JP5857801B2 - Electronic clock with built-in antenna - Google Patents

Description

  The present invention relates to an electronic timepiece with a built-in antenna.

In a GPS timepiece that acquires radio wave information from a GPS (Global Positioning System) satellite and displays an accurate time, an antenna for receiving radio waves is required.
As shown in Patent Document 1, a conventional GPS receiving antenna is mounted on a base material, an electrode is formed on the top surface of a dielectric, and a ground plate is formed on a substrate disposed on the bottom surface of the antenna. . The antenna and the substrate are fixed in close contact via an adhesive layer.

  In a watch, metal members such as an exterior case and interior parts are arranged around the antenna. If there is a change in the position of the antenna, a resonance frequency shift occurs, leading to a decrease in reception sensitivity. That is important.

Japanese Patent Laid-Open No. 10-197662

  However, in the conventional antenna, the antenna housing portion has a shape protruding from the timepiece main body, and the timepiece itself becomes large. In addition, there are restrictions on the design due to the antenna housing. In other words, the antenna used in the watch is required to be small and space-saving in order to realize a round shape that is a basic design shape of the watch.

  In order to meet such requirements, it is conceivable to form the antenna in a ring shape. However, when the antenna is formed in a ring shape, it is necessary to form a ground by an outer case or a movement without providing a base material on the lower surface of the antenna. Therefore, the antenna cannot be fixed by a method of adhering the antenna to the base material like a conventional antenna.

  In particular, the antenna material is a composite material of a dielectric and a plastic, and the material strength is brittle. In a timepiece, it is necessary to prevent changes in the position of the antenna from the usage pattern. Also, prevention of antenna position change is important in order not to cause a resonance frequency shift.

  An object of the present invention is to provide an electronic timepiece with a built-in antenna that accurately determines the position and securely holds the GPS antenna even when the GPS antenna installed inside the timepiece is formed in a ring shape.

  In order to solve the above problems, an electronic timepiece with built-in antenna according to the present invention includes a cylindrical outer case, a ground plate accommodated in the outer case, and a ring-shaped antenna body accommodated in the outer case. And a reference surface formed on the ground plate for positioning the antenna body in a direction perpendicular to the ground plate, and attached to the ground plate and engaged with the antenna body to bias the antenna body in the direction of the reference surface. And an engaging portion formed on the antenna body and engaged with the urging member.

  In this electronic timepiece with built-in antenna, an urging member is attached to the main plate, and this urging member is engaged with an engaging portion of the antenna body. The antenna body is placed on a reference surface formed on the ground plate, and is urged in the reference surface direction by the urging member.

Therefore, according to the present invention, even when the antenna body installed inside the watch is ring-shaped and stored in the exterior case, positioning in the direction perpendicular to the reference plane can be accurately performed, Thus, the antenna body can be securely held.
As a result, the antenna body can be prevented from being damaged, and the position of the antenna body is not changed, so that the occurrence of a resonance frequency shift can be prevented.
Further, since the engaging portion of the antenna body is engaged with the urging member, anyone can position the antenna body in the vertical direction with respect to the ground plane with a simple operation. Also, the antenna body can be easily attached to and detached from the ground plane.

In this antenna built-in type electronic timepiece, a plate member provided with a hook may be used as the urging member, and a protruding portion that engages with the hook may be formed on the antenna body as the engaging portion. In this way, the antenna body can be biased more reliably in the reference plane direction.
You may make it form the said protrusion part in the outer peripheral side part of the said antenna body. By forming the projecting portion on the side surface of the antenna body, the positioning operation of the antenna body or the mounting / removing operation of the antenna body is facilitated, and the antenna body is more reliably biased toward the reference plane. be able to.

  In this electronic timepiece with built-in antenna, a through hole that engages with the protruding portion may be formed in the hook. In this way, after the antenna body is placed on the surface of the plate member, the antenna body is positioned by engaging the through hole of the hook so that the protruding portion of the engaging portion of the antenna body is passed, or The antenna body can be easily attached and detached, and the antenna body can be more reliably biased toward the reference plane.

  In this electronic timepiece with built-in antenna, a ring-shaped plate material on which the antenna body is placed may be used as the biasing member. In this way, since the biasing member can be provided at the lower part of the antenna body, the antenna body can be reliably biased in the reference plane direction without increasing the size of the timepiece.

In this electronic timepiece with built-in antenna, the base plate is formed with a first guide engaging portion at a plurality of locations in the circumferential direction of the base plate, and the antenna body is engaged with the first guide engaging portion. You may make it form an engaging part. In this way, the antenna body is also positioned in the plane direction and the circumferential direction with respect to the ground plane.
As the first guide engaging portion, a guide protruding portion of the antenna body is formed so as to protrude in a perpendicular direction or a radial direction with respect to the ground plane, and the second guide engaging portion is engaged with the guide protruding portion of the antenna body. You may make it form the hollow part to match | combine. In this way, the antenna body can be easily positioned in the plane direction and the circumferential direction with respect to the ground plane.

1 is an overall view of a GPS system including an antenna built-in electronic timepiece 100 (electronic timepiece 100) according to an embodiment of the present invention. 2 is a plan view of the electronic timepiece 100. FIG. 2 is a partial cross-sectional view of the electronic timepiece 100. FIG. 2 is an exploded perspective view of a part of the electronic timepiece 100. FIG. 2 is a block diagram showing a circuit configuration of the electronic timepiece 100. FIG. FIG. 3 is a partially cutaway cross-sectional view showing an engagement state between a ring antenna of the electronic timepiece 100 and a protrusion formed on a ground plane. 4 is a partially broken cross-sectional view showing a vertical positioning portion of a ring antenna in electronic timepiece 100. FIG. 4 is a partially broken cross-sectional view showing a vertical positioning portion of a ring antenna in electronic timepiece 100. FIG. FIG. 3 is a partially broken cross-sectional view showing a ring antenna housing portion in the electronic timepiece. FIG. 6 is a partially broken plan view showing a modification of the antenna guide protrusion of the electronic timepiece 100. FIG. 6 is a partially broken plan view showing a modification of the antenna guide protrusion of the electronic timepiece 100.

  Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. However, in each figure, the size and scale of each part are appropriately changed from the actual ones. Further, since the embodiments described below are preferable specific examples of the present invention, various technically preferable limitations are attached thereto. However, the scope of the present invention is particularly limited in the following description. Unless otherwise stated, the present invention is not limited to these forms.

<A: Mechanical structure of an electronic timepiece with built-in antenna>
FIG. 1 is an overall view of a GPS system including an electronic timepiece 100 with a built-in antenna (hereinafter referred to as “electronic timepiece 100”) according to a first embodiment of the present invention. The electronic timepiece 100 is a wristwatch that receives radio waves (radio signals) from the GPS satellite 20 and corrects the internal time, and is a surface opposite to a surface (hereinafter referred to as “back surface”) that contacts the arm (hereinafter referred to as “surface”). ”).

  The GPS satellite 20 is a position information satellite that orbits a predetermined orbit over the earth, and transmits a navigation message superimposed on a 1.57542 GHz radio wave (L1 wave) to the ground. In the following description, the 1.57542 GHz radio wave on which the navigation message is superimposed is referred to as a “satellite signal”. The satellite signal is a right-handed circularly polarized wave.

  Currently, there are about 31 GPS satellites 20 (in FIG. 1, only 4 out of about 31 are shown), and in order to identify which GPS satellite 20 the satellite signal was transmitted from, The GPS satellite 20 superimposes a unique pattern of 1023 chips (1 ms period) called a C / A code (Coarse / Acquisition Code) on the satellite signal. The C / A code looks like a random pattern with each chip being either +1 or -1. Therefore, by correlating the satellite signal and the pattern of each C / A code, the C / A code superimposed on the satellite signal can be detected.

  The GPS satellite 20 is equipped with an atomic clock, and the satellite signal includes extremely accurate time information (hereinafter referred to as “GPS time information”) measured by the atomic clock. Further, a slight time error of the atomic clock mounted on each GPS satellite 20 is measured by a control segment on the ground, and the satellite signal includes a time correction parameter for correcting the time error. The electronic timepiece 100 receives a satellite signal transmitted from one GPS satellite 20, and corrects the internal time to an accurate time by using GPS time information and a time correction parameter included therein.

  The satellite signal includes orbit information indicating the position of the GPS satellite 20 on the orbit. The electronic timepiece 100 can perform positioning calculation using GPS time information and orbit information. The positioning calculation is performed on the assumption that the internal time of the electronic timepiece 100 includes some error. That is, in addition to the x, y, and z parameters for specifying the three-dimensional position of the electronic timepiece 100, the time error is also an unknown number. Therefore, the electronic timepiece 100 generally receives satellite signals respectively transmitted from four or more GPS satellites, and performs positioning calculation using GPS time information and orbit information included therein.

FIG. 2 is a plan view of the electronic timepiece 100. As shown in FIG. 2, the electronic timepiece 100 includes an exterior case 80. The exterior case 80 is configured by fitting a glass edge 82 made of ceramic to a cylindrical case 81 made of metal. In the present embodiment, the exterior case is composed of two parts, but may be composed of one part.
A disk-shaped dial 11 is arranged as a time display portion on the inner peripheral side of the glass edge 82 via a ring-shaped dial ring 83 made of plastic. The pointers 13 (13a to 13c) for displaying etc. are arranged. Further, a liquid crystal panel 40 is disposed below the dial plate 11 so that the liquid crystal panel 40 can be visually recognized from an opening formed in the dial plate 11.
Then, the opening on the surface side of the exterior case 80 is closed with a cover glass 84 through a glass edge 82, and through the cover glass 84, the internal dial 11, the pointers 13 (13a to 13c), and the liquid crystal display panel. 14 is visible.
In FIG. 2, the characters “TYO” displayed on the liquid crystal display panel 14 mean “Tokyo” and display the time of Japan in the world time function.

  The dial ring 83 has a horizontal ring-shaped portion in contact with the inner peripheral surface of the glass edge 82 on the outer peripheral side, and a mortar-shaped portion whose inner peripheral side is inclined inward. The doughnut-shaped storage space is defined by the shape portion and the mortar-shaped portion and the inner peripheral surface of the glass edge 82. A ring-shaped antenna body 40 is stored in the storage space.

  In this antenna body 40, a ring-shaped antenna is disposed along the outer edge of the dial 11 which is a time display portion. In the present embodiment, the antenna body 40 and the circuit board are connected using the antenna connection pins 44A (44B).

  Further, the electronic timepiece 100 manually receives the satellite signal from at least one GPS satellite 20 and corrects the internal time information by manually operating the crown 16 and the operation buttons 17 and 18 shown in FIGS. A mode (time information acquisition mode) and a mode (position information acquisition mode) in which satellite signals from a plurality of GPS satellites 20 are received and positioning calculation is performed to correct the time difference of internal time information are configured. The electronic timepiece 100 can also execute the time information acquisition mode and the position information acquisition mode periodically (automatically).

  FIG. 3 is a partial cross-sectional view showing the internal structure of the electronic timepiece 100, and FIG. 4 is an exploded perspective view of a part of the electronic timepiece 100. As shown in FIG. 3, the electronic timepiece 100 includes a cylindrical case 81 made of metal and a glass edge 82 made of ceramic to fit an outer case 80. A ring-shaped dial ring 83 made of plastic is attached along the inner circumference. Of the two openings of the exterior case 80, the opening on the front surface side is closed with the cover glass 84 via the glass edge 82, and the opening on the back surface side is closed with the back cover 85 formed of metal. Yes. The metal back cover 85 and the metal outer case 80 are fixed by screw grooves.

  The electronic timepiece 100 also includes a secondary battery 27 such as a lithium ion battery inside the outer case 80. The secondary battery 27 is charged with electric power generated by the solar panel 87. That is, solar charging is performed. The electronic timepiece 100 includes a light-transmitting dial plate 11, a pointer shaft 12 penetrating the dial plate 11, and a plurality of hands 13 (circling around the pointer shaft 12 to indicate the current time. A second hand 13a, a minute hand 13b and an hour hand 13c), and a driving mechanism 30 for driving the plurality of hands 13 by rotating the pointer shaft 12. The pointer shaft 12 extends in the front and back direction along the central axis of the exterior case 80.

  The dial plate 11 is a circular plate member that constitutes a time display portion that displays the time inside the outer case 80, is formed of a light-transmitting material such as plastic, and has a pointer 13 (13a) between it and the cover glass 84. ˜c) are arranged inside the dial ring 83. A hole through which the pointer shaft 12 passes is formed at the center of the dial 11 and an opening for allowing the liquid crystal display panel 14 to be visually recognized is formed.

  The drive mechanism 30 is attached to the main plate 38 and includes a step motor and a gear train such as a gear. The step motor rotates the hands 13 through the wheel train to drive the plurality of hands 13. Specifically, the hour hand 13c makes a full turn in 12 hours, the minute hand 13b in 60 minutes, and the second hand 13a in 60 seconds. Further, the base plate 38 to which the drive mechanism 30 is attached is disposed so as to sandwich the dial plate 11 between the hands 13.

  The electronic timepiece 100 also includes a solar panel 87 that performs photovoltaic power generation inside the exterior case 80. The solar panel 87 is a circular flat plate in which a plurality of solar cells (photovoltaic elements) that convert light energy into electric energy (electric power) are connected in series. The solar panel 87 is disposed between the dial 11 and the drive mechanism 30 and has pointers. It extends along the cross section of the shaft 12. The solar panel 87 is disposed inside the dial ring 83 in the extending direction. In addition, a hole through which the pointer shaft 12 passes is formed at the center of the solar panel 87, and an opening for allowing the liquid crystal display panel 14 to be visually recognized is formed.

The electronic timepiece 100 includes an antenna connection pins 44A and 44B, a circuit board 25, a balun 10 mounted on the circuit board 25, a GPS receiving unit (wireless receiving unit) 26, and a control unit 70 inside the exterior case 80. Is provided. The balun 10 is a balanced-unbalanced conversion element, and converts a balanced signal from the antenna body 40 that operates by balanced feeding into an unbalanced signal that can be handled by the GPS receiver 26.
The antenna connection pins 44A and 44B are arranged adjacent to each other in the circumferential direction of the antenna body 40, and only the antenna connection pin 44A is shown in FIG.

The electronic timepiece 100 includes a ring-shaped antenna body 40. The antenna body 40 is formed by using a ring-shaped dielectric as a base material, and forming a metal antenna pattern thereon by plating or silver paste printing. In the present embodiment, the antenna body 40 is arranged around the dial plate 11, is accommodated on the inner peripheral surface side of the glass edge 82, and is covered with a dial ring 83 and a cover glass 84. As this dielectric, a dielectric material that can be used at high frequencies, such as titanium oxide, can be formed by mixing it with a resin, and this makes it possible to further reduce the size of the antenna in combination with the shortening of the wavelength of the dielectric.
For example, in the case of GPS reception, since it is 1.57542 GHz, one wavelength is 19 cm, and in order to embed a normal antenna in a glass edge portion of a wristwatch, it does not fit as it is, and the wavelength needs to be shortened. In this embodiment, since the wavelength shortening by the dielectric is (εr) ^1/2 , in the present embodiment, εr = about 5 to 10 is used as the dielectric. Thereby, even if it is an antenna for GPS reception, a 1 wavelength loop antenna can be accommodated in a wristwatch, and size reduction of an antenna can be achieved.

  The antenna body 40 is fed through a feeding point, and an antenna connection pin 44A (44B) disposed on the lower surface of the antenna is connected to the feeding point. The antenna connection pin 44A (44B) is a pin-shaped connector made of metal, protrudes on the circuit board 25, passes through the insertion hole opened in the ground plane 38, and is inserted into the storage space. The board | substrate 25 and the antenna body 40 inside storage space are connected.

  Since the position of the antenna body 40 is set on the lower surface of the cover glass 84, it is possible to ensure good reception. In addition, since the upper portion of the antenna body 40 is covered with the dial ring 83, the antenna body 40 is not exposed and can be designed on the dial ring 83. There is no reduction. And since the position of the antenna body 40 is set outside the dial 11, the design freedom of the dial 11 is not lowered.

  Next, how to attach the antenna body 40 will be described. In the present embodiment, as shown in FIG. 4, the base plate 38 is formed with an inner peripheral side wall 38a and an antenna body accommodating portion 38c surrounded by the outer peripheral side wall 38b. A ring-shaped fixing plate 90 as an urging member made of metal is attached to the accommodating portion 38c, and the antenna body 40 is fixed to the ground plane 38 by engaging the fixing plate 90 and the antenna body 40. .

The ground plate 38 is formed with antenna guide protrusions 112 as first guide engaging portions extending in the vertical direction at four locations. The antenna guide protrusions 112 are inserted into the fixed plate 90. A plurality of insertion holes 93 are formed. By inserting the antenna guide protrusion 112 into these insertion holes 93, the position of the fixing plate 90 in the plane direction and the circumferential direction of the base plate 38 is determined.
Further, as shown in FIG. 4, the fixing plate 90 has conductive portions 91 formed at four locations on the outer peripheral portion, and these conductive portions 91 are configured to contact the inside of the exterior case 80. The

  Next, a plurality of screws 111 are engaged with screw holes 110 formed at a plurality of locations on the ground plate 38 through a plurality of insertion holes 92 formed on the stationary plate 90, so that the stationary plate 90 is firmly attached to the ground plate 38. And fix it.

In the lower part of the antenna body 40, a recess is formed as a second guide engaging portion that engages with the antenna guide protrusion 112 described above, and the antenna guide protrusion 112 of the ground plane 38 is a recess in the antenna body 40. The antenna body 40 is determined in the plane direction and the circumferential direction position of the ground plane 38 by being fitted to the portions. Details will be described later.
The first engagement portion formed on the ground plate may be a recess, and the second engagement portion formed on the antenna body may be a protrusion.

Furthermore, hooks 94 are formed at four places on the fixing plate 90, and a hook-like protruding portion 41 is formed on the antenna body 40 as an engaging portion that engages with the hook 94. In addition, the base plate 38 is formed with a pedestal portion 113 as a reference surface for determining the vertical position of the antenna body 40 at a plurality of locations.
Therefore, after the fixing plate 90 is attached to the ground plane 38, the antenna body 40 is placed on the stationary plate 90 so that the antenna guide protrusion 112 of the ground plane 38 and the recess of the antenna body 40 are engaged. 40 contacts the pedestal 113 at a plurality of locations. Furthermore, when the hook 94 of the fixing plate 90 is engaged with the hook-shaped protrusion 41 formed on the antenna body 40, the antenna body 40 is biased toward the ground plane 38 by the elastic force of the fixing plate 90. , Pressed against the pedestal 113. In this way, the antenna body 40 is reliably positioned in a direction perpendicular to the surface of the ground plane 38. Details will be described later.

<B: Circuit configuration of electronic timepiece with built-in antenna>
FIG. 5 is a block diagram showing a circuit configuration of the electronic timepiece 100. As shown in FIG. 5, the electronic timepiece 100 includes a GPS receiving unit 26 and a control display unit 36. The GPS receiver 26 performs processing such as satellite signal reception, GPS satellite 20 acquisition, position information generation, and time correction information generation. The control display unit 36 performs processing such as holding internal time information and correcting internal time information.

  The solar panel 87 charges the secondary battery 27 through the charge control circuit 29. The electronic timepiece 100 includes regulators 34 and 35, and the secondary battery 27 supplies drive power to the control display unit 36 via the regulator 34 and to the GPS reception unit 26 via the regulator 35. The electronic timepiece 100 also includes a voltage detection circuit 37 that detects the voltage of the secondary battery 27. Instead of the regulator 35, for example, a regulator 35-1 that supplies driving power to the RF unit 50 (details will be described later) and a regulator 35-2 that supplies driving power to the baseband unit 60 (details will be described later). Both of them may be provided separately. The regulator 35-1 may be provided inside the RF unit 50.

  The electronic timepiece 100 includes an antenna body 40, a balun 10, and a SAW (Surface Acoustic Wave) filter 32. As described in FIG. 1, the antenna body 40 receives satellite signals from the plurality of GPS satellites 20. However, since the antenna body 40 also receives some unnecessary radio waves other than the satellite signal, the SAW filter 32 performs a process of extracting the satellite signal from the signal received by the antenna body 40. That is, the SAW filter 32 is configured as a band-pass filter that passes a 1.5 GHz band signal.

  The GPS receiving unit 26 includes an RF (Radio Frequency) unit 50 and a baseband unit 60. As will be described below, the GPS receiver 26 performs a process of acquiring satellite information such as orbit information and GPS time information included in the navigation message from the 1.5 GHz band satellite signal extracted by the SAW filter 32.

  The RF unit 50 includes an LNA (Low Noise Amplifier) 51, a mixer 52, a VCO (Voltage Controlled Oscillator) 53, a PLL (Phase Locked Loop) circuit 54, an IF amplifier 55, an IF (Intermediate Frequency) filter 56, an ADC (ADC). (A / D converter) 57 and the like.

  The satellite signal extracted by the SAW filter 32 is amplified by the LNA 51. The satellite signal amplified by the LNA 51 is mixed with the clock signal output from the VCO 53 by the mixer 52 and down-converted to an intermediate frequency band signal. The PLL circuit 54 compares the phase of the clock signal obtained by dividing the output clock signal of the VCO 53 with the reference clock signal, and synchronizes the output clock signal of the VCO 53 with the reference clock signal. As a result, the VCO 53 can output a clock signal with a stable frequency accuracy of the reference clock signal. For example, several MHz can be selected as the intermediate frequency.

  The signal mixed by the mixer 52 is amplified by the IF amplifier 55. Here, by the mixing in the mixer 52, a high-frequency signal of several GHz is generated together with the signal in the intermediate frequency band. Therefore, the IF amplifier 55 amplifies a high frequency signal of several GHz along with the signal in the intermediate frequency band. The IF filter 56 passes the signal in the intermediate frequency band and removes the high frequency signal of several GHz (precisely, attenuates below a predetermined level). The intermediate frequency band signal that has passed through the IF filter 56 is converted into a digital signal by an ADC (A / D converter) 57.

  The baseband unit 60 includes a DSP (Digital Signal Processor) 61, a CPU (Central Processing Unit) 62, an SRAM (Static Random Access Memory) 63, and an RTC (Real Time Clock) 64. The baseband unit 60 is connected to a crystal oscillation circuit with temperature compensation circuit (TCXO: Temperature Compensated Crystal Oscillator) 65, a flash memory 66, and the like.

  A crystal oscillation circuit (TCXO) 65 with a temperature compensation circuit generates a reference clock signal having a substantially constant frequency regardless of the temperature. The flash memory 66 stores, for example, time difference information. The time difference information is information in which time difference data (such as a correction amount for UTC associated with coordinate values (for example, latitude and longitude)) is defined.

  When set to the time information acquisition mode or the position information acquisition mode, the baseband unit 60 performs a process of demodulating the baseband signal from the digital signal (intermediate frequency band signal) converted by the ADC 57 of the RF unit 50.

  In addition, when the time information acquisition mode or the position information acquisition mode is set, the baseband unit 60 generates a local code having the same pattern as each C / A code in the satellite search process described later, and generates a baseband signal. A process of correlating each C / A code included and the local code is performed. Then, the baseband unit 60 adjusts the local code generation timing so that the correlation value for each local code has a peak. The GPS satellite 20 is captured). Here, the GPS system employs a CDMA (Code Division Multiple Access) method in which all GPS satellites 20 transmit satellite signals of the same frequency using different C / A codes. Therefore, by detecting the C / A code included in the received satellite signal, it is possible to search for a GPS satellite 20 that can be captured.

Further, the baseband unit 60 uses a local code having the same pattern as the C / A code of the GPS satellite 20 in order to acquire the satellite information of the captured GPS satellite 20 in the time information acquisition mode or the position information acquisition mode. Performs processing to mix baseband signals. In the mixed signal, a navigation message including satellite information of the captured GPS satellite 20 is demodulated. Then, the baseband unit 60 detects TLM words (preamble data) of each subframe of the navigation message, and acquires satellite information such as orbit information and GPS time information included in each subframe (for example, stored in the SRAM 63). ) Process. Here, the GPS time information is the week number data (WN) and the Z count data, but may be only the Z count data when the week number data has been acquired previously.
And the baseband part 60 produces | generates the time correction information required in order to correct internal time information based on satellite information.

  In the time information acquisition mode, more specifically, the baseband unit 60 performs time measurement calculation based on the GPS time information, and generates time correction information. The time correction information in the time information acquisition mode may be, for example, GPS time information itself or information on a time difference between the GPS time information and the internal time information.

On the other hand, in the position information acquisition mode, more specifically, the baseband unit 60 performs positioning calculation based on GPS time information and orbit information, and the position information (more specifically, the electronic timepiece 100 is Get the latitude and longitude of the location. Further, the baseband unit 60 refers to the time difference information stored in the flash memory 66 and acquires time difference data associated with the coordinate values (for example, latitude and longitude) of the electronic timepiece 100 specified by the position information. . In this way, the baseband unit 60 generates satellite time data (GPS time information) and time difference data as time correction information. As described above, the time correction information in the position information acquisition mode may be the GPS time information and the time difference data itself. For example, instead of the GPS time information, the time correction information is a time difference data between the internal time information and the GPS time information. Also good.
The baseband unit 60 may generate time correction information from the satellite information of one GPS satellite 20, or may generate time correction information from the satellite information of a plurality of GPS satellites 20.

  The operation of the baseband unit 60 is synchronized with the reference clock signal output from the crystal oscillation circuit with temperature compensation circuit (TCXO) 65. The RTC 64 generates timing for processing satellite signals. The RTC 64 is counted up by the reference clock signal output from the TCXO 65.

The control display unit 36 includes a control unit 70, a drive circuit 74, and a crystal resonator 73.
The control unit 70 includes a storage unit 71 and an RTC (Real Time Clock) 72 and performs various controls. The control unit 70 can be configured by a CPU, for example.
The controller 70 sends a control signal to the GPS receiver 26 and controls the reception operation of the GPS receiver 26. Further, the control unit 70 controls the operation of the regulator 34 and the regulator 35 based on the detection result of the voltage detection circuit 37. The control unit 70 controls the driving of all the hands via the drive circuit 74.

  The storage unit 71 stores internal time information. The internal time information is time information measured inside the electronic timepiece 100 and is updated by a reference clock signal generated by the crystal unit 73. Therefore, even if the power supply to the GPS receiver 26 is stopped, the internal time information can be updated and the hand movement of the pointer can be continued.

  When the time information acquisition mode is set, the control unit 70 controls the operation of the GPS receiving unit 26, corrects the internal time information based on the GPS time information, and stores the internal time information in the storage unit 71. More specifically, the internal time information is corrected to UTC (Coordinated Universal Time) obtained by adding a UTC offset to the acquired GPS time information. Further, when the position information acquisition mode is set, the control unit 70 controls the operation of the GPS receiving unit 26, corrects and stores the internal time information based on the satellite time data (GPS time information) and the time difference data. Store in the unit 71.

<C: Antenna body positioning mechanism of electronic timepiece with built-in antenna>
Next, the positioning mechanism of the antenna body 40 of the electronic timepiece 100 of this embodiment will be described in detail.
As shown in FIG. 4, the electronic timepiece 100 of this embodiment includes a ground plane 38, a ring-shaped fixing plate 90 made of metal, and an antenna body 40. In the fixed plate 90, conductive portions 91 extending below the fixed plate 90 are formed at four locations on the outer peripheral portion.
The ground plane 38 is formed with an antenna body accommodating portion 38c surrounded by an inner peripheral side wall 38a and an outer peripheral side wall 38b. When attaching the fixing plate 90 to the base plate 38, first, the antenna guide protrusion 112 formed on the base plate 38 is inserted into the insertion hole 93 of the fixing plate 90, and the fixing plate 90 is placed on the accommodating portion 38c. By inserting the antenna guide protrusion 112 through the insertion hole 93, the position of the fixing plate 90 in the plane direction and the circumferential direction of the base plate 38 is determined. The conducting portion 91 contacts the inside of the outer case 80, and conduction with the metal outer case 80 is achieved.

  The base plate 38 has screw holes 110 formed at five locations, and the fixing plate 90 has insertion holes 92 formed at positions corresponding to the screw holes 110. When the fixing plate 90 is temporarily fixed to the base plate 38, temporary fixing is performed so that the positions of the insertion holes 92 of the fixing plate 90 and the screw holes 110 of the base plate 38 coincide. Then, the plurality of screws 111 are engaged with the screw holes 110 to firmly fix the fixing plate 90 to the base plate 38.

  In a state where the fixing plate 90 is attached to the ground plane 38, the antenna guide protrusion 112 protrudes in a direction perpendicular to the surface of the ground plane 38 through the insertion hole 93 as shown in FIG. 6.

  As shown in FIG. 6, a recess 42 that engages with the antenna guide protrusion 112 is formed in the lower portion of the antenna body 40. When the antenna body 40 is placed on the fixed plate 90, the antenna guide protrusion 112 formed on the ground plane 38 and the recess 42 of the antenna body 40 are placed so as to engage with each other.

  As shown in FIG. 4, the antenna guide protrusion 112 is formed in a columnar shape, and the corresponding recess 42 of the antenna body 40 is also formed in a cylindrical shape. Therefore, when the antenna guide protrusion 112 of the ground plane 38 is fitted into the recess 42 of the antenna body 40, the position of the antenna body 40 in the plane direction of the ground plane 38 is determined. Therefore, the virtual center of the antenna body 40 coincides.

  In addition, the antenna body 40 is also positioned in the circumferential direction of the ground plane 38 by fitting the recess 42 and the antenna guide protrusion 112. Thus, the antenna body 40 is positioned with respect to the ground plane 38 in the planar direction and the circumferential direction.

  The fixing plate 90 has four hooks 94 extending upward from the fixing plate 90. The hook 94 is formed with a through hole 95 as shown in FIG. Further, as shown in FIG. 7A, a hook-like protrusion 41 is formed in the antenna body 40 at a position corresponding to the hook 94.

  In addition, as shown in FIG. 4, the base plate 38 is formed with a plurality of pedestal portions 113 serving as reference planes for the positions of the antenna body 40 in the vertical direction with respect to the base plate 38. The pedestal portion 113 has a cylindrical shape, and the upper surface thereof is formed in parallel to the surface of the ground plane 38. Further, the height of each pedestal portion 113 is formed to be the same height as the surface of the main plate 38.

  Therefore, after the fixing plate 90 is attached to the ground plane 38, the antenna body 40 is placed on the stationary plate 90 so that the antenna guide protrusion 112 of the ground plane 38 and the recess 42 of the antenna body 40 are engaged. 7A, the lower surface of the antenna body 40 is in contact with the upper surface of the pedestal 113 at a plurality of locations.

  7A shows a cross section of the antenna body 40, the hook 94 of the fixing plate 90, and the ground plane 38, and FIG. 7B is a view as seen from the direction of arrow A shown in FIG. 7A. . As shown in FIGS. 7A and 7B, when the antenna body 40 is placed on the pedestal portion 113, the through hole 95 of the hook 94 and the hook-like protrusion 41 of the antenna body 40 are engaged. It does n’t match.

  From this state, as shown in FIG. 8 (A), the hook 94 is pulled upward, that is, in the direction of arrow B shown in FIG. 8 (A). The projecting portion 41 is engaged. As a result, as shown in FIG. 8B, the hook-shaped protruding portion 41 protrudes from the through hole 95 of the hook 94.

  Since the fixing plate 90 is fixed to the base plate 38 by the screw 111 as described above, and is formed of a metal having elasticity, by pulling the hook 94 in the direction of arrow B shown in FIG. The antenna body 40 engaged with the hook 94 is urged in the direction of the ground plane 38, that is, in the direction of arrow C in FIG.

  In this way, the antenna body 40 is reliably positioned in a direction perpendicular to the surface of the ground plane 38.

  As described above, in the present embodiment, even when the ring-shaped antenna body 40 that cannot be attached to the substrate is disposed in the storage space surrounded by the dial ring 83 and the glass edge 82 as shown in FIG. In addition, since the positioning is reliably performed in all of the vertical direction, the planar direction, and the circumferential direction with respect to the ground plane 38, a change in the position of the antenna body 40 in the storage space can be reliably prevented, and a resonance frequency shift can be generated. There is no. In addition, the antenna body 40 made of a composite material of dielectric and plastic and having a weak material strength can be reliably protected.

  In addition, the number of the screw holes 110, the antenna guide protrusions 112, and the pedestals 113 in the present embodiment is an example, and the number is not limited to the number described above, and may be increased or decreased as appropriate.

  The fixing plate 90 may be a member having an elastic force, and is not limited to metal.

<D: Modification>
In the embodiment described above, the antenna guide protrusion 112 formed extending in the direction perpendicular to the surface of the ground plane 38 and the recess 42 formed in the direction perpendicular to the surface of the antenna body 40 are engaged. Although the example to combine is demonstrated, this invention is not limited to such an example.

For example, as shown in FIG. 10, an antenna guide protrusion 114 is formed on the inner peripheral side wall 38a of the main plate 38 in the radial direction of the main plate 38 and protrudes toward the outer peripheral side wall 38b. A recess 43 corresponding to the antenna guide protrusion 114 may be formed in the part. By engaging the antenna guide 114 and the recess 43 as described above, the antenna body 40 can be positioned in the plane direction and the circumferential direction with respect to the ground plane 38.
A projecting portion is formed on the inner peripheral portion of the antenna body 40, and a recess portion corresponding to the projecting portion is formed on the inner peripheral side wall 38a of the ground plate, and the projecting portion and the recess portion are engaged with each other. Positioning in the plane direction and the circumferential direction with respect to the main plate 38 may be performed.

Further, as shown in FIG. 11, an antenna guide protrusion 115 is formed on the outer peripheral side wall 38 b of the main plate 38 in the radial direction of the main plate 38 and protrudes toward the inner peripheral side wall 38 a. Alternatively, a recess 45 corresponding to the antenna guide protrusion 115 may be formed. By engaging the antenna guide protrusion 115 and the recess 45 with each other, the antenna body 40 can be positioned in the planar direction and the circumferential direction with respect to the ground plane 38.
A protrusion is formed on the outer periphery of the antenna body, and a recess corresponding to the protrusion is formed on the outer peripheral side wall 38b of the ground plate, and the protrusion and the recess are engaged with each other with respect to the ground plate 38 of the antenna body 40. Positioning in the plane direction and the circumferential direction may be performed.

  In the above-described embodiment, the example in which the fixing plate is formed in a ring shape has been described. However, the fixing plate may be appropriately divided and attached to the ground plate. In the above-described embodiment, an example using a hook having a through-hole has been described. However, the hook does not necessarily have such a shape and can be engaged with the protruding portion of the antenna body. That's fine.

DESCRIPTION OF SYMBOLS 100 ... Electronic timepiece with built-in antenna, 11 ... Dial, 12 ... Pointer shaft, 13 (13a, 13b, 13c) ... Pointer, 26 ... GPS receiver, 30 ... Drive mechanism, 38 ... Ground plate, 40 ... Antenna body, 41 DESCRIPTION OF SYMBOLS ... Projection part, 42 ... Depression part, Antenna body, 80 ... Exterior case, 81 ... Case, 82 ... Glass edge, 83 ... Dial ring, 84 ... Cover glass, 85 ... Back cover, 87 ... Solar panel, 90 ... Fixed plate , 94 ... hooks, 95 ... through holes, 110 ... screw holes, 111 ... screws, 112 ... antenna guide protrusions, 113 ... pedestal parts.

Claims (9)

A cylindrical outer case,
A base plate stored in the exterior case;
A ring-shaped antenna body that will be housed in the outer case,
A reference plane formed on the ground plane and positioning the antenna body in a direction perpendicular to the ground plane;
An urging member attached to the ground plate and urging the antenna body in the direction of the reference plane by engaging with the antenna body;
An engagement portion that is formed on the antenna body and engages with the urging member;
An electronic timepiece with a built-in antenna. The biasing member is a plate member provided with a hook,
2. The antenna built-in electronic timepiece according to claim 1, wherein the engaging portion is a protruding portion that engages with the hook.   3. The antenna built-in electronic timepiece according to claim 2, wherein the protruding portion is formed on an outer peripheral side surface portion of the antenna body.   4. The antenna built-in electronic timepiece according to claim 3, wherein the hook is formed with a through hole that engages with the protruding portion.   4. The antenna built-in electronic timepiece according to claim 1, wherein the urging member is a ring-shaped plate material on which the antenna body is placed.   The ground plate is formed with first guide engaging portions at a plurality of locations in the circumferential direction of the ground plate, and the antenna body is engaged with the first guide engaging portion. The antenna built-in type electronic timepiece according to claim 1, wherein:   The first guide engaging portion is a guide protruding portion of the antenna body formed so as to protrude perpendicularly or radially to the ground plane, and the second guide engaging portion is engaged with the guide protruding portion of the antenna body. 7. The antenna built-in type electronic timepiece according to claim 6, wherein the electronic timepiece has an indented portion. 6. The antenna built-in electronic timepiece according to claim 5, wherein the ring-shaped plate member is divided into a plurality of pieces and attached to the main plate. The outer case and the biasing member are formed of metal,
  9. The antenna built-in type electronic timepiece according to claim 1, wherein a conductive portion that contacts the outer case is formed on the biasing member.

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