JP6349698B2 - RUNNING STATE DETECTION DEVICE, BEND ANGLE PASSING TIME ACQUISITION METHOD AND PROGRAM - Google Patents

Description

The present invention relates to a traveling state detection device , a turning time acquisition method, and a control program therefor for detecting and notifying where a current position is located on a preset passage route.

  In recent years, an increasing number of people enjoy running, such as jogging daily or participating in marathons. Small GPS-equipped electronic devices that record the courses and times run by such runners have appeared.

  In general GPS receivers, the accuracy of position data acquired by GPS varies. For example, even if the moving object which is the acquisition target of the position data runs in a straight line, the position data acquired at regular intervals is acquired by swinging to the left and right of the straight line.

  For this reason, when the movement distance of the runner is measured by taking the difference of the position data acquired at regular time intervals, the movement distance is measured longer than the actual distance.

  As a measure to reduce such errors in measurement distance, position data acquired at regular intervals is thinned out at preset time intervals and movement distances, thereby including many variations in the position data. It is possible to measure so that there is no.

  However, for example, if thinning is performed while the runner is passing a corner, a position data shortcut occurs before and after the corner, causing another problem that the travel distance according to the corner cannot be measured. To do.

  A host vehicle position correction system that corrects the host vehicle position calculated based on the detection output of the GPS sensor in accordance with the detection outputs of the distance sensor and the azimuth sensor has been considered (for example, see Patent Document 1).

  An in-vehicle navigation system that corrects the vehicle position calculated based on the detection output of the GPS sensor in accordance with the detection output of the geomagnetic sensor has been considered (for example, see Patent Document 2).

JP 2010-008095 A Japanese Patent Laid-Open No. 05-018773

  For example, in the marathon course, whether to run the left line, the right line, or the center line on each road included in the course is specified in advance. Full marathon, half marathon, etc. A predetermined distance is set. The distance from the start position to each check position is set with each corner included in the course as a check position.

  On the other hand, runners do not always run exactly along the prescribed line on each road in the marathon course, but sometimes meander or run on the opposite line. There is a natural shift between the runner's own travel distance. In addition, as described above, since the travel distance measured based on the position data from the GPS receiving device of the runner is longer than the actual distance, this does not directly match the prescribed distance on the course.

  Therefore, the measurement accuracy of the travel distance is corrected by correcting the travel distance measured based on the GPS receiver device for each corner (check position) based on the distance data set for the marathon course where the runner runs. However, in order to do so, it is necessary to accurately detect each corner (bent position) on the course.

  Although it is conceivable to accurately detect each turning angle on the marathon course by combining the positioning data detected by the GPS receiving device and the geomagnetic amount data detected by the geomagnetic sensor, the positioning data and geomagnetism can be detected in the first place. If the detection accuracy of the quantity data is poor, the corner cannot be detected.

The present invention has been made in view of such problems, and can accurately detect the turning angle at which a runner runs even when the detection accuracy of positioning data by a GPS receiver or the detection accuracy of geomagnetic quantity data by a geomagnetic sensor is poor. It is an object of the present invention to provide a traveling state detection device , a turning time acquisition method, and a control program thereof that are enabled.

A traveling state detection device according to the present invention is detected by a GPS receiver that detects a current position, a geomagnetic sensor that detects geomagnetism, current position data that is periodically detected by the GPS receiver, and the geomagnetic sensor. Data acquisition means for acquiring the geomagnetic data, accuracy determination means for determining the accuracy of the current position data acquired by the data acquisition means and the accuracy of the geomagnetic data, and the position detected by the GPS receiver GPS bend determining means for determining the passage of a turn based on a change in data, geomagnetic bend determination means for determining the passage of a turn based on a change in geomagnetic data detected by the geomagnetic sensor, and the GPS bend determination means when the passage of the corner is determined by said geomagnetism bend determining means, before Symbol GPS bend determining means Rising angle is passing the time it is determined that the geomagnetic bend time between time passage of street corner is determined in decision means, and the passage of the corner by the data in higher has been precision determined by the precision determination unit And transit time calculation means for setting the time close to the time at which the curve is judged to be the transit time of the corner.

A program according to the present invention is a program for controlling a computer of an electronic device having a GPS receiver that detects a current position and a geomagnetic sensor that detects geomagnetism, and the computer is periodically Data acquisition means for acquiring current position data detected by the GPS receiver and geomagnetic data detected by the geomagnetic sensor, accuracy of current position data acquired by the data acquisition means, and accuracy of geomagnetic data An accuracy determining means for determining the position, a GPS bend determining means for determining passage of a turn based on a change in position data detected by the GPS receiver, and a turn angle based on a change in geomagnetic data detected by the geomagnetic sensor. A geomagnetic bending judging means for judging the passage of the GPS, the GPS bending judging means and the geomagnetic When the passage of the corner is determined by the determining means rising, the time between the previous SL time pass corner is determined by the time passage of the corner is determined to the GPS bend determining means the geomagnetism bend determining means And a function that serves as a transit time calculation means that uses a time close to the time at which the turn of the corner is determined by the higher accuracy data determined by the accuracy determination means as the passage time of the turn. Yes.
According to the present invention, there is provided a method for acquiring a corner-passing time according to the present invention, which is a method for acquiring a corner-passing time of an electronic device having a GPS receiver that detects a current position and a geomagnetic sensor that detects geomagnetism. A data acquisition step for acquiring current position data detected by the unit and geomagnetic data detected by the geomagnetic sensor, and determining the accuracy of the current position data acquired by the data acquisition step and the accuracy of the geomagnetic data An accuracy determination step, a GPS bending determination step for determining the passage of a corner based on a change in position data detected by the GPS receiver, and a corner passage based on a change in geomagnetic data detected by the geomagnetic sensor. Determining the geomagnetic curve, determining the GPS curve and determining the GPS The time between the time at which the turn at the GPS turn judgment step is judged to pass at the turn at the GPS turn judgment step and the time at which the turn at the turn at the geomagnetic turn judgment step is judged when the turn at the turn judgment step is judged. And a transit time calculating step in which a time close to the time at which the turn of the corner is determined by the higher-accuracy data determined in the accuracy determination step is used as the transit time of the turn. Yes.

  According to the present invention, even when the detection accuracy of positioning data by a GPS receiver or the detection accuracy of geomagnetism data by a geomagnetic sensor is poor, it is possible to accurately detect the corner at which the runner runs.

1 is a front view showing an external configuration of a wristwatch type electronic apparatus 10 according to an embodiment of a traveling state detection device of the present invention. FIG. 2 is a block diagram showing a configuration of an electronic circuit of the wristwatch type electronic device 10. The figure which shows the specific example of the 3 axis | shaft local magnetic quantity data sampled and output by the geomagnetic sensor part 25 of the said wristwatch-type electronic device. The figure which shows the item of the map data (course information) 22b memorize | stored in the memory | storage device 22 of the said wristwatch-type electronic device 10. FIG. Schematic which shows an example of the running course memorize | stored as the map data (course information) 22b in the memory | storage device 22 of the said wristwatch-type electronic device 10. FIG. The figure which shows the memory | storage state of the reference direction data in the GPS reference direction memory 23e of the said wristwatch-type electronic device 10, and the present direction data in the GPS present direction memory 23f. The figure which shows the memory | storage state of the reference | standard geomagnetic amount data in the geomagnetic reference value (3-axis) memory 23g of the said wristwatch-type electronic device 10, and the present geomagnetic-value data in the geomagnetic present value (3-axis) memory 23h. 6 is a flowchart showing a running state detection process executed according to a control program 22a of the wristwatch type electronic device 10. 5 is a flowchart showing a check flag setting process for position data acquired from the GPS receiver 24 of the wristwatch type electronic device 10 at regular intervals. The flowchart which shows the movement distance measurement process accompanying the driving | running | working state detection process in the runner support mode of the said wristwatch-type electronic device. 6 is a flowchart showing an overall process of a bending determination process associated with a traveling state detection process in a runner support mode of the wristwatch type electronic device 10. 9 is a flowchart showing a GPS bending detection process for detecting a bending based on positioning data from the GPS receiving unit 24 in a bending determination process of the wristwatch type electronic device 10. 6 is a flowchart showing a geomagnetic bending detection process for detecting a bend based on geomagnetism data from a geomagnetic sensor unit 25 in a bending determination process of the wristwatch type electronic device 10. 7 is a flowchart showing an integrated bend detection process for finally determining the presence or absence of a bend based on the GPS bend detection process and the geomagnetic bend detection process in the bend determination process of the wristwatch type electronic device 10. A reference value update process for updating the reference direction data stored in the GPS reference direction memory 23e and the reference geomagnetism data stored in the geomagnetic reference value (3-axis) memory 23g in accordance with the bending determination process of the wristwatch-type electronic device 10. The flowchart which shows.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a front view showing an external configuration of a wristwatch type electronic apparatus 10 according to an embodiment of a traveling state detection device of the present invention.

  In addition, this driving | running | working state detection apparatus is realizable with portable terminal type electronic devices, such as a mobile telephone, a portable game machine, and portable PC other than the wristwatch type electronic device 10 demonstrated below.

  A key input unit 11 having a plurality of buttons for performing various mode settings, time adjustment instructions, start / stop instructions, and the like is provided on the side of the main body of the wristwatch type electronic device 10. Further, a display unit 12 for displaying contents according to the set mode is provided on the front surface of the main body. Reference numeral 13 denotes a wristband.

  This wristwatch-type electronic device 10 has a function suitable for use by a runner, a function to display a course map when running on a preset course, and how many kilometers from the start on the course A function to display the elapsed time, a function to display the elapsed time, a function to display how many kilometers from the current position on the course to the next checkpoint or goal, a function to display the passing time (lap time) per unit distance, etc. Have.

  FIG. 2 is a block diagram showing the configuration of the electronic circuit of the wristwatch-type electronic device 10.

  The electronic circuit of the wristwatch-type electronic device 10 includes a CPU (control unit) 21 that is a computer.

  The CPU 21 uses the RAM 23 as a working memory according to the electronic device control program 22a stored in the storage device 22 in advance or the electronic device control program 22a read from the outside via the input / output interface 28 and stored in the storage device 22. This program 22a controls the operation of each unit and executes various functions. This program 22a is a user operation signal from the key input unit 11 or the current position positioning (latitude / longitude) data based on reception by the GPS receiving unit 24, Alternatively, three-axis (X-axis, Y-axis, Z-axis) magnetic quantity data from the geomagnetic sensor unit 25, various sensor signals according to the user's movement from the motion sensor unit 26, or external via the input / output interface 28 It is activated in response to a communication signal from the device.

  The GPS receiving unit 24 receives and demodulates radio signals from a plurality of GPS satellites by the antenna 24a, and outputs information such as the latitude / longitude and time of the current location as positioning data every second.

  FIG. 3 is a diagram showing a specific example of the three-axis local magnetic quantity data sampled and output by the geomagnetic sensor unit 25 of the wristwatch-type electronic device 10.

  The geomagnetic sensor unit 25 of this embodiment has a triaxial geomagnetic sensor. For example, the local magnetic field data of the three axes (X axis, Y axis, Z axis) measured every 0.2 seconds are used for arm swinging. To eliminate noise due to influences, etc., it is averaged over 2 seconds, and the local magnetic data [μT] averaged over 2 seconds is output every second. Then, among the local magnetic quantity data output by the geomagnetic sensor unit 25, as shown by being surrounded by a range D, when the amount of change in two axes is larger than a certain threshold, it is detected as a turning angle.

  The motion sensor unit 26 includes an acceleration sensor and a gyro sensor, and measures or detects a magnitude of a movement, a change in direction, a walking movement, and the like associated with the movement of the user based on these sensor signals and outputs them.

  The input / output interface 28 is connected to, for example, an external PC, and inputs / outputs various data directly to / from the external PC or to / from a server device on the Internet via the external PC.

  FIG. 4 is a diagram showing items of map data (course information) 22b stored in the storage device 22 of the wristwatch type electronic device 10. As shown in FIG.

  FIG. 5 is a schematic diagram showing an example of a running course stored as map data (course information) 22b in the storage device 22 of the wristwatch type electronic device 10. As shown in FIG.

  In addition to the electronic device control program 22a, the storage device 22 stores map data (course information) 22b of a plurality of running courses, such as a jogging course and a marathon competition practice course before the user runs. The For example, as shown in FIG. 4 and FIG. 5, this data is composed of position data from the start position to each check position (turning corner in the present embodiment) that is a passing point on the way and the goal position. The data includes latitude / longitude data for each position and distance data indicating the distance from the start position. The map data (course information) 22b is created from a map displayed by a user on a personal computer using predetermined software, or provided as data from a tournament organizer or the like, and is transmitted via the input / output interface 28 of the wristwatch-type electronic device 10. And stored in the storage device 22. The distance data is not preliminarily converted into data, but may be calculated based on latitude / longitude data in the process.

  The RAM 23 includes a display data memory 23a, a current position memory 23b, a final check flag position memory 23c, a total movement distance memory 23d, a GPS reference direction memory 23e, a GPS current direction memory 23f, a geomagnetic reference value (3-axis) memory 23g, and a geomagnetism. A current value (3-axis) memory 23h, a next turn angle memory 23i, a step count memory 23j, a stride length memory 23k, a GPS accuracy weighting memory 23p, a geomagnetic accuracy weighting memory 23q, and the like are provided.

  In the display data memory 23a, display data for the display unit 12 is developed and stored as image data in a bitmap format.

  The current position memory 23b stores, for example, the movement position of the user (runner) according to the running course selected from the map data (course information) 22b. The movement position is obtained from the GPS receiving unit 24. Position data corresponding to the positioning data is stored.

  Here, it is possible to calculate the moving distance between the current position data obtained from the GPS receiver 24 and the previous position data, and add the difference to calculate the total moving distance. Data variations (errors) accumulate and an error occurs with the actual total travel distance. For this reason, in the position data obtained from the GPS receiver 24 every second, a check flag is set every certain period (for example, 4 seconds) during linear running, and the position data in which the check flag is set. Only the movement distance calculated by the difference between them is valid. When the runner passes a corner in the middle of the predetermined period, the distance traveled during that period is calculated as a shortcut, and therefore, if there is a corner passage determination to be described later, the GPS receiver 24 at that time. A check flag is also set for the position data obtained from (1). As a result, the position data including the error obtained by the GPS receiver 24 is linearized as much as possible to calculate the moving distance, and the moving distance where the course is bent can be calculated with high accuracy.

  In the final check flag position memory 23c, the latest position data (current position) in which the check flag is set is stored as the final check flag position.

  In the total movement distance memory 23d, for example, the movement distance of the user (runner) according to the running course selected from the map data (course information) 22b is stored.

  Further, the wristwatch-type electronic device 10 calculates whether or not the runner's running direction is bent based on the current position data acquired every second from the GPS receiver 24 and the previous position data. A function to detect based on a change in the direction data [deg] (change more than a threshold value from the reference direction data [deg]), and the current 3-axis averaged for 2 seconds obtained from the geomagnetic sensor unit 25 every second. It has a function of detecting based on the change in local magnetic quantity data [μT] (at least a threshold value change from the reference geomagnetic quantity data [μT] of two axes).

  FIG. 6 is a diagram showing a storage state of the reference direction data in the GPS reference direction memory 23e of the wristwatch type electronic device 10 and the current direction data in the GPS current direction memory 23f.

  In the GPS reference direction memory 23e, the reference direction data [deg] for detecting the bend in the direction in which the runner runs corresponds to the output timing (every second) of the positioning data acquired by the GPS receiver 24. In the initial stage, the current direction data [deg] is stored as the reference direction data [deg] as it is, and then updated to the current direction data [deg] when the bend is detected each time the bend is detected. And memorized. In the present embodiment, the direction data [deg] is a clockwise angle with true north as 0.

  In the GPS current direction memory 23f, current direction data calculated according to the current position data and the previous position data corresponding to the output timing (every second) of the positioning data acquired by the GPS receiver 24. [deg] is stored.

  In the present embodiment, it is assumed that the bending detection threshold based on the positioning data from the GPS receiver 24 is set to [50 °], and the current direction data [deg] with respect to the reference direction data [deg]. Is changed to the above-mentioned bend detection threshold [50 °] or more, it is determined that the runner has passed the bend corner.

  In the specific example shown in FIG. 6, when the initial reference direction data (= current direction data) is 55 [deg], the current direction data calculated by the 55th sampling is 108 [deg]. Since the amount of change is equal to or greater than the threshold value [50 °], it is detected that the runner has passed the corner. Then, the current direction data 108 [deg] when the turning angle is detected is updated as new reference direction data.

  FIG. 7 shows one axis among the storage states of the reference geomagnetic value data in the geomagnetic reference value (3-axis) memory 23g and the current geomagnetic value data in the geomagnetic current value (3-axis) memory 23h of the wristwatch type electronic device 10. It is a figure which shows the data of.

  In the geomagnetic reference value (3-axis) memory 23g, the bend in the direction in which the runner runs is detected corresponding to the output timing (1 second) of the geomagnetism data [μT] acquired by the geomagnetic sensor unit 25. Reference geomagnetism data [μT] is stored for each of the three axes (X axis, Y axis, Z axis), and initially, the current geomagnetism data [μT] is directly used as the reference geomagnetism data [μT]. After that, every time a bend is detected, it is updated and stored in the current geomagnetic quantity data [μT] when the bend is detected.

  In the geomagnetic current value (3-axis) memory 23h, each of the three axes (X-axis, Y-axis, Z-axis) corresponding to the output timing (every second) of the geomagnetism data acquired by the geomagnetic sensor unit 25 is stored. The current geomagnetic data [μT] averaged for 2 seconds is stored.

  In the present embodiment, it is assumed that the bending detection threshold based on the three-axis local magnetic quantity data from the geomagnetic sensor unit 25 is set to [15 μT], and the reference geomagnetic quantity data [μT] at least for the two axes. On the other hand, if the current geomagnetism data [μT] has changed to the bend detection threshold [15 μT] or more, it is determined that the runner has passed the bend.

  In the specific example shown in FIG. 7, when the initial reference geomagnetism data (= current geomagnetism data) is 10 [μT], the current geomagnetism data output for the 55th time is 27 [μT]. Since the change amount is equal to or greater than the threshold value [15 μT], it is detected that the runner has passed the turning corner, and the current geomagnetic amount data 27 [μT] when the turning corner is detected is updated as new reference geomagnetic amount data. It is shown that.

  When any running course stored as the map data (course information) 22b is set in the next corner memory 23i, latitude / longitude data and distance data corresponding to the first check position of the map data 22b are set. Is set (stored) by default, and the check is performed according to the bending determination based on the positioning data acquired from the GPS receiving unit 24 or the geomagnetic amount data from the geomagnetic sensor unit 25 as the user (runner) moves. Each time it is determined that the position has been reached, latitude / longitude data and distance data corresponding to the next check position are set (stored).

  The step count memory 23j stores step count data counted based on the sensor signal output from the motion sensor unit 26 in accordance with the movement of the user (runner).

  The stride memory 23k stores stride data calculated based on the moving distance between a certain point (position) and the number of steps.

  In the GPS accuracy weighting memory 23p, a weighting value corresponding to the detection accuracy of the positioning data calculated in the bending determination based on the positioning data from the GPS receiving unit 24 is stored.

  The geomagnetism accuracy weighting memory 23q stores a weighting value corresponding to the detection accuracy of the geomagnetism data calculated when determining the bending based on the geomagnetism data from the geomagnetic sensor unit 25.

  The analysis data storage unit 27 includes positioning data from the GPS receiving unit 24, triaxial magnetic quantity data from the geomagnetic sensor unit 25, sensor signals from the motion sensor unit 26, and the current position ( 23b), total movement distance (23d), number of steps (23j), step length (23k), and lap time analyzed based on elapsed time from the start, distance to goal, average speed, momentum, and the like are stored.

  The wristwatch type electronic device 10 determines the positioning accuracy of the positioning data obtained from the GPS receiver 24 based on PDOP (Position Dilution of Precision), and accompanies the movement between the two points according to the positioning accuracy. It has a function of weighting the direction calculation (detection) accuracy. The PDOP is an index of the geometrical arrangement of the satellites, and is called a position accuracy deterioration degree. When the value is small, the positioning accuracy is high, and when the value is large, the positioning accuracy is low.

  Specifically, the PDOP value changes to “10.0”, where “1.0” is the minimum value, and is normally “2.0”, and is determined as “positioning accuracy is good”. If the positioning data of the PDOP “2.0” or less is used at these two points when moving from to the second point, the direction calculation (detection) accuracy weighting value associated therewith is set to “5”, and the PDOP If positioning data of “4.0” or higher is used at two points, the weight value of direction calculation (detection) accuracy associated therewith is set to “1”. The weighting value is stored in the GPS accuracy weighting memory 23p.

  The wristwatch-type electronic device 10 determines and weights the accuracy of the three-axis local magnetic quantity data obtained from the geomagnetic sensor unit 25 according to fluctuations caused by the disturbance of the local magnetic quantity data. Has the function of

  Specifically, the detected value of the geomagnetic amount data is substantially constant, but fluctuation is caused by the surrounding environment. If this fluctuation is about ± 10 [μT], it is determined that the accuracy is good and the weighting value is determined. Is set to “5”, and if it is ± 100 [μT] or more, it is determined that the accuracy is deteriorated due to effects other than bending such as arm swing, and the weighting value is set to “1”. The weighting value is stored in the geomagnetic accuracy weighting memory 23q.

  In the wristwatch-type electronic device 10 configured as described above, the CPU 21 controls the operation of each part of the circuit according to the instructions described in the electronic device control program 22a, and the software and hardware operate in cooperation. The functions described in the following operation explanation are realized.

  Next, the runner support function of the wristwatch type electronic device 10 having the above-described configuration will be described.

  FIG. 8 is a flowchart showing a running state detection process executed according to the control program 22a of the wristwatch type electronic device 10.

  When the operation mode is set to the runner support mode according to the electronic device control program 22a activated in response to the user operation of the key input unit 11, the data memories 23b to 23k in the RAM 23 are reset and the user is now A course setting message that prompts the user to set a running course for the (runner) is displayed on the display unit 12.

  In accordance with the course setting message, when a running course desired by the user selected from the map data (course information) 22b of the storage device 22 or a running course provided by a marathon event organizer or the like is set (step S1). The latitude / longitude data and distance data corresponding to the first check position of the set course are set (stored) in the next corner memory 23i (step S2).

  When the start button is pressed at the start position and running according to the set course is started (step S3 (Yes)), the operations of the GPS receiving unit 24, the geomagnetic sensor unit 25, and the motion sensor unit 26 are performed. Is started (step S4).

  Then, according to the travel distance measurement process described later with reference to FIGS. 9 and 10, the travel distance from the start of running is calculated based on the positioning data acquired from the GPS receiver 24 and stored in the total travel distance memory 23d. At the same time (step SA), the elapsed time is calculated (step S5).

  At this time, from the movement distance from the start stored in the total movement distance memory 23d, the calculated elapsed time, the lap time, and the distance data corresponding to the first check position stored in the next turn memory 23i, The distance to the next check position (CP) after subtracting the total movement distance, the distance to the goal by subtracting the total movement distance from the set course distance data, and the like are displayed on the display unit 12 (see FIG. 1). .

  The motion (running) motion of the runner is analyzed based on the sensor signal of the acceleration sensor acquired from the motion sensor unit 26, and the number of steps from the start of the running is measured and stored in the step count memory 23j (step S6).

  Then, according to the bending determination process described later with reference to FIGS. 11 to 15, the user (runner) makes a turn based on the positioning data acquired from the GPS receiving unit 24 or the geomagnetic data acquired from the geomagnetic sensor unit 25. It is determined whether or not is bent (step SB).

  Here, in a state where it is not determined that the user has made a turn (Step S7 (No)) and in a state where it is not determined that the stop button has been pressed (Step S8 (No)), the total movement distance from the start of the running is calculated. The process, the elapsed time calculation process, and the step count measurement process are repeatedly executed, and the total moving distance, elapsed time, lap time, and the next check position (CP) and the distance to the goal are sequentially updated and displayed (steps). SA, S5, S6).

  Thereafter, the user (runner) makes a turn (here, the first check position) based on the positioning data acquired from the GPS receiver 24 or the geomagnetism data acquired from the geomagnetic sensor 25 in accordance with the bending determination process described later. ) (Step SB, S7 (Yes)), the current position (latitude / longitude) data corresponding to the positioning data from the GPS receiver 24 stored in the current position memory 23b is The latitude / longitude data corresponding to the first check position set in the next corner memory 23i is corrected (step S9). This is because the position obtained by GPS may have an error of several meters to several tens of meters depending on the reception situation, and is detected by passing through a corner and corrected to an accurate position.

  At the same time, the travel distance data stored in the total travel distance memory 23d is corrected to the distance data corresponding to the first check position set in the next turn memory 23i (step S10). ). This is because an error occurs in the position error obtained by GPS and also in the distance calculated from the output of the motion sensor unit 26, so that it is detected that the vehicle has passed a corner and is corrected to an accurate value.

  Then, the distance from the start position to the first check position set in the next turn angle memory 23i is divided by the actual number of steps to the first check position stored in the step count memory 23j. The user's stride is calculated and stored in the stride memory 23k (step S11).

  Then, latitude / longitude data and distance data corresponding to the next check position (here, the second check position) are set (stored) in the next corner memory 23i (step S12).

  At this time, the distance corresponding to the first check position is subtracted from the distance corresponding to the second check position or the distance of the set course, and the distance to the next check position (CP) according to the user operation. Or the distance to the goal is displayed on the display unit 12.

  Thereafter, the process returns to the process from step SA, and the total movement distance is calculated based on the positioning data from the GPS receiving unit 24 until it is determined that the vehicle has turned the corner corresponding to the second check position. And the update process, the update process of elapsed time, and the step count measurement process based on the sensor signal from the motion sensor unit 26 are repeatedly executed (steps SA to S8 → SA).

  Thereafter, it is determined that the second check position, the third check position,..., And the turn corresponding to the next check position set in the next turn angle memory 23i are turned (step S7 (Yes)). Each time, the latitude / longitude data of the current position stored in the current position memory 23b is corrected according to the latitude / longitude data of the check position (step S9), and stored in the total movement distance memory 23d. The process of correcting the total movement distance data according to the distance data of the check position (step S10), the process of calculating the latest stride (step S11), and the process of setting the next check position (step S12) are repeatedly executed. Is done.

  For this reason, for example, as shown in FIG. 5, the total travel distance after the start based on the set running course is defined in the running course every time the check positions 1, 2,. Since the correction is made in accordance with the distances to the respective check positions, the positioning data obtained from the GPS sensor unit 24 as the movement distance to the next check position after passing through the check position (difference of sampled position data) Even if calculated and added based on the above, it can be calculated and displayed as a sufficiently high-precision moving distance.

  Next, a travel distance measurement process (step SA) for calculating a travel distance from the start of running based on the positioning data acquired from the GPS receiver 24 in accordance with the travel state detection process described with reference to FIG. This will be described in detail.

  FIG. 9 is a flowchart showing a check flag setting process for position data acquired from the GPS receiver 24 of the wristwatch type electronic device 10 at regular intervals.

  This check flag setting process is executed in response to the position data being acquired from the GPS receiver 24 at regular time intervals (1 second), and the bending determination described later with reference to FIGS. According to the processing, when it is determined that the user (runner) has made a turn (step A11 (Yes)), and the determination that the turn has been made is not longer than a certain period T (for example, 4 seconds) (step A12 (Yes)). ), A check flag is set in the position data stored in the current position memory 23b (step A13). On the other hand, when it is not determined that the vehicle is bent (step A11 (No)) and it is not determined that the vehicle has not been bent for a certain period T or more (step A12 (No)), the position data stored in the current position memory 23b is stored. The check flag is not set (step A14).

  Then, with respect to the traveling direction based on the previous position data and the current position data acquired from the GPS receiver 24, the value of the angle changed from the immediately preceding traveling direction is determined (step A15).

  Here, when it is determined that the traveling direction has changed within a range of 0 ° to 5 °, which is substantially straight, the predetermined flag for setting the check flag by determining that there has been no turn over the predetermined period T. The interval of the period T is extended twice (2T) (step A16a). Thereby, when it is determined that the traveling direction is a substantially straight line, the position data including the error obtained by the GPS receiving unit 24 is made as straight as possible so that the movement distance can be calculated with higher accuracy. .

  When it is determined that the traveling direction has changed within a range of 10 ° to 20 ° corresponding to a gentle curve, the check flag is set by determining that there has been no turn over the predetermined period T. The interval of the fixed period T is shortened to one half (T / 2) (step A16b). As a result, when the traveling direction is not determined as a turning angle, but when it is determined that the course is gently turning, the setting distance of the check flag is shortened so that the moving distance can be calculated more accurately.

  On the other hand, when it is determined that the traveling direction has changed outside the ranges of 0 ° to 5 ° and 10 ° to 20 °, the interval of the predetermined period T is not changed (step A16c). As a result, when it is impossible to determine whether the traveling direction is a substantially straight line or a gentle curve, the processing is left to the determination of whether or not the vehicle is turning (step A11).

  FIG. 10 is a flowchart showing the movement distance measurement process associated with the running state detection process in the runner support mode of the wristwatch type electronic device 10.

  When position data is acquired from the GPS receiver 24 at regular time intervals (one second) and stored in the current position memory 23b, the position data in which the final check flag stored in the final check flag position memory 23c is set. And a moving distance corresponding to the difference between the position data stored in the current position memory 23b and the position data stored in the current position memory 23b (step A21).

  Here, the current total travel distance is calculated by adding the travel distance calculated this time to the total travel distance stored in the total travel distance memory 23d with the previous travel distance measurement process, and the current total travel distance is calculated. When it is confirmed that the distance is longer than the previous total travel distance (step A22 (Yes)), the total travel distance stored in the total travel distance memory 23d is updated to the current total travel distance (step A23). ).

  If the check flag is set in the position data stored in the current position memory 23b (step A24 (Yes)), the position data is the final check flag position memory as the position data in which the final check flag is set. 23c (step A25).

  As a result, the position data including the error obtained by the GPS receiving unit 24 can be calculated as a straight line or a substantially straight line as much as possible so that the moving distance can be accurately calculated, and the course is gently bent. The moving distance can be calculated with high accuracy.

  In addition, when the positioning accuracy of the positioning data acquired from the GPS receiving unit 24 is poor or when the positioning data itself is not acquired, the number of steps (23j) and the step length (22k) acquired based on the sensor signal from the motion sensor unit 26. Thus, the movement distance is calculated, and the calculated movement distance is added to the total movement distance so far and updated.

  Next, with the running state detection process described with reference to FIG. 8, the runner has passed a corner based on the positioning data acquired from the GPS receiver 24 or the geomagnetic data acquired from the geomagnetic sensor 25. The bending determination process (step SB) for determining whether or not will be described in detail.

  FIG. 11 is a flowchart showing the entire bending determination process associated with the running state detection process in the runner support mode of the wristwatch type electronic device 10.

  This bend determination process is executed in correspondence with the positioning data sampling interval (for example, 1 second) by the GPS receiver 24, and a GPS bend detection process (step B1) described later with reference to FIG. , Geomagnetic bending detection processing (step B2) described with reference to FIG. 13, integrated bending detection processing (step B3) described with reference to FIG. 14, and reference value update processing described with reference to FIG. (Step B4).

  FIG. 12 is a flowchart showing a GPS bend detection process for detecting a bend based on the positioning data from the GPS receiver 24 in the bend determination process of the wristwatch type electronic device 10.

  When positioning data is acquired from the GPS receiver 24 every predetermined time (one second), the current positioning data and the previous positioning data are based on the value of the PDOP (for example, “1.0” to “10.0” or more). Weighting values “5” to “1” indicating whether the direction calculation accuracy is good or bad based on the above are calculated (step B11a), and it is determined whether or not the weighting value is equal to or greater than a prescribed value (eg, “2”). (Step B11b).

  Here, if it is determined that the weighting value indicating whether the direction calculation accuracy is good or bad is greater than or equal to a specified value (step B11b (Yes)), the current position data and the previous position data acquired from the current positioning data. Based on the movement vector (current direction data [deg]) is calculated and stored in the GPS current direction memory 23f (see FIG. 6) (step B12).

  Then, a difference (change) between the reference direction data [deg] stored in the GPS reference direction memory 23e (see FIG. 6) and the current direction data [deg] is calculated (step B13), and the current value is calculated from the reference direction. It is determined whether or not the change in the direction is equal to or greater than a preset bend detection threshold [50 °] (step B14).

  Here, if it is determined that the change from the reference direction data [deg] to the current direction data [deg] has reached the bending detection threshold [50 °] or more (step B14 (Yes)), the runner determines the turning angle in the GPS. It is detected that it has passed, and a flag indicating this is stored in the buffer in the RAM 23 for 3 seconds (step B15).

  On the other hand, when it is determined in step B11b that the weighting value indicating whether the direction calculation accuracy is good or bad is not equal to or greater than a predetermined value (step B11b (No)), and in step B14, the reference direction data is changed to the current direction data. When it is determined that the change in the value is less than the threshold value (step B14 (No)), it is processed as non-detection of bending by GPS (step B16).

  In the bending detection (GPS) process, the current direction data (movement vector) is calculated from the previous position data and the current position data acquired from the GPS receiving unit 24. However, the current vector is calculated by calculating the Doppler velocity vector. It is good also as a structure which estimates direction data.

  FIG. 13 is a flowchart showing a geomagnetic bending detection process for detecting a bend based on the geomagnetism data from the geomagnetic sensor unit 25 in the bending determination process of the wristwatch type electronic device 10.

  When geomagnetism data is acquired from the geomagnetic sensor unit 25 at regular time intervals (1 second), the value is determined according to fluctuations caused by disturbance of the value of the geomagnetism data (for example, ± 0 to ± 100 [μT] or more). The weighting values “5” to “1” indicating whether the accuracy is good or bad are calculated (step B21a), and it is determined whether or not the weighting value is equal to or greater than a specified value (for example, “2”) (step B21b). .

  Here, if it is determined that the weighting value indicating the accuracy of the geomagnetic data is greater than or equal to a specified value (step B21b (Yes)), measurement is performed every 0.2 seconds with the movement for 2 seconds immediately before that. An average value (2-second average) of the geomagnetic amount data thus calculated is calculated and stored in the geomagnetic current value (3-axis) memory 23h (see FIG. 7) as current geomagnetic amount data [μT] (step B22).

  Then, the reference geomagnetism data [μT] stored in the geomagnetic reference value memory (3-axis) 23g (see FIG. 7) and the current geomagnetism data [μT] stored in the geomagnetic current value (3-axis) memory 23h. Is calculated (step B23), and it is determined whether or not the change from the reference geomagnetism to the current geomagnetism is equal to or greater than a preset bending detection threshold [15 μT] (step B24).

  Here, the change from the corresponding reference geomagnetism data [μT] to the current geomagnetism data [μT] is more than the bending detection threshold [15 μT] for at least two of the three geomagnetic current data [μT]. If it is determined that it has become (step B24 (Yes)), it is detected that the runner has passed the corner in geomagnetism, and a flag indicating this is stored in the buffer in the RAM 23 for 3 seconds (step B25).

  On the other hand, when it is determined in step B21b that the weighting value indicating the accuracy of the geomagnetic amount data acquired from the geomagnetic sensor unit 25 is not equal to or greater than a specified value (step B21b (No)), and the step B24 If it is determined that the change from the reference geomagnetism data to the current geomagnetism data is less than the threshold for at least two of the three-axis magnetism (step B24 (No)), no bending due to geomagnetism is detected. Processed as detection (step B26).

  FIG. 14 is a flowchart showing an integrated bend detection process for finally determining the presence or absence of a bend based on the GPS bend detection process and the geomagnetic bend detection process in the bend determination process of the wristwatch type electronic device 10.

  First, the runner moves depending on whether there is a change in the position data acquired from the GPS receiver 24 or whether the runner's running motion is detected by various sensor signals acquired from the motion sensor 26. It is determined whether the vehicle is stopped or stopped (step B31).

  Here, when it is determined that the runner is not stopped but moving (step B31 (No)), it is determined whether or not passage of the runner's curve is detected by the GPS curve detection process or the geomagnetic curve detection process. (Steps B32 and B33).

  If it is determined by the GPS curve detection process that a runner's curve has been detected (step B32 (Yes)), a flag indicating the detection of a curve angle due to geomagnetism is stored in the buffer in the RAM 23 by the geomagnetic curve detection process. Is determined, that is, whether passage of a corner is detected by geomagnetism within the past 3 seconds (step B34a).

  Here, when it is determined that the flag indicating the detection of the corner due to the geomagnetism is not stored in the buffer in the RAM 23 and the passage of the corner due to the geomagnetism is not detected within the past 3 seconds (step B34a (No)). ), It is determined by the GPS detection that the runner has passed a corner (step B36).

  On the other hand, if the flag indicating the detection of the corner by the geomagnetism is stored in the buffer in the RAM 23 and it is determined that the passage of the corner is also detected by the geomagnetism within the past 3 seconds (step B34a (Yes)). ), A weighting value indicating the accuracy of the direction calculation calculated when detecting the turning of the corner by the GPS, and a weighting value indicating the accuracy of the geomagnetic quantity data calculated when detecting the passing of the corner by the geomagnetism. The time at which the passage of the corner is detected is corrected according to the ratio (step B35).

  Specifically, for example, the detection time of the turn of the corner by the GPS is [0: 0: 3], the weight value of the direction calculation accuracy is “1”, and the passage detection time of the turn by the geomagnetism is If it is [0: 0: 0] 3 seconds before and the weight value of the accuracy of the geomagnetism data is “2”, the passing detection time of the current corner is the ratio of the weight value “1: 2 "is corrected to [0 hour 0 minute 1 second].

  Then, it is finally determined that the runner has passed the corner at the corrected passage detection time (step B36).

  If it is determined that the runner's turn has been detected by the geomagnetic bend detection process instead of the GPS bend detection process (step B33 (Yes)), the GPS bend detection process causes a GPS in the buffer in the RAM 23 to be detected. It is determined whether or not a flag indicating the detection of a turning angle is stored, that is, whether or not passing of a turning angle is detected by GPS within the past 3 seconds (step B34b).

  If it is determined that the GPS corner detection flag is not stored in the buffer in the RAM 23 and the GPS corner detection is not detected within the past 3 seconds (step B34b (No)). ), It is determined by the geomagnetic detection that the runner has passed a corner (step B36).

  On the other hand, if a flag indicating the detection of a corner by GPS is stored in the buffer in the RAM 23, and it is determined that the passage of the corner has been detected by the GPS within the past 3 seconds (step B34b (Yes)). ), A weighting value indicating the accuracy of the geomagnetic quantity data calculated when detecting the passing of the corner by the geomagnetism, and a weighting value indicating the accuracy of the direction calculation calculated when detecting the passing of the corner by the GPS The time when the passage of the corner is detected is corrected according to the ratio (step B35).

  Specifically, as described above, for example, the detection time of the turn of the bend by the geomagnetism is [0: 0: 3], the weight value of the geomagnetic data accuracy is “2”, and the turn of the turn by the GPS is When the passage detection time is [0: 0: 0] 3 seconds before and the weight value of the direction calculation accuracy is “1”, the passage detection time of the current corner is the ratio of the weight value “ It is corrected to [0: 0: 2] according to 2: 1 ”.

  Then, it is finally determined that the runner has passed the corner at the corrected passage detection time (step B36).

  On the other hand, when it is determined in step B31 that the runner is stopped (step B31 (Yes)), the passage of the runner's corner is detected in either the GPS curve detection process or the geomagnetic curve detection process. If it is determined that there is not (step B32, B33 (No)), it is processed as bending non-determination (step B37).

  When such a turn detection process detects a turn at a turn within 3 seconds by both GPS and geomagnetism, the turn detection time at the turn is corrected according to the weighting ratio of the respective detection accuracy. Corresponding to the corrected time, the total travel distance after the start based on the set running course is corrected according to the distance specified in the running course, so that the GPS and the geomagnetism Even when the detection accuracy of both is poor, it is possible to accurately detect the turning angle where the runner runs and display it as a sufficiently high-precision moving distance.

  15 updates the reference direction data stored in the GPS reference direction memory 23e and the reference geomagnetic quantity data stored in the geomagnetic reference value (3-axis) memory 23g in accordance with the bending determination process of the wristwatch-type electronic device 10. It is a flowchart which shows a reference value update process.

  In this reference value update process, first, when it is determined that either the GPS curve detection process or the geomagnetic curve detection process detects passage of a corner of a runner (step B41 (Yes) or B42 (Yes)). The current direction data [deg] stored in the GPS current direction memory 23f is stored and updated as it is as the reference direction data [deg] of the GPS reference direction memory 23e and stored in the geomagnetic current value (3-axis) memory 23h. The current geomagnetism data [μT] is stored and updated as is as the reference geomagnetism data [μT] in the geomagnetic reference value (3-axis) memory 23g (step B43).

  Further, in steps B11a and B11b in the GPS bending detection process (see FIG. 12), the weight value of the direction calculation accuracy based on the positioning data acquired from the GPS receiving unit 24 is returned from less than the specified value to more than the specified value. If it is determined (step B44 (Yes)), the current direction data [deg] stored in the GPS current direction memory 23f with the return of the positioning accuracy is directly used as the reference direction data [deg] of the GPS reference direction memory 23e. ] Is updated and stored (step B45).

  Further, in steps B21a and B21b in the geomagnetic bending detection process (see FIG. 13), the weight value of the accuracy of the three-axis local magnetic quantity data acquired from the geomagnetic sensor unit 25 is changed from less than the specified value to more than the specified value. Even when it is determined that the geomagnetism data is restored (step B44 (Yes)), the current geomagnetism data [μT] stored in the geomagnetism current value (3-axis) memory 23h with the restoration of the geomagnetism data accuracy is directly used as the geomagnetic reference It is updated and stored as reference geomagnetic data [μT] in the value (3-axis) memory 23g (step B45).

  Therefore, according to the running state detection function in the runner support mode of the wristwatch-type electronic device 10 having the above-described configuration, the current direction data based on the positioning data acquired by the GPS receiver 24 every predetermined time (for example, 1 second). And the geomagnetism data acquired by the geomagnetic sensor unit 25 are compared with the corresponding reference direction data and the reference geomagnetism data, respectively, and it is determined that any of them has changed by a predetermined detection threshold value or more. Detects that the runner has passed a corner. At this time, the accuracy of the positioning data and the accuracy of the geomagnetic quantity data are determined, and weight values corresponding to the respective accuracy are calculated. And when it is detected by both the positioning data and the geomagnetic amount data that the runner has passed a turning angle within the last 3 seconds, the weighting value according to the accuracy of the positioning data and the geomagnetic amount data The passing detection time of the corner is corrected in accordance with the ratio of the weighting value corresponding to the accuracy of.

  Therefore, in the running course arbitrarily set by the user, even when the detection accuracy of the positioning data and geomagnetic quantity data is poor, the time when the runner has passed the corner on the course can be obtained accurately. The position data and distance data at the corresponding check position can be corrected to an accurate value.

  Further, according to the running state detection function in the runner support mode of the wristwatch-type electronic device 10 having the above-described configuration, when it is not detected that the runner has passed a corner for a predetermined period T or more, the GPS receiving unit 24, a check flag is set at the current position corresponding to the positioning data acquired by 24, and the distance data up to the check position corresponding to the current position is added to the distance data at the check position corresponding to the turning angle to obtain the travel distance. calculate. When the traveling direction based on the previous position data according to the positioning data and the current position data is within a range of 0 to 5 ° in which the change from the immediately preceding traveling direction is determined to be substantially straight. Is set by extending the fixed period T to a double interval (2T), and if the fixed period T is within a range of 10 to 20 ° determined to be a gentle curve, the fixed period T is halved. The interval is shortened to (T / 2).

  For this reason, when it is determined that the traveling direction is a substantially straight line, the position data including the error obtained by the GPS receiver 24 is made as straight as possible by increasing the setting interval of the check position. The movement distance can be calculated more accurately, and when it is determined that the traveling direction is gently bent, the check distance setting interval can be shortened to calculate the movement distance on the curve more accurately. .

  Further, the geomagnetism data acquired by the geomagnetic sensor unit 25 every predetermined time (for example, 1 second) is the geomagnetism data measured every predetermined time (for example, 0.2 seconds) shorter than the predetermined time. Since it is acquired as a value averaged over a predetermined period (for example, 2 seconds) longer than the time, noise due to the influence of arm swing or the like can be effectively removed. Therefore, it can be determined more accurately whether the runner has passed the corner based on the geomagnetic amount data acquired by the geomagnetic sensor unit 25.

  In the embodiment, the positioning accuracy of the positioning data obtained from the GPS receiving unit 24 is determined based on the value of PDOP obtained by indexing the geometrical arrangement of the satellites. In addition, if radio waves from reflected GPS satellites are mixed, the value of the PDOP may be erroneously determined. Therefore, an accuracy determination index including other data parameters such as the traveling speed, the number of satellites, and the received signal level is determined. May be.

  In the embodiment, the accuracy of the values of the three-axis local magnetic quantity data obtained from the geomagnetic sensor unit 25 is determined according to the fluctuation caused by the disturbance of the local magnetic quantity data, and the weight value is set. The configuration was determined. Specifically, if the fluctuation of the detected value of the geomagnetic amount data is about ± 10 [μT], the accuracy is judged to be good, and the weighting value is set to “5”, and if it is ± 100 [μT] or more, the accuracy is deteriorated. Determination was made and the weighting value was set to “1”.

  On the other hand, as described below, the accuracy of the geomagnetic amount data obtained from the geomagnetic sensor unit 25 is determined by combining other sensor information, for example, positioning data obtained from the GPS receiving unit 24, and The weighting value may be determined.

  For example, the direction (angle) and magnitude data of the geomagnetic vector are stored in advance as a table for each latitude / longitude of the necessary area. Then, the direction (angle) and magnitude of the vector of the geomagnetism data obtained from the geomagnetic sensor unit 25 are read from the table corresponding to the latitude and longitude of the positioning data obtained from the GPS receiving unit 24. Compare the direction and magnitude of the geomagnetic vector. If the magnitude of the compared geomagnetic vector is a deviation of ± 20 [μT] or less and the direction (angle) is a deviation of ± 10 ° or less, it is determined that the accuracy is good and the weighting value is determined. Is “5”, and the magnitude of the compared geomagnetic vector is a deviation of ± 300 [μT] or more, it is determined that the accuracy is deteriorated, and the weighting value is determined as “1”.

  In the above-described embodiment, the electronic device control is performed inside the wristwatch-type electronic device 10 for all processing by the running state detection function including the movement distance measurement processing and the bending determination processing described with reference to FIGS. The program is executed according to the program 22a.

  On the other hand, each function (22a) and database (22b) is provided in a server device on the network, and a user operation signal from the key input unit 11 of the wristwatch type electronic device 10 or positioning data acquired by the GPS receiving unit 24 is provided. By transmitting the three-axis local magnetic quantity data acquired by the geomagnetic sensor unit 25 and each sensor signal acquired by the motion sensor unit 26 from the input / output interface 28 to the server device, the processing of the server device is performed. The wristwatch type electronic device 10 may receive and display highly accurate data such as the current position and the total movement distance analyzed by the execution.

  Each processing method and database by the wristwatch-type electronic device 10 described in each of the above embodiments, that is, a running state detection process shown in the flowchart of FIG. 8, a check flag setting process shown in the flowchart of FIG. 9, and a flowchart of FIG. Each of the databases including the movement distance measurement process associated with the traveling state detection process, the bending determination process associated with the traveling state detection process illustrated in the flowcharts of FIGS. 11 to 15, and the map data (course information) 22b As programs that can be executed by a computer, an external recording medium (memory card (ROM card, RAM card, etc.), magnetic disk (floppy disk, hard disk, etc.), optical disk (CD-ROM, DVD, etc.), semiconductor memory, etc. Store and distribute in (not shown) Can. Then, the computer of the portable electronic device provided with the GPS receiving unit 24, the geomagnetic sensor unit 25, and the motion sensor unit 26 reads the program recorded in the external recording medium into the storage device 22, and operates according to the read program. Is controlled, the high-accuracy traveling state detection function described in the embodiment can be realized, and the same processing can be executed by the method described above.

  Further, program data for realizing each of the above methods can be transmitted on the network N in the form of a program code, and the program data is transmitted to the GPS receiving unit 24, the geomagnetic sensor unit 25, and the motion sensor unit 26. The above-described high-accuracy traveling state detection function can also be realized by importing into a computer of a portable electronic device equipped with the above.

  Note that the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention at the stage of implementation. Further, each of the embodiments includes inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some constituent elements are deleted from all the constituent elements shown in each embodiment or some constituent elements are combined in different forms, the problems described in the column of the problem to be solved by the invention If the effects described in the column “Effects of the Invention” can be obtained, a configuration in which these constituent requirements are deleted or combined can be extracted as an invention.

  Hereinafter, the invention described in the scope of claims of the present application will be appended.

[1]
A GPS receiver for detecting the current position;
A geomagnetic sensor for detecting geomagnetism;
Data acquisition means for periodically acquiring current position data detected by the GPS receiver and geomagnetic data detected by the geomagnetic sensor;
Accuracy determination means for determining the accuracy of the current position data acquired by the data acquisition means and the accuracy of the geomagnetic data;
GPS bending determination means for determining passage of a corner based on a change in position data detected by the GPS receiving unit;
A geomagnetic bend determining means for determining the passage of a bend based on a change in geomagnetic data detected by the geomagnetic sensor;
The time at which the GPS bend determination means determines the passage of the turn based on the accuracy determined by the accuracy determination means when the GPS bend determination means and the geomagnetic bend determination means determine the passage of the bend. And passing time calculating means for calculating the passing time of the turn according to the weighting ratio, weighting the time when the turn of the turn is determined by the geomagnetic bending determination means,
A running state detecting device comprising:

[2]
Course setting means for setting a course including a plurality of corners in which distances from the start are associated in advance,
When moving the course set by the course setting means, total movement distance calculation means for calculating the total movement distance from the start,
The movement distance from the start calculated by the total movement distance calculation means is the time when the GPS curve determination means determines the passage of a turn, or the time when the geomagnetic curve determination means determines the passage of a turn, Or total travel distance correction means for correcting the distance on the course set by the course setting means in association with the turn angle for each turn time calculated by the passage time calculation means;
The travel state detection device according to [1], comprising:

[3]
Check position storage means for storing the current position data acquired by the data acquisition means as a check position when the GPS curve determination means and the geomagnetic curve determination means do not determine the passage of a turn for a certain period;
A moving distance calculating means for calculating a moving distance during traveling based on the current position data detected by the GPS receiver and the check position stored in the check position storage means;
A bending situation determination means for judging a situation of a bending in a traveling direction based on current position data periodically detected by the GPS receiver and previous position data;
A fixed period changing means for changing a time interval of the fixed period according to the bending situation in the traveling direction determined by the bending condition determining means;
The travel state detection device according to [1] or [2], characterized in that

[4]
The fixed period changing means extends and changes the time interval of the fixed period when the bending condition in the traveling direction determined by the bending condition determining means is equal to or less than a first angle range, A time interval of the predetermined period is shortened and changed when the angle is within a second angle range larger than the angle range;
The travel state detecting device according to [3], wherein

[5]
An averaged data acquisition means for acquiring geomagnetic data detected by the geomagnetic sensor as data averaged over a predetermined period;
The data acquisition means periodically acquires current position data detected by the GPS receiver and geomagnetic data acquired as data averaged over a predetermined period by the averaged data acquisition means.
The traveling state detection device according to any one of [1] to [4], wherein:

[6]
A program for controlling a computer of an electronic device having a GPS receiver for detecting a current position and a geomagnetic sensor for detecting geomagnetism,
The computer,
Data acquisition means for periodically acquiring current position data detected by the GPS receiver and geomagnetic data detected by the geomagnetic sensor;
Accuracy determination means for determining the accuracy of the current position data acquired by the data acquisition means and the accuracy of the geomagnetic data;
GPS bending determination means for determining passage of a corner based on a change in position data detected by the GPS receiving unit;
A geomagnetic bend determining means for determining the passage of a bend based on a change in geomagnetic data detected by the geomagnetic sensor;
The time at which the GPS bend determination means determines the passage of the turn based on the accuracy determined by the accuracy determination means when the GPS bend determination means and the geomagnetic bend determination means determine the passage of the bend. And passing time calculating means for calculating the passing time of the turn according to the weighting ratio, by weighting the time when the turn of the turn is determined by the geomagnetic bending determination means,
A computer-readable program that allows it to function as a computer.

DESCRIPTION OF SYMBOLS 10 ... Watch-type electronic device 11 ... Key input part 12 ... Display part 13 ... Wristband 21 ... CPU (control part)
22 ... Storage device 22a ... Electronic device control program 22b ... Map data (course information)
23 ... RAM
23a ... Display data memory 23b ... Current position memory 23c ... Final check flag position memory 23d ... Total travel distance memory 23e ... GPS reference direction memory 23f ... GPS current direction memory 23g ... Geomagnetic reference value (3-axis) memory 23h ... Geomagnetic current value (3-axis) memory 23i ... step count memory 23j ... step length memory 23p ... GPS accuracy weighting memory 23q ... geomagnetic accuracy weighting memory 24 ... GPS receiving unit 25 ... geomagnetic sensor unit 26 ... motion sensor unit (acceleration sensor / gyro sensor)
27 ... Analysis data storage unit 28

Claims (7)

A GPS receiver for detecting the current position;
A geomagnetic sensor for detecting geomagnetism;
Data acquisition means for periodically acquiring current position data detected by the GPS receiver and geomagnetic data detected by the geomagnetic sensor;
Accuracy determination means for determining the accuracy of the current position data acquired by the data acquisition means and the accuracy of the geomagnetic data;
GPS bending determination means for determining passage of a corner based on a change in position data detected by the GPS receiving unit;
A geomagnetic bend determining means for determining the passage of a bend based on a change in geomagnetic data detected by the geomagnetic sensor;
When the passage of the corner by the GPS bend determining means and said geomagnetism bend determining means determines, prior Symbol pass corner is determined by the time passage of the corner is determined to the GPS bend determining means the geomagnetism bend determining means A passing time calculation means that uses a time close to the time at which the passage of the turn is determined by the higher accuracy data determined by the accuracy determination means as the passage time of the turn When,
A running state detecting device comprising: Course setting means for setting a course including a plurality of corners in which distances from the start are associated in advance,
When moving the course set by the course setting means, total movement distance calculation means for calculating the total movement distance from the start,
The movement distance from the start calculated by the total movement distance calculation means is the time when the GPS curve determination means determines the passage of a turn, or the time when the geomagnetic curve determination means determines the passage of a turn, Or total travel distance correction means for correcting the distance on the course set by the course setting means in association with the turn angle for each turn time calculated by the passage time calculation means;
The travel state detection device according to claim 1, comprising: Check position storage means for storing the current position data acquired by the data acquisition means as a check position when the GPS curve determination means and the geomagnetic curve determination means do not determine the passage of a turn for a certain period;
A moving distance calculating means for calculating a moving distance during traveling based on the current position data detected by the GPS receiver and the check position stored in the check position storage means;
A bending situation determination means for judging a situation of a bending in a traveling direction based on current position data periodically detected by the GPS receiver and previous position data;
A fixed period changing means for changing a time interval of the fixed period according to the bending situation in the traveling direction determined by the bending condition determining means;
The travel state detection device according to claim 1 or 2, further comprising: The fixed period changing means extends and changes the time interval of the fixed period when the bending condition in the traveling direction determined by the bending condition determining means is equal to or less than a first angle range, A time interval of the predetermined period is shortened and changed when the angle is within a second angle range larger than the angle range;
The traveling state detection device according to claim 3. An averaged data acquisition means for acquiring geomagnetic data detected by the geomagnetic sensor as data averaged over a predetermined period;
The data acquisition means periodically acquires current position data detected by the GPS receiver and geomagnetic data acquired as data averaged over a predetermined period by the averaged data acquisition means.
The traveling state detection device according to any one of claims 1 to 4, wherein the traveling state detection device according to any one of claims 1 to 4 is provided. A program for controlling a computer of an electronic device having a GPS receiver for detecting a current position and a geomagnetic sensor for detecting geomagnetism,
The computer,
Data acquisition means for periodically acquiring current position data detected by the GPS receiver and geomagnetic data detected by the geomagnetic sensor;
Accuracy determination means for determining the accuracy of the current position data acquired by the data acquisition means and the accuracy of the geomagnetic data;
GPS bending determination means for determining passage of a corner based on a change in position data detected by the GPS receiving unit;
A geomagnetic bend determining means for determining the passage of a bend based on a change in geomagnetic data detected by the geomagnetic sensor;
When the passage of the corner by the GPS bend determining means and said geomagnetism bend determining means determines, prior Symbol pass corner is determined by the time passage of the corner is determined to the GPS bend determining means the geomagnetism bend determining means A passing time calculation means that uses a time close to the time at which the passage of the turn is determined by the higher accuracy data determined by the accuracy determination means as the passage time of the turn ,
A computer-readable program that allows it to function as a computer. A method of obtaining a turn time of a turn of an electronic device having a GPS receiver that detects a current position and a geomagnetic sensor that detects geomagnetism,
A data acquisition step of periodically acquiring current position data detected by the GPS receiver and geomagnetic data detected by the geomagnetic sensor;
An accuracy determination step for determining the accuracy of the current position data acquired by the data acquisition step and the accuracy of the geomagnetic data;
A GPS bend determination step for determining the passage of a turn based on a change in position data detected by the GPS receiver; and
A geomagnetic bending determination step for determining the passage of a corner based on a change in geomagnetic data detected by the geomagnetic sensor;
When it is determined that the corner has passed through the GPS bend determination step and the geomagnetic bend determination step, the time at which the GPS bend determination step is determined to pass the bend and the passage of the bend is determined in the geomagnetic bend determination step. And a passing time calculating step in which a time close to the time at which the passing of the turning angle is determined by the higher accuracy data determined in the accuracy determining step is set as the passing time of the turning angle. ,
A method for obtaining a corner transit time having