery E, which prevents overcharging.
For example, the power supply circuit 208 is configured to include a voltage-reducing circuit, a constant oscillation voltage circuit, a logic constant voltage circuit, and a power-up circuit. electric. The voltage-reducing circuit lowers the voltage of the power generated by the solar cell G and the power stored in the auxiliary battery E to the desired voltage value, and supplies the electrical power having the voltage value lowered to the voltage circuit. oscillation constant voltage, logic constant voltage circuit and power supply increase circuit. The constant oscillation voltage circuit utilizes the electrical energy provided by the voltage step circuit to generate a constant voltage for powering the oscillator circuit 202 and feeds the oscillator circuit 202 with the generated constant voltage. The logic constant voltage circuit generates, by employing the electrical power supplied by the voltage-reducing circuit, a constant voltage for supplying a logic unit, and supplies the logic unit with the constant voltage generated. The logic unit comprises at least the main control circuit 204. The power supply increase circuit increases, at a desired voltage value, the electrical power supplied by the voltage-lowering circuit, and provides the electric power having the desired voltage. increased voltage value at the display driving circuit 205.
The main control unit 20A may comprise a power quantity detection circuit produced intended to detect the amount of power produced from the solar cell G, a luminance detection circuit for detecting the luminance of the environment in wherein the electronic device 1 is used, as well as a remaining battery charge detecting circuit for detecting the remaining charge of the auxiliary battery E. Each detection circuit can send the detection value to the main control circuit 204.
As shown in FIG. 9, in the electronic device 1A, the main control circuit 204 and the motor control unit 40 are also connected to each other by means of two control lines and three transmission lines. As a result, the electronic device 1A according to the present embodiment also makes it possible to obtain an advantageous technical effect which is the same as that according to the first embodiment.
As stated above, in the prior art, a motor driver is part of the main control unit. However, in the architectures according to the embodiments described above, the motor control unit 40 is dissociated from the main control circuit 204. In this way, according to the embodiments described above, the load to be treated is reduced in the main control circuit 204, which improves the self-controllability of the motor control control unit 40 side.
In addition, according to the embodiments described above, a single line is employed as a transmission line for transmitting the control signal of the main control circuit 204 to the engine control unit 40. Of this In this way, it is possible to minimize the number of transmission lines allocated to the motor control in the main control circuit 204.
For example, even in the case where five connections are allocated to the control of the communication circuit 206, additionally the number of operation buttons increases and the number of allocated control connections increases, according to the embodiments described above. high, the control line to the engine control unit 40 can be assured. As a result, the motor 48 can be driven and controlled in a reliable manner.
In addition, according to the embodiments described above, even if several support bodies 50 provided with a motor 48 and a motor control unit 40 are mounted on the electronic device 1, the number ports of the main control circuit that are allocated to a motor 48 is minimized. As a result, it is possible to control the plurality of motors 48.
According to the embodiments described above, the operating time of the main control circuit 204 when the indicator needle is driven is very reduced. As a result, the power of the main control circuit 204 can be saved.
In addition, according to the embodiments described above, an architecture is adopted in which the signal RDYB indicating a state of needle actuation is emitted. Accordingly, until the main control circuit 204 outputs the next instruction signal (needle actuation control signal), the timepiece waits for edge interruption. As a result, the power of the main control circuit 204 can also be saved during high speed needle operation.
In addition, according to the embodiments described above, the motor control unit 40 operates, for example, with an electrical consumption of approximately 0.1 μΑ outside the actuation time. needle, which minimizes the contribution ratio to the power consumption of the system as a whole.
In addition, according to the embodiments described above, the period of reception of the instruction signal is defined by the GATE hold signal and it is minimized. As a result, faulty operation against external noise can be prevented.
In addition, according to the embodiments described above, the motor control control unit 40 operates by reducing the power supply voltage of the motor control unit 40 to the same voltage ( for example 1.57 V) than that of the electronic timepieces with indicator hands of the prior art afferent. As a result, even if the power supply voltage of the entire system is 3 to 4.2 V as with a lithium-ion battery, the specifications of the motor 48 can lead to energy saving or can lead to couples optimized highs.
In addition, according to the embodiments described above, the needle positions are under the control of the main control circuit 204. Accordingly, a needle position counter inside the control unit Motor control control 40 is not necessary and, thus, the circuit size can be minimized.
In the embodiments described above, it has been described the example in which power is consumed when the main control circuit 204 emits the level H. However, the configuration is not limited thereto. The power consumption may correspond to a logic circuit of the main control circuit 204 to be used. In the case of high power consumption when the L level is emitted, for example, the main control circuit 204 can switch the GATE hold signal from the H level to the L level at time t3 in FIG. 3, can switch the MOFR signal from the H level to the L level at the instant t2, can switch the MOFR signal from the L level to the H level at time t3 and can switch the GATE hold signal from the L level to the H level at the moment t4. In this case, the first level is the L level, while the second level is the H level.
Third Embodiment [0157] In the first embodiment and in the second embodiment, the example in which the main control circuit 204 sends two types of instruction (instruction to make a normal rotation) has been described. at motor 48, instruction to reverse motor (48) to motor control unit 40. However, the configuration is not limited thereto. The number of instruction types can be greater than or equal to 3.
In a third embodiment, there will be described an example in which the number of instruction types is equal to 4.
[0159] FIG. 10 is a block diagram showing an exemplary architecture of an electronic device 1B according to the present embodiment.
As shown in FIG. 10, the electronic device 1B comprises the charging terminal 11, the charge control circuit 12, the auxiliary battery 13, the switch SW, a main control unit 20B, a support body 50B, the first indicator hand 60A, the second indicator hand 60B, the third indicator hand 60C, the display unit 70, the operation unit 75, the sensor 80 and the alarm 85. The same reference numerals will be used for the constituent elements having the same functions as those of the electronic device 1 (FIG 1) described as the first embodiment. In addition, the example of FIG. 10 will be described as an example in which the present embodiment is applied to the electronic device 1. However, it is also possible to apply the present embodiment to the architecture of the electronic device 1A (FIG 9).
The main control unit 20B comprises the crystal oscillator 201, the oscillator circuit 202, the frequency divider circuit 203, a main control circuit 204B, the display control circuit 205 and the circuit of communication 206.
The crystal oscillator 30, the engine control unit 40B, the first motor 48A, the second motor 48B, the third motor 48C, the wheel 49A, the wheel 49B and the wheel 49C are attached to the support body 50B.
The motor control unit 40B comprises the voltage step-down circuit 41, the input control circuit 42, the oscillator circuit 43, the frequency divider circuit 44, a class determination circuit. needle actuator 451 (determining circuit), the driving pulse generation circuit 46 and the driving circuit 47. The needle actuating class determination circuit 451 comprises a class determining circuit needle actuator 451A (determining circuit), a needle actuating class determining circuit 451B (determining circuit) and a needle actuating class determining circuit 451C (determining circuit) .
In this way, differences between the electronic circuit 1 and the electronic circuit 1B are in the main control circuit 204B and in the needle operation class determining circuit 451.
In addition to the processing of the main control circuit 204, the main control circuit 204B sends an instruction to the engine control unit 40B to actuate the indicator hand 60 according to a third type (called hereinafter a third type needle actuation) and an instruction to actuate the indicator needle 60 according to a fourth type (hereinafter referred to as a fourth type needle actuation). In the present embodiment, actuation to cause the indicator hand 60 to perform normal rotation by means of the motor 48 is called a first actuation, an actuation to cause the indicator hand to reverse by means of the motor 48. is called a second actuation, an actuation to cause the indicator needle 60 to be actuated according to the third type by means of the motor 48 is called a third actuation and an actuation to cause the indicator needle 60 to be actuated according to the fourth type to motor means 48 is called a fourth actuation.
The needle operation class determination circuit determines the type of the instruction signal outputted from the main control circuit 204B. The needle operation class determination circuit 451 sends the determination result to the pilot pulse generation circuit 46.
The MOFR signal serving as the first instruction signal is addressed to the needle actuating class determining circuit 451 A. The needle actuating class determination circuit 451A counts the number of periods wherein the input control circuit 42 outputs the signal indicative of the level H and the number of periods during which the MOFR signal is at the level H, which identifies the class of needle actuation of the MOFR signal. The needle operation class determination circuit 451A sends the determination result to the drive pulse generation circuit 46A when the hold signal GATE changes from the H level to the L level. The determination result indicates that any of four alternatives which are information or a signal indicating a normal rotation, information or a signal indicating reverse rotation, information or a signal indicating a low voltage needle actuation (also called BLI needle actuation ( acronym for Battery Life Indica-tor)), and information or a signal indicating a demonstration needle actuation. Here, the low voltage needle actuation (BLI needle actuation) is a pointer needle operation in a state where the auxiliary battery voltage 13 has a value equal to or less than a predetermined voltage. . For example, low voltage needle actuation refers to a state in which the indicator needle is actuated once every two seconds. In addition, the demonstration needle actuation designates a needle actuation state used for confirmation of operation or demonstration when the timepiece is sent or displayed in magazines. For example, the demonstration needle actuation refers to a state of needle operation wherein each indicator needle performs normal rotation to reverse rotation or reverse rotation to normal rotation.
The signal M1FR acting as a second instruction signal is addressed to the needle actuating class determining circuit 451 B. The needle actuating class determination circuit 451B counts the number of periods which the input control circuit 42 outputs the signal indicative of the level H, as well as the number of periods during which the signal M1FR is at the level H, which identifies the class of needle actuation of the
M1FR signal. When the hold signal GATE goes from the H level to the L level, the needle operation class determination circuit 451B sends the determination result to the drive pulse generation circuit 46B.
The signal M2FR acting as a third instruction signal is addressed to the needle operation class determination circuit 451C. The needle operation class determination circuit 451C counts the number of periods during which the input control circuit 42 outputs a signal indicative of the level H, as well as the number of periods during which the M2FR signal is at the level. H, which identifies the needle actuation class of the M2FR signal. When the hold signal GATE goes from the H level to the L level, the needle operation class determination circuit 451C sends the determination result to the pilot pulse generation circuit 46C.
Now, we will describe an example of each of the instruction signals that are the needle actuation of the first type until the needle actuation of the fourth type.
[0171] FIG. 11 is a view showing an example of each of the instruction signals from a first type needle actuation to a fourth type needle actuation according to the present embodiment. The description will be made using the MOFR signal in FIG. 11 as an example of the instruction signal. In fig. 11, the horizontal axis represents the time, while the vertical axis represents the level of each signal among the level H and the level L. In addition, the waveform g1 is a signal waveform of the signal GATE, while waveform g2 is the signal waveform of the MOFR signal.
In the example shown in FIG. 11, a period from time t201 to time t202 includes an instruction instruction pulse and represents a period of a first type needle actuation that causes the needle actuation to be performed. in a normal rotation with the indicator needle 60.
The period from time t203 to time t204 comprises two instruction instruction instruction pulses and represents a second type needle actuation period which causes a needle operation consisting of reverse rotation to the indicator needle 60.
The period from time t205 to time t206 comprises three pulses of the pulse signal and represents a third type of needle actuation period that causes needle actuation to be performed at a low voltage. the indicator needle 60.
The period from time t207 to time t208 comprises four instruction instruction instruction pulses and represents a fourth type needle actuation period that causes the needle actuation to be performed. demonstration with the indicator needle 60.
Now, we will describe each signal example for the actuation of the third type needle.
[0177] FIG. 12 is a view showing each signal example in the third type needle actuation, according to the present embodiment. In fig. 12, the horizontal axis represents the time and the vertical axis represents the level of each signal among the level H and the level L. The waveforms g1 to g5 are the same as those in FIG. 3. In addition, in fig. 12, the MOFR signal represents an example of an instruction signal.
The main control circuit 204B switches the GATE hold signal from the level L to the level H in the period from the instant t251 to the instant t252. Then, the main control circuit 204B emits three instruction pulses in which the MOFR signal is at the level H in the period from the instant t251 to the instant 252.
As the number of periods during which the MOFR signal is at the level H is equal to 3 (3 instruction pulses) in the period during which the GATE hold signal is at the level H, the class determination circuit D Needle operation determines that this is the instruction for low voltage needle actuation. Then, the control circuit 47A switches the control signal M00 from the level H to the level L at the instant t252 and causes the control signal M00 to move from the level L to the level H at the instant t253. Based on what the needle actuating class determining circuit 451A and the driving circuit 47A issue, the motor driving control unit 40B sets that the RDYB signal must be at the level H at the same time. instant t252. Then, the control circuit 47A switches the control signal M01 from the level H to the level L at the instant t254 and switches the control signal M01 from the level L to the level H at the instant t255. Based on what the needle actuating class determining circuit 451A and the driving circuit 47A issue, the motor driving control unit 40B sets that the RDYB signal must be at the level L to the control circuit. moment t255. In this manner, the first indicator needle 60A rotates normally two steps.
The operation over the period from time 256 to time t260 is similar to operation over the period from time t251 to time t255. The period from time t251 to time t256 lasts, for example, two seconds. The period from time t252 to time t254 lasts, for example, 125 ms.
Now, we will describe each signal example for the fourth class of needle actuation.
[0182] FIG. 13 is a view showing each signal example in the fourth type needle actuation, according to the present embodiment. In fig. 13, the horizontal axis represents the time and the vertical axis represents the level of each signal among the levels H and L. The waveforms g1 to g5 are the same as those in FIG. 12. In addition, fig. 13 shows an example in which the MOFR signal is the instruction signal. In the example shown in FIG. As a demonstration needle actuation, a normal rotation is performed four times after a reverse rotation has been performed four times.
The main control circuit 204B switches the GATE hold signal from the level L to the level H in the period from the instant t301 to the instant t302. Then, the main control circuit 204B transmits four instruction pulses in which the MOFR signal is at the level H in the period from time t301 to time t302.
As the number of periods during which the MOFR signal is at the level H is equal to 4 (4 instruction pulses) in the period during which the hold signal GATE is at the level H, the class determination circuit D Needle operation 451A determines that this is the instruction for the demonstration needle actuation. Then, the control circuit 47A transmits the control signal M00 and the control signal M01 so that the first indicator pointer performs four inverse rotations in the period from the instant t302 to the instant 309. Then, the control circuit 47A transmits the control signal M00 and the control signal M01 so that the first indicator needle 60A performs four normal rotation times in the period from time t310 to time t317. Based on what the needle actuating class determining circuit 451A and the driving circuit 47A transmit, the motor driving control unit 40B sets that the signal RDYB must be at the level H in the period from time t302 to time t317.
[0185] Now, a processing procedure of the engine control unit 40B will be described when the instruction signal is received.
[0186] FIG. 14 is a block diagram of a method of an engine control unit when the instruction signal according to the present embodiment is received.
[0187] Step S101: the input control circuit 42 detects a period during which the GATE hold signal sent to the GATE command line is at the level H. Then, the input control circuit 42 detects which signal GATE holds from level H to level L.
Step S102: the needle operation class determination circuit 451 counts the instruction pulse number in which the MmFR signal is at the level H in the period during which the GATE hold signal is at the level of H, and determines the type of the instruction signal, based on the number of instruction pulses counted. In the case where the needle operation class determination circuit 451 determines that it is the first type needle actuation, the method proceeds to step S103. In the case where the needle operation class determining circuit 451 determines that it is the second type needle actuation, the method continues in step S104. In the case where the needle actuating class determination circuit 451 determines that it is the third type needle actuation, the method proceeds to step S105. In the case where the needle actuating class determination circuit 451 determines that it is the fourth type needle actuation, the method proceeds to step S106.
Step S103: On the basis of the determination result emitted by the needle actuating class determining circuit 451, the driving pulse generating unit 46 generates the pulse signal to cause the signal to be generated. motor a normal rotation of one step (needle actuation of the first type). After the pilot pulse generating unit 46 has performed the method, the method continues at step S107.
[0190] Step S104: Based on the determination result from the needle operation class determining circuit 451, the driving pulse generation unit 46 generates the pulse signal to cause the signal to be generated. reverse rotation of one step (needle actuation of the second type). After the pilot pulse generating unit 46 has performed the method, the method continues at step S107.
Step S105: On the basis of the determination result emitted by the needle actuating class determining circuit 451, the driving pulse generating unit 46 generates the pulse signal to effect the motor needle actuation in low voltage (third type needle actuation). After the pilot pulse generating unit 46 has performed the method, the method continues at step S107.
Step S106: On the basis of the determination result issued by the needle actuating class determining circuit 451, the driving pulse generating unit 46 generates the pulse signal to cause the signal to be generated. motor demonstration needle actuation (fourth type needle actuation). After the pilot pulse generating unit 46 has performed the method, the method continues at step S107.
Step S107: on the basis of the pulse signal emitted by the pilot pulse generation circuit 46, the control circuit 47 generates the control signal for driving the motor 48 and operates the motor using the control signal. pilot signal generated.
By the steps described above, the method of the engine control unit 40B when the instruction signal is received is completed.
As described above, in the present embodiment, the number of instruction pulses in the instruction signal is counted and on the basis of the counted result, two or more types of classes of instruction are counted. needle actuation to cause the indicator needle 60 to effect needle actuation by means of the motor 48 are determined.
According to the present embodiment, in addition to the advantageous effects of the first embodiment and the second embodiment, this architecture allows the indicator needle to perform different needle operations in response to the number of pulses. instruction contained in the instruction signal.
In the embodiments described above, the load other than the indicator needle is constituted, for example, by the display control circuit 205 and the communication circuit 206. However, the configuration is not identical. limited to that. Any other load can be integrated as long as the load other than the indicator needle can be added to the timepiece and requires high speed processing in the control unit.
The present invention is not limited to the embodiments described above. In addition, in the present invention, any two or more preferred embodiments of the first embodiment, the second embodiment, and the third embodiment may be partially or fully combined with each other. .
A program for performing all or part of the functions of the main control unit 20 (20A or 20B) or the motor control unit 40 (40B) according to the present invention can be recorded on a medium. computer readable recording. The program recorded on the recording medium can be read and executed by a computer system in order to fulfill all or part of the functions of the main control unit 20 (20A or 20B) or the control control unit of the control unit. Engine 40. The "computer system" referred to herein includes the operating system or hardware of the peripheral devices. In addition, the "computer system" also includes the Web or Web (World Wide Web) provided with a home page providing environment (or display environment). "Computer-readable medium" means a portable medium such as a flexible disk, a magneto-optical disk, a read-only memory (or ROM) and CD-ROM (or CD-ROM), or it may be a medium storage device such as a hard disk that is part of the computer system. In addition, the "computer-readable recording medium" includes that which carries the program for a certain period of time, such as a random access memory (RAM) that is part of the computer system used as a server or as a client in the case where the program is transferred via a network such as the Internet or a communication line such as a telephone line.
[0200] In addition, the aforementioned program can be transmitted from the system to computer having the program stored in the storage device to another computer system via a transmission medium or by using a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting the program means a medium having a function of transmitting information as in a network (a communication network) such as the Internet or a communication line (communication cable) such that a telephone line. In addition, the aforementioned program may partially perform the functions described above. In addition, the above-mentioned program may be a difference file (difference program) which can perform the functions described above in combination with the program previously recorded in the computer system.
Description of reference numerals and symbols [0201] 1,1A, 1B: electronic device 10: circuit board 11: charging terminal 12: charging control circuit 13: auxiliary battery 20, 20A, 20B: main control unit 201: crystal oscillator 202: oscillator circuit 203: frequency divider circuit 204, 204B: main control circuit 205: display driver circuit 206: communication circuit 207: load control circuit 208: circuit power supply 30: crystal oscillator 40: motor control unit 41: voltage-reducing circuit

权利要求:
Claims (13)
[1]
42: Input control circuit 43: Oscillator circuit 44: Frequency divider circuit 45, 45A, 45B, 45C: normal / inverse rotation determining circuit 46, 46A, 46B, 46C: pulse generating circuit 47, 47A, 47B, 47C: pilot circuit 48A: first motor 48B: second motor 48C: third motor 49A, 49B, 49C: wheel 50: support body 60: indicator needle 60A: first indicator needle 60B: second hand indicator 60C: third indicator pointer 70: display unit 75: actuating unit 80: sensor 85: alarm 451,451 A, 451 B, needle actuating class determination circuit 451C: SW: GATE switch: signal definition of instant MOFR, M1FR, M2FR: instruction signal Claims
1. Timepiece (electronic device 1, 1A, 1B) in which an indicator needle (60) is driven by a motor (48) and a high speed processing is required to control a load other than the indicator needle, the timepiece comprising: a main control circuit (204, 204B) which gives the moment of activation of the motor to drive the load and which is actuated by an operating frequency acting as a first frequency, and a motor control unit (40, 40B) which generates a driving pulse to activate the motor and which is actuated by an operating frequency acting as a second frequency which is lower than the first frequency.
[2]
2. Timepiece according to claim 1, wherein a clock signal forming the base of the first frequency and a clock signal forming the base of the second frequency are desynchronized relative to each other.
[3]
Timepiece according to claim 1 or 2, wherein, based on the first frequency, the main control circuit sends an instruction signal indicating the moment of activation of the motor, to the control unit. motor control, in which, on the basis of the first frequency, the main control circuit sends an expected time definition signal to define the time that allows the instruction signal to be applied to the motor control, and wherein the motor control unit generates the driving pulse, based on the second frequency, at the selected time in response to the instruction signal.
[4]
The timepiece of claim 3, wherein the instruction signal comprises an instruction pulse in which the motor control unit comprises a determining circuit (45,451) which counts the number of pulses of the motor. received instruction present in the instruction signal, while receiving the instantaneous definition signal, and which determines at least two types of needle actuation class for actuating the indicator needle by means of the motor, in response to the number of instruction pulses, and in which, on the basis of a result determined by the determining circuit, the motor control unit actuates the indicator hand by means of the motor, in response to the class d needle actuation.
[5]
The timepiece of claim 4, wherein the instruction signal can be configured to include the instruction pulses, the number of which varies according to the class of needle actuation, for a duration of the instant definition signal, whenever two or more types of operation are performed.
[6]
6. Timepiece according to one of claims 3 to 5, wherein the main control circuit changes the level of the instant definition signal from a first level to a second level, wherein, after passing the instantaneous definition signal to the second level, the main control circuit changes the level of the instruction signal from the first level to the second level, wherein, after passing the signal from instruction at the second level, the main control circuit passes the instruction signal to the first level, and in which, after passing the instruction signal to the first level, the main control circuit passes the definition signal of the first level. moment from the second level to the first level.
[7]
7. Timepiece according to claim 4, wherein the class of needle operation includes at least one of the first type in which the indicator needle is made to perform a first actuation by means of the engine, a second type according to which the indicator needle is made to perform a second actuation different from the first actuation by means of the motor, a third type in which the indicator needle is made to perform a third actuation different from the first actuation and the second actuation by means of the motor. , and a fourth type in which the indicator needle is made to perform a fourth actuation different from the first actuation, the second actuation and the third actuation by means of the motor.
[8]
8. Timepiece according to claim 7, wherein the first type is an actuation intended to cause the indicator needle to perform normal rotation by means of the motor, and the number of instruction signals is equal to 1 while the instantaneous definition signal is received, wherein the second type is an actuation intended to cause the indicator pointer to reverse rotation by means of the motor, and the number of the instruction signals is equal to 2 while the instant definition signal is received, wherein the third type is an actuation intended to cause the indicator hand to be actuated by means of the motor so as to indicate a reduced battery voltage to a user when the voltage value d a battery powering the timepiece is low, and the number of instruction signals is equal to 3 while the definition signal inst ant is received, wherein the fourth type is an operation to cause the indicator hand to operate differently from that which occurs when the time is displayed by the motor, and the number of the instruction signals is equal to 4 while the instant definition signal is received.
[9]
9. Timepiece according to one of claims 3 to 8, wherein the motor comprises a first motor for driving a first indicator hand, and a second motor for driving a second indicator hand, wherein the circuit controlling the level of the instantaneous definition signal from a first level to a second level, wherein, after passing the instantaneous definition signal to the second level, the main control circuit passes the a first instruction signal level to specify the activation of the first motor and the level of a second instruction signal to specify the activation of the second motor, each from a first level to a second level, wherein, after passing the first instruction signal and the second instruction signal at the second level, the main control circuit t passing the first instruction signal and the second instruction signal each to the first level, and wherein, after passing the first instruction signal and the second instruction signal each to the first level, the control circuit The principal causes the second-level instant-definition signal to pass to the first level.
[10]
10. Timepiece according to one of claims 1 to 9, wherein the indicator hand indicates the time.
[11]
Timepiece according to one of claims 1 to 10, wherein the number of transmission lines through which the instruction signal passes to give the instructions to the motor for driving the indicator needle to generate the pulse The pilot is the same as the number of engines, and in which the number of signals addressed to the main control unit for controlling the engine, including the instruction signal, can be obtained by adding one to the number of engines.
[12]
A method of controlling a timepiece in which an indicator needle is driven by a motor and high speed processing is required to drive a load other than the indicator hand, the method comprising: a step that is actuated by an operating frequency acting as a first frequency, and in which a main control circuit for driving the load transmits the driving moment of the motor, and a step in which a motor control unit operated by an operating frequency making second frequency office which is lower than the first frequency generates a driving pulse to activate the engine, wherein the step of specifying the driving time comprises a step of passing the level of a definition signal of time provided to define the moment of driving the motor from a first level to a second n based on a rate of the first frequency, a step of passing the level of an intended instruction signal to specify the driving of the motor from a first level to a second level, after the passage of the second-level time-defining signal, a step of passing the instruction signal to the first level, after the instruction signal has passed to the second level, and a step of passing the definition signal of moment from the second level to the first level, after passing the instruction signal to the first level.
[13]
The method of controlling a timepiece of claim 12, further comprising: a step in which the motor control unit counts the number of instruction pulses present in the instruction signal during a period of time. period during which the instantaneous definition signal is at the second level, and a step in which the engine control unit determines, from the number of steps counted, a class of needle actuation provided for an actuation of the indicator needle by means of the motor, and generates, according to the determined needle actuation class, a control pulse intended to control the motor.

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