JPH10260055A - Device for detecting traveling speed and direction of pedestrian - Google Patents

Abstract

PROBLEM TO BE SOLVED: To precisely detect a traveling speed or the like of a pedestrian with no use of a GSP receiver. SOLUTION: With the use of a three-axial acceleration sensor 16 and a three-axial rate sensor 18, a gravitationally accelerating direction signal (g) is obtained from outputs Gx0, Gy0, Gz0 from the acceleration sensor 16, and then, using this signal (g) as an initial value, a gravitationally accelerating direction tracing means 22 calculates a correction value for a present posture from three-axial rate signals Rx, Ry, Rz. The acceleration outputs Gx0, Gy0, Gz0 are corrected by this correction value so as to obtain acceleration outputs Gx, Gy, Gz corresponding to vertical motion with respect the ground surface. A walking period detecting means 30 multiplies the period of the vertical motion by a clock period so as to obtain a walking period (the period by which the pedestrian advance one step). A travel speed calculating means 32 multiplies thus obtained walking period by a foot step so as to detect a traveling speed with no use of a GPS receiver.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pedestrian traveling speed / direction detecting device suitable for application to, for example, a walking route guidance device that can be carried by a pedestrian.

[0002]

2. Description of the Related Art As a technique related to a moving speed / direction detecting device for a pedestrian, for example, an automobile navigation system can be cited. In this system, GPS
The position of the own vehicle is obtained by the satellite navigation according to the present invention, and the position, the traveling direction, and the like of the own vehicle are displayed on a map on a display.

[0003] In a car navigation system, even if a radio wave from a GPS satellite cannot be received, the vehicle can be controlled by so-called inertial navigation by using a distance sensor and a rate sensor together. It is also known to be able to detect the position.

On the other hand, as a navigation system that can be carried by a pedestrian, for example, there is a technique disclosed in Japanese Patent Application Laid-Open No. Hei 8-202982. In this technique, a GPS receiver is used as a means for detecting a current position of a pedestrian, and a gyro or a geomagnetic sensor is used as means for detecting a walking direction.

[0005]

However, when considering the use of the above-mentioned conventional car navigation system as a pedestrian traveling speed / direction detecting device, when walking in a building street or building, However, it is impossible to detect the position of pedestrians, even if the navigation system with inertial navigation, when walking in a building or building, how to detect the moving distance or speed There is an issue of whether it is good.

On the other hand, when considering the use of the above-described pedestrian portable navigation system as a pedestrian traveling speed / direction detecting device, the pedestrian always holds the portable navigation system in a fixed direction. There is no guarantee that the output is upside down, and the output may be upside down, left and right inverted. Further, in the navigation system that can be carried by a pedestrian, there is a problem that it is difficult to detect the pedestrian position with sufficient accuracy because a GPS receiver, a geomagnetic sensor, and the like are used.

[0007] The present invention has been made in view of such a problem, and a pedestrian movement capable of detecting the moving speed and direction regardless of the state of the pedestrian carrying the portable device. It is an object to provide a speed / direction detection device.

It is another object of the present invention to provide a pedestrian moving speed / direction detecting device capable of accurately detecting the moving speed / direction.

[0009]

The present invention provides a three-axis acceleration detecting means, a three-axis rate detecting means, and a gravitational acceleration direction detecting means for detecting a gravitational acceleration direction from an output of the three-axis acceleration detecting means. A gravitational direction tracking unit that calculates a correction value from an output of the three-axis rate detection unit, using a gravitational acceleration direction obtained by the gravitational acceleration direction detection unit as an initial gravitational acceleration direction; 3
Acceleration signal correction means for correcting the output of the three-axis acceleration detection means, rate signal correction means for correcting the signals of the three-axis rate detection means based on the correction value, and a ground surface based on the output of the acceleration signal correction means. A stride cycle detecting means for detecting a vertical vibration component with respect to the pedestrian and detecting a walking cycle of the pedestrian as a step cycle; a moving speed calculating means for calculating a moving speed by multiplying the detected step cycle by a stride; Moving direction detecting means for detecting the traveling direction on the ground surface based on the output of the signal correcting means.

According to the present invention, the direction of the ground surface (the direction of gravitational acceleration) is detected by the triaxial acceleration detecting means, and the attitude of the pedestrian moving speed / direction detecting device itself is detected. The three-axis acceleration detecting means detects vertical vibration caused by the pedestrian's walking, and analyzes the vibration component to determine a walking cycle (time required to take one step), which is a pedestrian's walking cycle. To detect. The moving speed is calculated by multiplying the step cycle by the step length.

By using the direction of the ground surface detected by the three-axis acceleration detecting means as an initial value of the three-axis rate sensor, it is possible to use a case where a pedestrian is performing a sudden movement or a vehicle. Even if there is an error in the output of the three-axis rate detection means,
The direction of movement on the ground surface can be detected.

[0012]

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

FIG. 1 is a block diagram showing a configuration of a pedestrian moving distance / direction detecting means 10 as an example for detecting a moving distance and a moving direction (moving direction) of a pedestrian. The pedestrian route guidance device can be configured by using the pedestrian movement distance / direction detection means 10 of the example in FIG.

FIG. 2 is a block diagram showing the configuration of the step setting means 12 as an example for setting the step of a pedestrian.

FIG. 3 is a block diagram showing the configuration of the inertial speed detecting means 14 as an example for detecting the pedestrian's inertial moving speed.

FIG. 4 shows a pedestrian moving distance / direction detecting means 10 of FIG. 1 combined with a step setting means 12 of FIG. 2 and an inertial speed detecting means 14 of FIG. The configuration of the pedestrian movement distance / direction detection means 17 including speed detection is shown.

The pedestrian movement distance / direction detecting means 10 shown in FIG. 1 is a means for detecting acceleration in three orthogonal axes.
An axis acceleration sensor 16 and a three-axis rate sensor 18 as means for detecting orthogonal three-axis rates are provided.

Further, a pedestrian moving distance / direction detecting means 1
0 is an input connected to the output side of the gravitational acceleration direction detecting means (gravity direction detecting means) 20 connected to the output side of the three-axis acceleration sensor 16, and the output side of each of the three-axis rate sensor 18 and the gravitational acceleration direction detecting means 20. Gravitational acceleration direction tracking means 2
Two.

Further, the pedestrian movement distance / direction detecting means 10 includes an acceleration signal correcting means 24 having an input connected to the output side of the three-axis acceleration sensor 16 and the gravitational acceleration direction tracking means 22, and a three-axis rate sensor 18. And a rate signal correcting means 26 having an input connected to the output side of the gravity acceleration direction tracking means 22.

Further, the pedestrian movement distance / direction detecting means 10 has an input connected to the output side of the acceleration signal correcting means 24, and a step period detecting means 30 to which a clock is supplied from a clock generating means 28. The moving speed calculating means 32 connected to the output side of the step cycle detecting means 30 and supplied with a stride (also referred to as a stride signal or stride data), and the movement connected to the output side of the rate signal correcting means 26. It has a direction detecting means 34.

The pedestrian moving distance / direction detecting means 10 shown in FIG. 1 is basically configured as described above. Next, the operation will be described. A microcomputer is mounted on each component constituting the pedestrian moving distance / direction detecting means 10 as necessary, and the following operation is performed by processing by the computer.

The three-axis acceleration sensor 16 detects accelerations in the x, y, and z directions according to the movement of the pedestrian, and acceleration signals Gx0, Gy for the respective axes.
0, Gz0 (m / s ² ) is output. The three-axis rate sensor 18 detects a rate in each axis direction according to the movement of the pedestrian, and a rate signal (also simply referred to as a rate) Rx for each axis.
0, Ry0, Rz0 (rad / s) are output.

The gravitational acceleration direction detecting means 20 extracts the acceleration component due to gravity from the three-axis acceleration signals Gx0, Gy0, Gz0, and determines the direction of the gravitational acceleration direction signal g (m / m / m).
s ² ). In this case, the gravitational acceleration direction is detected when it is determined that the amplitude of at least one of the three-axis acceleration signals Gx0, Gy0, and Gz0 is periodically changing. If it is determined that the DC component has been removed, the remaining DC component from which a relatively high frequency vibration component has been removed can be separated as a gravitational acceleration component by low-pass filter processing or the like. In addition, for example, when the pedestrian stops, the acceleration signal Gx
When no vibration component is included in 0, Gy0, and Gz0, the obtained acceleration signal may be identified as the gravitational acceleration component.

The gravitational acceleration direction tracking means 22 sets the three-axis rate signals Rx0, Ry0, Rz0 as initial values when the gravitational acceleration direction detection means 20 succeeds in detecting the gravitational acceleration direction signal g, and is obtained thereafter. By processing the rate signals Rx0, Ry0, Rz0 of each axis as the inclination of the pedestrian movement distance / direction detection means 10 (inclination with respect to the ground surface), the pedestrian movement distance / direction detection means 10
Is calculated with respect to the ground surface, and the calculation result is output as a correction amount (correction value).

The acceleration signal correcting means 24 converts the acceleration signals Gx0, Gy0, Gz0 of each axis to the ground surface using the correction value output from the gravitational acceleration direction tracking means 22.
The acceleration signals Gx, Gy, and Gz of the axis are converted and output.

Similarly, the rate signal correction means 26 converts the rate signals Rx0, Ry0, Rz0 of each axis into three-axis rate signals Rx, Ry for the ground surface using the correction values output from the gravity acceleration direction tracking means 22. , Rz and output.

The clock generating means 28 generates a clock having a constant period (for example, 0.2 ms) for detecting a walking period of a pedestrian. The step cycle detecting means 30 is a three-axis acceleration signal Gx, Gy, Gz converted into an acceleration motion with respect to the ground surface output from the acceleration signal correcting means 24.
For example, the vibration components (upper and lower components) are separated by, for example, high-pass filtering, and the time required for a pedestrian to take one step at a time is counted from the period of the separated vibration components by counting the number of clocks of the fixed period. Then, the time is converted into a time and detected as a step cycle (step cycle signal).

The moving speed calculating means 32 multiplies the step period detected by the step period detecting means 30 by the set step length of the user (pedestrian) or the default step length to obtain the moving speed (moving speed). Signal).

The moving direction detecting means 34 calculates the rotation angle about the vertical axis in the direction of gravitational acceleration from the three-axis rate signals Rx, Ry, Rz converted into the rate motion with respect to the ground surface output from the rate signal correcting means 26. And outputs it as the moving direction.

In this case, according to the pedestrian moving distance / direction detecting means 10 of FIG. 1, the moving distance / direction with respect to the ground surface can be accurately detected regardless of the state in which the pedestrian is carrying the portable device. Becomes In other words, it is possible to detect the posture of the pedestrian movement distance / direction detection means 10 itself. Further, according to the pedestrian movement distance / direction detection means 10 of FIG. 1, the movement speed can be obtained by multiplying the step cycle detected based on the output of the three-axis acceleration sensor 16 by the set step length. And, for example, GPS
The effect that it is possible to detect the moving speed of the pedestrian even in a situation where the radio wave from the satellite cannot be received is achieved.

The step setting means 12 in the example of FIG. 2 is connected to the GPS receiver 42, the measurement position storage means 44 connected to the output side of the GPS receiver 42, and connected to the output side of the GPS receiver 42. The step count storage means 46 to which the step cycle is supplied from the step cycle detection means 30, the step count calculation means 48 connected to the output side of the step count storage means 46 and the output side of the measurement position storage means 44, and the output of the step length calculation means 48. A step length storage means 50 is connected and supplied with a step cycle from the step cycle detection means 30, and a measurement timing instructing means 52 connected to the input side of the measurement position storage means 44 and the number of steps storage means 46.

The stride setting means 12 shown in FIG. 2 is basically configured as described above. Next, the operation will be described. In addition, similarly to the constituent elements of the pedestrian movement distance / direction detecting means 10, the constituent elements of the stride setting means 12 are equipped with a microcomputer as necessary. Is performed.

The GPS receiver 42 receives a radio wave from a GPS satellite through the receiving antenna 43 and detects a measurement position (latitude, longitude, altitude). Measurement position storage means 44
Stores the measurement position when the GPS receiver 42 can receive radio waves, calculates the distance between the measurement positions (between two points), and outputs the calculated distance.

The number-of-steps storage means 46 stores the number of steps required for movement between any two points (measurement positions) when the GPS receiver 42 can receive radio waves. The number of steps can be calculated by counting step period signals between measurement positions.

The step length calculating means 48 is used for storing the measured position storing means 4
The step length can be calculated by dividing the distance between any two points (measurement positions) stored in step 4 by the corresponding number of steps between any two points stored in the number-of-steps storage means 46. .

The stride storage means 50 is a table (look-up table) that associates the calculated stride with the step cycle at that time.
To be stored. For example, when the walking cycle is 0.5 seconds, 1
A stride such as m is stored in association with a stride such as 50 cm when the stride cycle is 1 second. Then, the correspondence table is updated as necessary, and the stride corresponding to the stride cycle is output as the registered stride.

The measurement timing instructing means 52 instructs measurement start timing and measurement end timing of arbitrary two points (measurement positions) used in the measurement position storage means 44 and the number of steps storage means 46.

According to the stride setting means 12 in the example of FIG. 2, the individual difference of the pedestrian as a user or the difference in the stride caused by the physical condition of the pedestrian is automatically set and updated as the registered stride. The effect that it becomes possible is achieved.

In this case, the stride is stored in accordance with the step cycle, in other words, the pace of walking of the pedestrian (normal walking, fast walking, slow walking, running, etc.). Can be output in accordance with the tempo (how to walk).

The moving speed calculating means 32 (see FIG. 1)
The stride set in is not limited to the registered stride according to the example in FIG.
It can also be set arbitrarily by input setting means (not shown).

The step length is set by performing a so-called map matching (position prediction method) using the pedestrian's movement route and a road map (electronic road shape information), and dividing the movement distance on the map by the number of steps. Can also be obtained.

The inertial velocity detecting means 14 of FIG. 3 includes three-axis acceleration signals Gx, Gy, Gz for the ground surface output from the acceleration signal correcting means 24 and the gravitational acceleration direction output from the gravitational acceleration direction detecting means 20. A gravitational acceleration removing means 60 for receiving the signal g, a speed change calculating means 62 connected to the output side of the gravitational acceleration removing means 60 and supplied with a clock from the clock generating means 28, and an output of the speed change calculating means 62 Speed change integrating means 64 connected to the side.

Next, the operation of the inertial speed detecting means 14 will be described. A microcomputer is also mounted on each component constituting the inertial velocity detecting means 14 as necessary, and the following operation is performed by computer processing.

The gravitational acceleration elimination means 60 includes the corrected acceleration signals Gx and G obtained from the acceleration signal correction means 24.
From y and Gz, acceleration signals Gx ', Gy' and Gz 'are obtained by removing the gravitational acceleration component using the gravitational acceleration direction signal g obtained by the gravitational acceleration direction detection means 20 and output. The speed change calculating means 62 detects a speed change by multiplying by a predetermined clock cycle (time) provided by the clock generating means 28. The speed change integrating means 64 continuously integrates and averages the detected speed change values, and outputs a so-called moving average value as the inertial moving speed.

FIG. 4 shows a combination of the pedestrian movement distance / direction detecting means 10 of FIG. 1 with the step setting means 12 of FIG. 2 and the inertial speed detecting means 14 of FIG. 3, as described above.
The configuration of a pedestrian movement distance / direction detection unit 17 including detection of an inertial speed as an example is shown.

In the example of FIG. 4, the step-converted moving speed obtained by the moving speed calculating means 32 from the step cycle and the registered step length, and the instantaneous changing speed or inertial moving speed obtained by the inertial speed detecting means 14 are used as the moving speed selecting means. 70 so as to be able to select and output.

The moving speed selecting means 70 selects a step-converted moving speed as a moving speed in a moving condition at a relatively low speed where it is difficult to detect the moving speed with high accuracy, so that a sufficiently large acceleration can be obtained. In a moving state at a high speed, by selecting the inertial moving speed or the changing speed, it is possible to detect the moving speed with high accuracy in any state.
When the inertial moving speed or the changing speed is selected, the moving speed selecting means selects the inertial moving speed when the signal level of the inertial moving speed is sufficiently higher than the changing speed.

More specifically, the speed at which a person as a pedestrian walks using his feet is usually about 4 to 8 km / h, and even in the case of running, it is about 20 + α km / h. It is difficult to detect the acceleration signal. Further, in the case of movement by a foot, an error increases when the inertial movement speed is selected because vibration noise is present.

Therefore, when the moving speed is higher than a certain level, there is a high possibility that the pedestrian is moving on the vehicle. In the case of movement by a vehicle, a sufficient acceleration signal is often obtained, so the inertial movement speed is selected.
The difference between the movement by walking and the movement by the vehicle can be determined as the movement by walking if the vibration component is detected when the inertial movement speed is detected.

It should be noted that the present invention is not limited to the above-described embodiment, but can adopt various configurations without departing from the gist of the present invention.

[0051]

As described above, according to the present invention, since the posture of the pedestrian moving speed / direction detecting device can be detected, the pedestrian can carry the portable device in any state. The effect that the moving speed / direction can be detected is achieved.

According to the present invention, the vertical movement of the pedestrian is detected by using the three-axis acceleration detecting means and the rate detecting means, and the moving direction is detected. Therefore, the effect that the moving speed can be obtained from the period of the vertical movement is achieved.

When a GPS receiver is used, the stride can be calibrated, and the effect that the moving speed can be calculated more accurately is achieved.

When the stride length can be calibrated, the stride length can be set according to the individual difference of the user.

[Brief description of the drawings]

FIG. 1 shows the moving distance and moving direction (moving direction) of a pedestrian.
FIG. 2 is a block diagram showing a configuration example of a pedestrian movement distance / direction detection unit for detecting a pedestrian;

FIG. 2 is a block diagram illustrating a configuration example of a stride setting unit that sets a stride of a pedestrian;

FIG. 3 is a block diagram illustrating a configuration example of an inertial speed detecting unit for detecting an inertial moving speed of a pedestrian;

FIG. 4 is a pedestrian movement distance / direction including detection of inertial speed obtained by combining the pedestrian movement distance / direction detection means of FIG. 1 with the step setting means of FIG. 2 and the inertial speed detection means of FIG. 3; FIG. 3 is a block diagram illustrating a configuration example of a detection unit.

[Explanation of symbols]

10, 17: Moving distance / direction detecting means for pedestrians 12: Step setting means 14: Inertial speed detecting means 16: 3-axis acceleration sensor 18: 3-axis rate sensor 20: Gravitational acceleration direction detecting means 22: Gravitational acceleration direction tracking means 24 ... Acceleration signal correction means 26 ... Rate signal correction means 30 ... Step cycle detection means 32 ... Moving speed calculation means 34 ... Movement direction detection means

Claims (4)

[Claims] 1. A three-axis acceleration detection means, a three-axis rate detection means, a gravitational acceleration direction detection means for detecting a gravitational acceleration direction from an output of the three-axis acceleration detection means, and a gravitational acceleration direction detection means Gravitational direction tracking means for calculating a correction value from the output of the three-axis rate detection means, using the gravitational acceleration direction obtained by the above as the initial gravitational acceleration direction; and an output of the three-axis acceleration detection means based on the correction value. Signal correcting means for correcting the signal of the three-axis rate detecting means based on the correction value, and detecting a vertical vibration component with respect to the ground surface from the output of the acceleration signal correcting means. A walking cycle detecting means for detecting a walking cycle of a pedestrian as a walking cycle; and a moving speed calculating means for calculating a moving speed by multiplying the detected walking cycle by a stride. A moving speed / direction detecting device for a pedestrian, comprising: a step; and a moving direction detecting means for detecting a traveling direction on the ground surface based on an output of the rate signal correcting means. 2. The apparatus according to claim 1, wherein the step used by said moving speed calculating means is obtained by dividing a moving distance obtained by using a GPS receiver by the number of steps required to walk said moving distance. A moving speed / direction detecting device for pedestrians. 3. The apparatus according to claim 1, wherein the stride used by the moving speed calculating means is a position using road shape information with respect to a moving distance and a moving direction obtained by using a GPS receiver. A moving speed / direction detecting device for a pedestrian, wherein a moving distance obtained by performing a prediction method is obtained by dividing the moving distance by the number of steps required to walk the moving distance. 4. The apparatus according to claim 1, wherein the three-axis acceleration signal corrected by the acceleration signal correction means has a relatively large level. Moving speed calculated by multiplying the acceleration signal of the target level by the time to calculate the moving speed, is used in place of the moving speed obtained by multiplying the stride by the step cycle. Direction detection device.