JP6631356B2 - Electronic clock - Google Patents

Description

  The present invention relates to an electronic timepiece.

  Patent Document 1 describes an electronic timepiece that displays time and information (altitude, temperature, and atmospheric pressure) different from the time using an hour hand, a minute hand, and a second hand. The electronic timepiece described in Patent Literature 1 displays a scale digit corresponding to an hour hand, a scale digit corresponding to a minute hand, when displaying altitude, when displaying temperature, and when displaying atmospheric pressure. Change the scale digit corresponding to the second hand.

JP 2013-32919 A

  The electronic timepiece described in Patent Literature 1 displays information different from time using an hour hand, a minute hand, and a second hand. For this reason, the electronic timepiece described in Patent Literature 1 cannot display time, which is the most basic function of an electronic timepiece, when displaying information different from time using hands.

  The present invention has been made in view of the above-described circumstances, and it is an object of the present invention to make it possible to continue time display when displaying a plurality of types of information different from time using a pointer.

One embodiment of the electronic timepiece of the present invention has an hour hand and a minute hand, a time display unit that displays time using the hour hand and the minute hand, a first hand different from the hour hand and the minute hand, and a numerical value. An information display unit having a scale indicated by a, a control unit that displays a physical quantity indicated by a numerical value using the first pointer and the scale, a first display unit that displays information different from the numerical value, The control unit uses the numerical value of the scale as a value obtained by multiplying the numerical value of the scale by 10 ⁿ (n is an integer of 0 or more), and uses the first physical quantity indicated by the numerical value as the first guideline. And the scale are displayed using the first pointer and the scale, and the second physical quantity represented by a numerical value and different from the first physical quantity is displayed using the first pointer and the scale. the value, the first display portion is displaying the information If, to instruct the scale indicated by the specific numerical values to the first pointer, and wherein the.
According to this aspect, the first physical quantity and the second physical quantity are displayed by using the first pointer and the scale different from the hour hand and the minute hand, so that the time is displayed by the hour hand and the minute hand, and the first physical quantity or the second physical quantity is displayed. Two physical quantities can be displayed.
According to this aspect, for example, the numerical value “1” of the scale is used as “1000” (= 1 × 10 ³ ) when displaying the first physical quantity, and is used when displaying the second physical quantity. Used as “10” (= 1 × 10 ¹ ). Therefore, even when two physical quantities having different numbers of digits and different types are displayed using the first pointer and the scale, the two physical quantities can be displayed easily by changing the digit corresponding to the numerical value of the scale.

In one aspect of the electronic timepiece described above, it is preferable that the first physical quantity is an altitude or an atmospheric pressure, and the second physical quantity is time.
According to this aspect, it is possible to easily and visually display two different physical quantities of altitude and time or pressure and time.

In one aspect of the electronic timepiece described above, the electronic timepiece further includes a first display unit that displays information different from a numerical value, and the control unit displays a specific numerical value when the first display unit displays the information. It is desirable to make the first pointer indicate the scale that has been set.
According to this aspect, in addition to the above-described operation and effect, when the first display unit displays information different from a numerical value, the first pointer displays a specific numerical value (for example, zero), so that the first pointer displays the first numerical value. It is possible to indicate the invalidity of the display using the pointer and the scale.

In one aspect of the electronic timepiece described above, it is preferable that the information is in a specific direction.
According to this aspect, in addition to the above-described operation and effect, it is possible to show the invalidity of the display using the first pointer and the scale when the display unit displays the specific direction.

1 is an overall view of a GPS including an electronic timepiece according to an embodiment of the present invention. It is a top view showing an example of the electronic timepiece concerning this embodiment. It is a top view which expands and shows a 6 o'clock information display part. It is a top view which expands and shows a 2 o'clock information display part. FIG. 2 is a configuration diagram of an electronic timepiece W. It is a top view which shows an example of a 6:00 information display part. It is a top view which shows the modification of a 6 o'clock information display part. It is a top view which shows the other modification of a 6:00 information display part. It is a top view which shows another modification of a 6:00 information display part.

<First embodiment>
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the dimensions and scale of each part are different from actual ones as appropriate. The embodiments described below are preferred specific examples of the present invention. For this reason, this embodiment is provided with various technically preferable limitations. However, the scope of the present invention is not limited to these embodiments unless otherwise specified in the following description.

  FIG. 1 is an overall view of a GPS including an electronic timepiece with a sensor (hereinafter, simply referred to as “electronic timepiece”) W according to the present embodiment. The electronic timepiece W obtains the position information and the time information of the current position using a radio wave which is an example of an external signal.

  The electronic timepiece W is a wristwatch that receives a radio wave (satellite signal) from the GPS satellite 8 and corrects the time measured by the internal timepiece. The electronic timepiece W displays time and the like on a surface (hereinafter, referred to as “front surface”) opposite to a surface in contact with the arm (hereinafter, referred to as “back surface”). The GPS satellite 8 is a navigation satellite that orbits a predetermined orbit above the earth. The GPS satellite 8 transmits a 1.57542 GHz radio wave (L1 wave) on which the navigation message is superimposed, 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.

  At present, there are approximately 31 GPS satellites 8 (only four are shown in FIG. 1). In order to make it possible to identify from which GPS satellite 8 the satellite signal was transmitted, each GPS satellite 8 converts a unique pattern of 1023 bits (1 ms cycle) called a C / A code (Coarse / Acquisition Code) into the satellite signal. Superimpose. Each bit is either +1 or -1. Thus, the C / A code looks like a random pattern.

  The GPS satellite 8 carries an atomic clock. The satellite signal contains extremely accurate GPS time information measured by an atomic clock. A slight time error of an atomic clock mounted on each GPS satellite 8 is measured by the control segment on the ground. The satellite signal also includes a time correction parameter for correcting the time error. The electronic timepiece W receives a satellite signal (radio wave) transmitted from one GPS satellite 8 and obtains an accurate time (time information) obtained using GPS time information and a time correction parameter included therein. Is used as the internal time.

The satellite signal also includes orbit information indicating the position of the GPS satellite 8 in orbit. The electronic timepiece W can perform positioning calculation using the GPS time information and the orbit information.
The positioning calculation is performed on the assumption that the time measured by the internal clock of the electronic timepiece W includes a certain error. That is, in addition to the x, y, and z parameters for specifying the three-dimensional position of the electronic timepiece W, the time error becomes an unknown. Therefore, the electronic timepiece W generally receives satellite signals transmitted from four or more GPS satellites 8, respectively, performs positioning calculation using the GPS time information and the orbit information included therein, and calculates the current position. Find the location information of

FIG. 2 is a plan view showing the electronic timepiece W.
The electronic timepiece W has an hour hand 1, a minute hand 2, and a second hand 31. The dial 5 has a 12-hour scale 5a formed in an annular shape. An hour hand 1, a minute hand 2 and a dial 5 constitute a time display unit 10. Further, the electronic timepiece W has a measurement display hand 11. The measurement display hand 11 is used to display measurement results of various sensors described later and measurement results of a chronograph function (stopwatch function) described later.
The second hand 31 is provided on a circular information display unit (hereinafter, referred to as a “10:00 information display unit”) 3 on the 10 o'clock side of the electronic timepiece W. The 10:00 information display unit 3 displays, for example, the second of the current time with the second hand 31.

  In addition to the 10 o'clock information display section 3, the electronic timepiece W has a 6 o'clock side circular information display section (hereinafter referred to as “6 o'clock information display section”) 4 and a 2 o'clock side circular information display section (hereinafter, referred to as “2 o'clock information display section”). 7 (referred to as “2 o'clock information display section”).

FIG. 3 is an enlarged plan view showing the 6 o'clock information display unit 4.
The electronic timepiece W includes, as display modes, a time display mode (TIME) for displaying time, an altitude display mode (ALT) for displaying altitude, a barometric pressure display mode (BAR) for displaying barometric pressure, and a bearing for displaying bearing. It has a display mode (COM) and an option display mode (OP).
In the time display mode, a chronograph function (stopwatch function) is effective in addition to the time display.
In the option display mode, for example, a device for measuring biological information such as a pulse sensor is connected to the communication unit 104 (see FIG. 5) wirelessly or by wire. The option display mode is a mode for displaying biological information measured by the device. The option display mode is not limited to the mode for displaying biological information, and can be changed as appropriate.
The 6 o'clock information display unit 4 displays the display modes (the time display mode, the altitude display mode, the barometric pressure display mode, the azimuth display mode, and the option display mode) with the first display hand 42, and displays the remaining battery level and the like. It is displayed by the second display hand 41.

FIG. 4 is an enlarged plan view showing the 2 o'clock information display unit 7.
The 2 o'clock information display unit 7 displays the altitude in the altitude display mode, the air pressure in the atmospheric pressure display mode, the pulse in the optional display mode, and the time in the stopwatch function, in cooperation with the measurement display hand 11 and the scale. 74a to 74j and measurement display hands 71 and 72 are displayed.

  FIG. 5 is a configuration diagram of the electronic timepiece W. In FIG. 5, among the plurality of display units included in the electronic timepiece W and the stepping motor that drives the hands of each display unit, the 2 o'clock information display unit 7 and the measurement display hands 71 of the 2 o'clock information display unit 7 Only the step motor 51 that drives 72 is shown.

As shown in FIG. 5, the electronic timepiece W includes an elevation sensor 101, a direction sensor 102, and a barometric pressure sensor 103.
The altitude sensor 101 measures the altitude. The direction sensor 102 measures the north direction.
The pressure sensor 103 measures the pressure.
The altitude and the atmospheric pressure are each an example of a first physical quantity represented by a numerical value.
The north direction is an example of a specific direction, and is also an example of information different from a numerical value.

  The electronic timepiece W further includes a communication unit 104 that communicates with a pulse sensor or the like, a reception unit 105 that receives a satellite signal, buttons 13 to 15 that are operated by a user, and a measurement display hand 71 of the 2:00 information display unit 7. And a control unit 100 for controlling the electronic timepiece W.

  The control unit 100 is configured by a processor such as a CPU, for example. The control unit 100 measures the time (internal time) using, for example, an internal clock (not shown), and corrects the internal time using the satellite signal received by the receiving unit 105.

Button 13 receives a user operation (press operation) for starting the stopwatch function in the time display mode and a user operation (press operation) for ending the stopwatch function.
The button 14 receives a user operation (press operation) for switching the display mode.
The button 15 is used to start a user operation (push operation) to start altitude measurement in the altitude display mode, a user operation (push operation) to start azimuth measurement in the azimuth display mode, and Receives a user operation (pressing operation) for starting measurement of atmospheric pressure. Note that the button 15 receives a user operation (press operation) for starting the stopwatch function and a user operation (press operation) for ending the stopwatch function in the time display mode instead of the button 13. Is also good.

  The electric circuit system 107 including the control unit 100, the elevation sensor 101, the direction sensor 102, the atmospheric pressure sensor 103, the communication unit 104, the receiving unit 105, and the step motor 51 is driven by using the battery 106 as a power supply.

<Display mode>
The display mode is managed by the control unit 100. The control unit 100 switches the display mode in accordance with the user's pressing operation on the button 14.

<Display and change of display mode>
As shown in FIG. 3, in the 6 o'clock information display unit 4, an “ALT” area 44 b corresponding to the altitude display mode, an “BAR” area 44 c corresponding to the barometric pressure display mode, and “corresponding to the azimuth display mode”. The "COM" area 44d is arranged in the order of "ALT" area 44b, "BAR" area 44c, and "COM" area 44d.

  Further, an area (“TIME” area) 44 a corresponding to the time display mode is arranged on the opposite side of the “ALT” area 44 b from the “BAR” area 44 c side. On the opposite side of the “COM” area 44d from the “BAR” area 44c side, an area (“OP” area) 44e corresponding to the option display mode is arranged.

  The first display hand 42 indicates that the display mode is the time display mode by pointing to the area 44a of “TIME”. The first display hand 42 indicates that the display mode is the altitude display mode by pointing to the “ALT” area 44b. The first display hand 42 indicates that the display mode is the barometric pressure display mode by pointing to the area 44c of “BAR”. The first display hand 42 indicates that the display mode is the azimuth display mode by pointing to the area 44d of “COM”. The first display hand 42 indicates that the display mode is the option display mode by pointing to the “OP” area 44e. The first display hand 42 is driven by a step motor (not shown) controlled by the control unit 100. That is, the pointing position of the first display hand 42 is controlled by the control unit 100.

  In the rotation direction (circumferential direction) of the first display hand 42, the distance between the “ALT” region 44b and the “BAR” region 44c is equal to the “COM” region 44d and the “ALT” region 44b. And the distance between the "BAR" region 44c and the "COM" region 44d is smaller than the distance between the "COM" region 44d and the "ALT" region 44b. Has also become shorter. Here, the distance between the "COM" region 44d and the "ALT" region 44b in the rotation direction (circumferential direction) of the first display hand 42 does not pass through the "BAR" region 44c. It means the distance between the “COM” region 44d and the “ALT” region 44b in the rotation direction (circumferential direction) of 42.

  Note that, in daily life, the time display mode is generally used frequently. For this reason, the "TIME" area 44a (corresponding to the time display mode) is arranged at the 12:00 position where it is most visible. Further, in a usage scene in outdoor sports such as mountain climbing, there is a high possibility that the altitude display mode, the barometric pressure display mode, and the azimuth display mode are used.

<Display of measured values (Part 1: Altitude, barometric pressure, pulse, time in stopwatch function)>
The altitude in the altitude display mode, the barometric pressure in the barometric pressure display mode, the pulse in the optional display mode, and the time in the stopwatch function are indicated by the 2:00 information display unit 7 shown in FIGS. 11 is displayed.

As shown in FIG. 4, the 2 o'clock information display section 7 has measurement display hands 71 and 72 and a dial 73.
The measurement display hands 71 and 72 are examples of a first hand different from the hour hand 1 and the minute hand 2 respectively.
The dial 73 is an example of a member having scales 74a to 74j indicated by numerical values.
In FIG. 4, the scales 74a to 74j are indicated by numerical values "0" to "9", respectively.

The control unit 100 converts the physical quantities (measured values of altitude, measured values of barometric pressure, measured values of pulse, and measured values of time by the stopwatch function) indicated by numerical values into the measurement display hands 71 and 72 and the scales 74a to 74j. Is displayed using. At this time, the control unit 100 uses the numerical values of the scales 74a to 74j as values obtained by multiplying the numerical values of the scales 74a to 74j by 10 ⁿ (n is an integer of 0 or more).
Here, each of the measured value of the altitude, the measured value of the atmospheric pressure, and the measured value of the pulse is an example of a first physical quantity represented by a numerical value.
On the other hand, the measured value of the time by the stopwatch function is an example of a second physical quantity of a type indicated by a numerical value and different from the first physical quantity.

  The control unit 100 displays the first physical quantity using the measurement display hands 71 and 72 and the scales 74a to 74j, and displays the second physical quantity using the measurement display hands 71 and 72 and the scales 74a to 74j. In some cases, different values are used as n described above.

In the present embodiment, when displaying the first physical quantity, the control unit 100 determines the numerical value (for example, “2”) of the scales 74a to 74j for the combination of the measurement display hand 71 and the scales 74a to 74j, The value (“2000”) obtained by multiplying “2”) by 10 ^{3 (= n)} (= 1000) is used. In this case, the control unit 100 uses “3” as n described above.
On the other hand, when displaying the second physical quantity, for the combination of the measurement display hand 71 and the scales 74a to 74j, the control unit 100 changes the numerical value (for example, “2”) of the scales 74a to 74j into the numerical value (“2”). ) Is multiplied by 10 ^{1 (= n)} (= 10) and used as a value (“20”). In this case, the control unit 100 uses “1” as n described above.

Further, when displaying the first physical quantity, the control unit 100 changes the numerical value (for example, “2”) of the scales 74a to 74j with respect to the combination of the measurement display hand 72 and the scales 74a to 74j with the numerical value (“2”). ) Is multiplied by 10 ^{2 (= n)} (= 100) and used as a value (“200”). In this case, the control unit 100 uses “2” as n described above.
On the other hand, when displaying the second physical quantity, for the combination of the measurement display hand 72 and the scales 74a to 74j, the control unit 100 changes the numerical value (for example, “2”) of the scales 74a to 74j to the numerical value (“2”). ) Is multiplied by 100 ^{(= n)} (= 1) and used as a value (“2”). In this case, the control unit 100 uses “0” as n described above.

Therefore, when the first physical quantity (any one of the measured value of the altitude, the measured value of the atmospheric pressure, and the measured value of the pulse) is displayed, the value of the first physical quantity at the thousands position is displayed by the measurement display hand 71, and the first physical quantity is displayed. The value of the hundreds digit of the physical quantity is displayed on the measurement display hand 72.
Note that the control unit 100 drives the stepping motor (not shown) that drives the measurement display hand 11 for the value of the tens place and the value of the tens place of the first physical quantity. The value of the place and the value of the ones place are displayed using the measurement display hand 11 and the scale (100 divisions) divided into 100 on the dial ring 17.

On the other hand, when the second physical quantity (measured value of time by the stopwatch function) is displayed, the value of the tenth place in the second physical quantity is displayed by the measurement display hand 71, and the value of one tenth in the second physical quantity is displayed. The value of the position is displayed on the measurement display hand 72.
In addition, regarding the value of the second in the second physical quantity, the control unit 100 drives the step motor (not shown) that drives the measurement and display hand 11 so that the value of the second in the second physical quantity is compared with the measurement and display hand 11. , A 12-hour scale 5 a provided on the dial 5. At this time, the control unit 100 moves the measurement display hand 11 every ５ second and makes one revolution in 60 seconds.

<Display of measured value (Part 2: North direction)>
The north direction in the direction display mode is indicated by the measurement display hand 11.
In the present embodiment, the control unit 100 drives a motor (not shown) that drives the measurement display hand 11 so that the measurement display hand 11 indicates the north direction measured by the direction sensor 102. At this time, the control unit 100 causes the measurement display hands 71 and 72 to display a scale 74a (numerical value “0”).

<Operation in each display mode>
Next, the operation in each display mode will be described.

<Time display mode>
In the time display mode, the time is displayed by the hour hand 1, the minute hand 2, and the second hand 31 of the 10:00 information display unit 3. That is, when the first display hand 42 in the 6 o'clock information display unit 4 points to the "TIME" area 44a (when the display mode is the time display mode), the hour hand 1, the minute hand 2 and the 10:00 information display are performed. The time is displayed by the unit 3. The hour hand 1 and the minute hand 2 indicate time (hour and minute) in any display mode other than the time display mode.

  As shown in FIG. 3, the dial 4a of the 6 o'clock information display unit 4 indicates the character 43b of “MEAS” indicating “measurement” and the remaining amount of the battery 106 that is the power source of the electronic timepiece W. A battery remaining meter 43c is provided.

<Altitude display mode>
When detecting that the button 15 is pressed in a state where the display mode is the altitude display mode, the control unit 100 outputs an operation start signal to the altitude sensor 101 to cause the altitude sensor 101 to start measuring the altitude and perform the second display. A step motor (not shown) for driving the second display hand 41 is driven so that the hand 41 indicates a position indicating the character 43b of “MEAS”.

  The altitude sensor 101 starts measuring the altitude when receiving the operation start signal, and outputs the altitude measurement result to the control unit 100 when the altitude measurement is completed. When receiving the measurement result of the altitude, the control unit 100 controls the step motor 51 and the like, and displays the measurement result of the altitude using the 2:00 information display unit 7 and the measurement display hand 11.

At this time, for the combination of the measurement display hand 71 and the scales 74a to 74j, the control unit 100 multiplies the numerical values of the scales 74a to 74j by 10 ^{3 (= n)} (= 1000). Used as Further, the control unit 100 sets the numerical value of the scales 74a to 74j as a value obtained by multiplying the numerical value by 10 ^{2 (= n)} (= 100) for the combination of the measurement display hand 72 and the scales 74a to 74j. Used.
Therefore, when the measurement display hands 71 and 72 indicate the positions shown in FIG. 4 in the altitude display mode, an altitude of 1400 m is indicated.

  Further, control unit 100 drives a step motor (not shown) that drives second display hand 41 so that second display hand 41 indicates a position indicating battery remaining amount meter 43c.

<Azimuth display mode>
When the control unit 100 detects that the button 15 is pressed in a state where the display mode is the azimuth display mode, the control unit 100 outputs an operation start signal to the azimuth sensor 102 to cause the azimuth sensor 102 to start measuring the azimuth and perform the second display. A step motor (not shown) for driving the second display hand 41 is driven so that the hand 41 indicates a position indicating the character 43b of “MEAS”.

  The azimuth sensor 102 starts measuring the azimuth when receiving the operation start signal, and outputs the azimuth measurement result to the control unit 100 when the azimuth measurement is completed. When receiving the measurement result of the azimuth, the control unit 100 controls the stepping motor 51 and the like to cause the measurement display needle 11 to indicate the measurement result of the azimuth (north azimuth), and to indicate the scale 74a on the measurement display hands 71 and 72. (Numerical value “0”) is displayed.

  In this case, the measurement display hand 11 that displays the north direction is an example of a first display unit that displays information different from a numerical value. The scale 74a indicated by a numerical value “0” is an example of a scale indicated by a specific numerical value. The specific numerical value is not limited to “0” and can be changed as appropriate.

  As described above, when the measurement display hand 11 displays the north direction (information that is not a numerical value), the measurement display hands 71 and 72 display a specific numerical value “0”. It is possible to show the invalidity of the display (numerical display) using 74a to 74j.

  The control unit 100 further drives a step motor (not shown) that drives the second display hand 41 so that the second display hand 41 points to a position indicating the battery remaining amount meter 43c.

<Barometric pressure display mode>
When detecting that the button 15 has been pressed in a state where the display mode is the barometric pressure display mode, the control unit 100 outputs an operation start signal to the barometric pressure sensor 103 to cause the barometric pressure sensor 103 to start measuring the barometric pressure. A step motor (not shown) for driving the second display hand 41 is driven so that the hand 41 indicates a position indicating the character 43b of “MEAS”.

  The pressure sensor 103 starts measuring the pressure when receiving the operation start signal, and outputs the measurement result of the pressure to the control unit 100 when the measurement of the pressure is completed. When receiving the measurement result of the atmospheric pressure, the control unit 100 controls the stepping motor 51 and the like to display the measurement result of the atmospheric pressure using the 2:00 information display unit 7 and the measurement display hand 11.

At this time, for the combination of the measurement display hand 71 and the scales 74a to 74j, the control unit 100 multiplies the numerical values of the scales 74a to 74j by 10 ^{3 (= n)} (= 1000). Used as Further, the control unit 100 sets the numerical value of the scales 74a to 74j as a value obtained by multiplying the numerical value by 10 ^{2 (= n)} (= 100) for the combination of the measurement display hand 72 and the scales 74a to 74j. Used.
For this reason, when the measurement display hand 71 and the measurement display hand 72 indicate the positions shown in FIG. 4 in the atmospheric pressure display mode, an air pressure of 1400 hPa is displayed.

  Further, control unit 100 drives a step motor (not shown) that drives second display hand 41 so that second display hand 41 indicates a position indicating battery remaining amount meter 43c.

<Stopwatch function in time display mode>
When detecting that the button 13 or the button 15 is pressed in a state where the display mode is the time display mode, the control unit 100 starts the stopwatch function.

  When the stopwatch function is started, the control unit 100 controls the stepping motor 51 and the like to display the time measurement result (time) on the 2:00 information display unit 7 and the measurement display hand 11.

At this time, for the combination of the measurement display hand 71 and the scales 74a to 74j, the control unit 100 multiplies the numerical values of the scales 74a to 74j by 10 ^{1 (= n)} (= 10). Used as In addition, for the combination of the measurement display hand 72 and the scales 74a to 74j, the control unit 100 sets the numerical values of the scales 74a to 74j as a value obtained by multiplying the numerical value by 100 ^{(= n)} (= 1). Used.
For this reason, when the stopwatch function is executed in the time display mode and the measurement display hands 71 and 72 indicate the positions shown in FIG. 4, 14 minutes (min) are indicated. .

  Thereafter, when the control unit 100 detects that the button 13 or the button 15 is pressed during the execution of the stopwatch function, the control unit 100 stops measuring the time, and the measurement display hands 71 and 72 of the 2 o'clock information display unit 7 and the measurement display hands The hand movement with 11 is stopped.

  Further, control unit 100 drives a step motor (not shown) that drives second display hand 41 so that second display hand 41 indicates a position indicating battery remaining amount meter 43c.

Next, the entire electronic timepiece W will be described.
The electronic timepiece W receives a radio wave including time information, and corrects a display time based on the time information. In the electronic timepiece W, the dial 5 is arranged on the inner peripheral side of the dial ring 17, and a bezel 19 is arranged concentrically with the dial ring 17 on the outer peripheral side of the dial ring 17.

  The dial 4a of the 6:00 information display unit 4 has a first display area 44 and a second display area 43 as shown in FIG. The first display area 44 and the second display area 43 are arranged adjacent to each other so as not to overlap with each other.

  The second display area 43 is a fan-shaped range in which the center angle about the concentric axis 40 is θ1 (= 108 °).

  The first display area 44 is an arc-shaped area having a center angle θ2 (= 129 °) about the concentric axis 40. Each of the display areas 43 and 44 is divided into a plurality of display units by a rotation angle on the concentric axis 40.

  In the second display area 43, an area (43c) indicating the remaining battery level and areas (43a and 43b) indicating the operation state of the electronic timepiece W are provided. The second display hand 41 indicates the remaining battery level by indicating an area indicating the remaining battery level. The second display hand 41 indicates the operation state of the electronic timepiece W by indicating a region indicating the operation state of the electronic timepiece W.

  The operating state of the electronic timepiece W includes “wireless stop”, which means stopping reception of radio waves including time information, and measurement corresponding to the display mode displayed by the first display hand 42 (altitude, azimuth, air pressure, stopwatch, etc.). (Measurement of time by function) is being executed.

  In the present embodiment, the second display area 43 is provided with a battery remaining amount meter 43c, an icon 43a indicating that wireless communication is stopped, and a character 43b of "MEAS" indicating "measuring". The area where the character 43 b of “MEAS” is located is adjacent to the first display area 44.

  The second display hand 41 selectively displays the remaining battery level and the operation state of the electronic timepiece W by rotating about the concentric axis 40 in the second display area 43.

  On the other hand, the first display hand 42 is rotated in the first display area 44 about the concentric axis 40 to rotate the current display mode (time display mode, elevation display mode, barometric pressure display mode, azimuth display mode, option display mode). Display).

  Each display mode also indicates the type of the measured value in the display mode. For example, the time display mode indicates time or time as a type of measured value, the altitude display mode indicates altitude as a type of measured value, the barometric pressure display mode indicates barometric pressure as a type of measured value, and the azimuth display mode indicates , The direction is indicated as the type of the measured value, and the option display mode indicates the biological information as the type of the measured value.

  The second display hand 41 moves within a range of 108 ° from the “MEAS” position to the “E” position (empty; empty position) within a range of ± 54 ° around the “F” position (full position). The second information (the remaining battery level and the operation state of the electronic timepiece W) is displayed.

  When the user operates the button when the wireless function (the function of receiving radio waves including time information) cannot be used, such as when the user carrying the electronic timepiece W is on an airplane (for example, when the user 13 and the button 15), and the second display hand 41 points to the icon 43a indicating that the wireless communication is stopped.

The first display area 44 includes an area 44a of “TIME”, an area 44b of “ALT”, an area 44c of “BAR”, an area 44d of “COM”, and an area 44e of “OP”.
In the first display area 44, the first display needle 42 is displayed in the display unit of each display mode (“TIME” area, “ALT” area, “BAR” area, “COM” area, “OP” area). By instructing one of 44a to 44e alternatively, the current display mode is displayed.

  In the present embodiment, the display units 44a to 44e of each display mode are indicated by characters written in a band-shaped arc-shaped region. Specifically, “TIME” (time), “ALT” (elevation), “BAR” (barometric pressure), “COM” (compass: direction), and “OP” (option) are shown as the display units 44a to 44e. Have been.

The display mode displayed at the position indicated by the first display hand 42, that is, the display mode displayed in the first display area 44 can be switched by pressing the button 14.
For example, each time the button 14 is pressed once, the first display hand 42 rotates clockwise by 30 °. Therefore, every time the button 14 is pressed once, the display mode is changed from the time display mode (“TIME” mode) to the elevation display mode (“ALT” mode), the barometric pressure display mode (“BAR” mode), and the azimuth display mode. (“COM” mode) and an option display mode (“OP” mode).
When the button 14 is pressed in a state where the first display hand 42 points to the option display mode (“OP” mode), the first display hand 42 is reversed and the “TIME” area 44 a (the time display mode Area).

  In the example shown in FIG. 3, the second display hand 41 indicates the remaining battery level “F” (full), and the first display hand 42 indicates the time display mode.

  An information display section 5b for seeing through the date dial 6 displaying a calendar is formed in the direction of the 6:00 on the dial 4a of the 6:00 information display section 4. The information display unit 5b displays a calendar date, which is an example of the third information. The information display unit 5b is fixedly arranged on a straight line passing through the concentric axis 40 and connecting the 12 o'clock side and the 6 o'clock side, whereby a symmetrical design of the entire electronic timepiece W is realized.

According to the electronic timepiece W according to the present embodiment described above, the control unit 100 measures the physical quantities represented by numerical values (measured value of altitude, measured value of atmospheric pressure, measured value of pulse, and measurement of time by the stopwatch function). ) Are displayed using the measurement display hands 71 and 72, which are different from the hour hand 1 and the minute hand 2, and the scales 74a to 74j. At this time, the control unit 100 uses the numerical values of the scales 74a to 74j as values obtained by multiplying the numerical values of the scales 74a to 74j by 10 ⁿ .
The control unit 100 displays the first physical quantity (each of the measured value of the altitude, the measured value of the atmospheric pressure, and the measured value of the pulse) using the measurement display hands 71 and 72 and the scales 74a to 74j, and the second physical quantity. A different value is used as n described above when (measured value of time in the stopwatch function) is displayed using the measurement display hands 71 and 72 and the scales 74a to 74j.

As described above, the first physical quantity and the second physical quantity are displayed by using the measurement display hands 71 and 72 different from the hour hand 1 and the minute hand 2 and the scales 74a to 74j, so that the time is displayed by the hour hand 1 and the minute hand 2. In addition, the first physical quantity or the second physical quantity can be displayed.
Further, for example, the numerical value “1” of the scale is used as “1000” (= 1 × 10 ³ ) when the measurement display hand 71 indicates the first physical quantity, and “1” when displaying the second physical quantity. 10 "(= 1 × 10 ¹ ). Therefore, even when two physical quantities having different numbers of digits and different types are displayed using the pointer and the scale, by changing the digit corresponding to the numerical value of the scale, these two physical quantities can be displayed easily.
Note that n is not limited to the value described above, and can be changed as appropriate according to the displayed physical quantity.

  When the measurement display hand 11 indicates the north direction, the control unit 100 causes the measurement display hands 71 and 72 to display a scale 74a (numerical value “0”). The display using the measurement display hands 71 and 72 and the scales 74a to 74j (numerical display) by displaying the numerical value "0" by the measurement display hands 71 and 72 when the measurement display hand 11 displays the north direction. ) Can be shown to be invalid.

When grasping the state of the electronic timepiece W, the user visually recognizes the indicated position of the second display hand 41 to check the operation state and the remaining battery level of the electronic timepiece W, and also indicates the position of the first display hand 42. There is a possibility that the current display mode is confirmed by visually checking the position.
In the present embodiment, the first display area 44 indicated by the first display hand 42 and the second display area 43 indicated by the second display hand 41 are adjacent to each other.
Therefore, when grasping the state of the electronic timepiece W, the user can visually recognize the display mode displayed by the first display hand 42 and the operation state and the remaining battery level displayed by the second display hand 41 at a time. And the need to move the gaze greatly is reduced. Therefore, high visibility can be obtained for the display content of the first display hand 42 and the display content of the second display hand 41.

In the present embodiment, the first display hand 42 and the second display hand 41 rotate coaxially.
For this reason, space saving can be achieved as compared with the case where the first display hand 42 and the second display hand 41 rotate respectively on different axes.

In the present embodiment, the operation state displayed by the second display hand 41 includes a measuring state indicating that the measurement corresponding to the display mode displayed by the first display hand 42 is being executed. The area of the character 43 b of “MEAS” corresponding to the measuring state is adjacent to the first display area 44 indicated by the first display hand 42.
For this reason, the user can visually recognize, at a time, the display mode indicated by the first display hand 42 and the display indicating whether the measurement corresponding to the display mode is being executed.

In the present embodiment, an icon 43a indicating that the wireless communication is stopped is arranged next to “F” (full) of the battery remaining amount meter 43c.
Reception of radio waves including time information (wireless communication) uses relatively large power. Therefore, the condition for performing wireless communication is that the remaining battery level is close to full charge (“F”). Therefore, it can be estimated that the second display hand 41 has a high probability of pointing to “F” of the battery remaining meter 43c during the wireless communication. Therefore, in order to quickly switch from wireless communication to wireless stop, it is desirable to arrange the icon 43a indicating wireless stop next to “F” indicating the remaining battery level.

  In the present embodiment, in an area not overlapping with the second display area 43 and the first display area 44, the third information that displays the third information on a straight line passing through the concentric axis 40 and connecting the 12 o'clock side and the 6 o'clock side is provided. As a display area, an information display section 5b for displaying the date dial 6 of the calendar is fixedly arranged. Therefore, the symmetry of the design can be emphasized, and the stability of the design can be enhanced.

(Modification)
The present invention is not limited to the above-described embodiment. For example, various modifications as described below are possible. Further, one or a plurality of modifications arbitrarily selected from the following modification modes can be appropriately combined.

  In the above-described embodiment, as shown in FIG. 2 and FIG. 3, the battery remaining amount meter 43c indicates three of “E” (empty; empty), “M” (medium; middle), and “F” (full). Although the number of stages is divided, the number of stages of display of the remaining battery meter 43c is not limited to three and can be changed as appropriate.

  FIG. 6 is a diagram showing an example of a division angle of the battery remaining meter 43c when the display of the battery remaining meter 43c is divided into three stages as shown in FIGS. FIG. 7 shows the battery level meter 43c when the display of the battery level meter 43c is divided into four stages (“E”, “M1” (middle 1), “M2” (middle 2), and “F”). It is a figure showing an example of a division angle. Here, it is assumed that the relationship of “M1” <“M2” holds as the battery remaining amount. In both cases of the example shown in FIG. 6 and the example shown in FIG. 7, the battery remaining amount meter 43c is an area having a central angle of 54 ° on the dial 4a.

  As shown in FIG. 6, when the display of the battery remaining amount meter 43c is divided into three stages, the battery remaining amount meter 43c has a central angle of 27 ° on the dial 4a, and “E”, “M”, and “F”. Is divided into On the other hand, as shown in FIG. 7, when the display of the battery remaining amount meter 43c is divided into four stages, the battery remaining amount meter 43c displays “E” and “M1” at the central angle of 18 ° on the dial 4a. It is divided into “M2” and “F”.

At this time, it is desirable to move the second display hand 41 at every angle obtained by dividing 360 ° by 4n (n is a natural number less than 15). Hereinafter, this point will be described.
For example, when the second display hand 41 is configured to move at every angle obtained by dividing 360 ° by 4n, a drive mechanism used in many watches that moves the hands at every angle obtained by dividing 360 ° by 60. Although it is difficult to achieve commonality of parts and components, it is possible to increase the distance that the second display hand 41 moves by one hand movement, and to reduce the number of hand movements (ie, switching time) associated with display switching to 2/3. Become.

  In addition, without being limited to the present modification, in the case of a configuration in which the second display hand 41 is moved at an angle obtained by dividing 360 ° by 4n, the second display hand 41 is used to move the upper, lower, left, right ( Here, upper, lower, left, and right correspond to the 12 o'clock side, the 6 o'clock side, the 9 o'clock side, and the 3 o'clock side, respectively. In addition, even when the battery remaining amount meter 43c is configured as shown in FIGS. 6 and 7, for example, by configuring the second display hand 41 to move at every angle obtained by dividing 360 ° by 4n, Any display (three-part battery remaining meter and four-part battery remaining meter) can be supported.

In the 6 o'clock information display unit 4 shown in FIGS. 2 and 3, the area where the icon 43a is arranged and the area where the character 43b of “MEAS” is arranged may be switched as shown in FIG. Further, as shown in FIG. 9, a battery remaining amount meter 43c may be arranged between an area where the icon 43a is arranged and an area where the character "MEAS" 43b is arranged.
In the case of the examples shown in FIGS. 8 and 9, the area next to the battery remaining meter 43c is an area of the character 43b of "MEAS".

  It is conceivable that the measurement of the atmospheric pressure, the altitude, the azimuth, and the like is frequently used depending on the situation of the use scene at the time of climbing or sailing a sailboat (for example, the use scene at irregular weather). For this reason, when the area next to the battery remaining meter 43c is the area of the character 43b of “MEAS”, the pointing position of the second display hand 41 is moved from the area of the remaining battery meter 43c to the area of the character 43b of “MEAS”. The number of drive steps of the step motor 51 required for switching can be reduced. Thus, power consumption can be reduced.

  In the above embodiment, the arrangement order of the “ALT” region 44b, the “BAR” region 44c, and the “COM” region 44d can be changed as appropriate.

  Further, in the above-described embodiment and modified examples, the primary battery is described as an example of the power source of the driving source such as the step motor 51. However, the present invention is not limited to this, and the power source may be in any form. It may be. For example, a secondary battery may be used as a power supply. In this case, the secondary battery may be charged by an external commercial power supply 100V. In addition, a solar cell panel may be built in electronic timepiece W, and the secondary battery may be charged with electric power generated by the solar cell panel.

  In the above embodiment, the altitude sensor 101 and the barometric pressure sensor 103 are provided. However, a table indicating the relationship between the barometric pressure and the altitude is stored in a storage device (not shown), and the control unit 100 responds to the barometric pressure from the table. In the case of having a function of reading the altitude, the barometric pressure sensor (pressure sensor) 103 can also serve as the altitude sensor 101. Further, the control unit 100 may determine the altitude by calculating geographic information (position information) by positioning calculation using GPS, and display the determined altitude. In this case, the altitude sensor 101 can be omitted.

13-15: button, 51: step motor, 7: 2 o'clock information display unit, 71, 72: measurement display hand, 73: dial, 100: control unit, 101: altitude sensor, 102: azimuth sensor, 103: atmospheric pressure Sensor, 104: communication unit, 105: reception unit, 106: battery.

Claims (3)

A time display unit having an hour hand and a minute hand, and displaying time using the hour hand and the minute hand;
A first hand different from the hour hand and the minute hand,
An information display unit having numerical scales,
A control unit that displays a physical quantity represented by a numerical value using the first pointer and the scale;
A first display unit for displaying information different from the numerical value ,
The control unit includes:
The scale value is used as a value obtained by multiplying the scale value by 10 ⁿ (n is an integer of 0 or more),
A case where the first physical quantity represented by a numerical value is displayed using the first pointer and the scale, and a case where a second physical quantity represented by a numerical value and different from the first physical quantity is represented by the first pointer and the scale. In the case of using and displaying, the n is set to a different value ,
When the first display unit is displaying the information, the first indicator is instructed to indicate the scale indicated by a specific numerical value;
An electronic timepiece characterized by the above-mentioned. The first physical quantity is an altitude or an atmospheric pressure,
The second physical quantity is time;
The electronic timepiece according to claim 1, wherein: It said information electronic timepiece according to claim 1 or 2, characterized in that the specific orientation.

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