JP2022006248A - Distance measuring device and distance measuring method using the same - Google Patents

Abstract

To provide a distance measuring device and a method that can easily measure a distance between a measuring instrument and a measurement target at low cost without having to adjust the beam to the measurement target at the time of measurement, even when the measurement target is in close proximity to another object, or when a light or radio wave from the measuring instrument is weak.SOLUTION: A measuring instrument 200 transmits an output signal to a measurement target based on a measurement start signal of a control device, and also receives a response signal from the measurement target, the measurement target 300 transmits the response signal to a measuring device in response to the output signal from the measuring instrument, and the control device 100 is wirelessly connected to the measuring instrument and the measurement target. A distance between the measuring instrument and the measurement target is measured when the measurement start signal is transmitted and when the response signal from the measurement target is received, according to a circuit delay time in the measuring instrument until the measuring device transmits an output signal in response to the measurement start signal from the control device and a circuit delay time in the measurement target until the measured object transmits a response signal in response to the output signal from the measuring instrument.SELECTED DRAWING: Figure 6

Description

The present invention relates to a distance measuring device for measuring a distance between a measuring instrument and a measuring object, and a distance measuring method using the distance measuring device.

As a method for measuring the distance from the measuring instrument to the object to be measured, the optical type and the radio wave type have been widely known. Then, for example, in the case of the optical type, it is described in JP-A No. 11-142519 (Patent Document 1), and in the case of the radio wave type, it is described in JP-A-5-323201 (Patent Document 2). The radio wave type distance measuring device and the like are disclosed.

Of these, in the optical type, as shown in FIG. 1, in general, as shown in FIG. 1, the measuring instrument irradiates the object to be measured by light emission using a light source such as a laser or an LED, and the reflected light from the object to be measured is emitted. It is a method of receiving light and calculating the distance.

Then, as the calculation method, the TOF (Time of Flight) method, which calculates the distance from the round-trip time from the light emission to the return of the reflected light, and the distance is calculated from the phase difference between the light emission and the reflected light. There is a phase difference detection method.

Further, the radio wave type is generally a method of transmitting a radio wave from a measuring instrument toward a measuring object, receiving a radio wave reflected from the measuring object, and calculating a distance, as shown in FIG. ..

As the calculation method, there are the TOF method that calculates the distance from the round-trip time of the radio wave like the laser method, and the FMCW (Frequency Modulated Continuous Wave) method that calculates the distance from the change in frequency, and the ultrasonic wave is used instead of the radio wave. May be used.

Japanese Unexamined Patent Publication No. 11-142519 Japanese Unexamined Patent Publication No. 5-323201

However, the conventional optical distance measuring device basically has the following problems.

That is, although a laser is widely used as a light source, a fixed laser is inexpensive, but on the other hand, the irradiation angle is narrow due to the small diffusion from the light source, and it is not possible to automatically measure a measured object having an indefinite position. Therefore, it is extremely difficult to adjust the laser when the operator needs to irradiate the measurement object with the laser and the measurement object is far away.

On the other hand, a scanning laser can automatically detect and measure a target, but it is very expensive. Also, if the laser is replaced with a highly diffusive LED, it is not necessary to align the beam with the object to be measured, but if there is another object around the object to be measured, it is possible to determine whether the reflected light is the object to be measured or the object around it. It is not possible.

Further, the measurement distance and the measurement accuracy greatly depend on the reflectance of the measured object. Therefore, in the case of a measured object having a low reflectance, the measurement distance becomes short and the measurement accuracy decreases. Further, in an object having a strong gloss, there is no guarantee that the reflected light will be incident on the light receiving portion of the measuring instrument, so that there is a problem that the surface of the object to be measured must be diffuse reflection.

Similarly, the conventional radio wave type distance measuring device basically has the following problems.

That is, the radio wave has a wide field of view (irradiation angle) and it is not necessary to align the beam with the object to be measured, but the distance resolution, that is, the ability to separate and detect a plurality of nearby objects is low. Therefore, even with the latest 79 GHz band millimeter wave, the distance resolution is only 37.5 mm, and high-precision measurement is impossible in an environment where there are other objects near the object to be measured.

Further, the measurement distance and the measurement accuracy largely depend on the RCS (Radar Cross-Section) of the measured object. RCS is the ability to reflect radio waves in the direction of the antenna when it receives radio waves from the radar, and varies depending on the size, shape, and material of the object to be measured. If the object to be measured is large, close to the shape of a triangular pyramid, and has high radio wave reflectance, the measurement distance will be long and the measurement accuracy will increase, but if this condition is not met, the distance and accuracy will decrease. rice field.

Therefore, an object of the present invention is to solve the above-mentioned problems, and it is not necessary to adjust the beam to the measured object at the time of measurement, although the cost is low, and the measured object is in close proximity to another object or the measured object. Even if there is another object on the angle line close to the azimuth angle of, or if the light (or radio wave) emitted from the measuring instrument that reaches the object is weak, it can be easily measured with the measuring instrument. An object of the present invention is to provide a distance measuring device and a distance measuring method capable of measuring a distance between an object and an object.

In order to solve the above problems, the present invention is a distance measuring device for measuring a distance between a measuring instrument and a measuring object, and the distance measuring device includes the measuring instrument, the measuring object, and a control device. The control device is wirelessly connected to the measuring instrument and the measuring object, and controls the measuring instrument and the measuring object, and the measuring instrument is based on the measurement start signal of the control device. , The output signal is transmitted to the measuring object and the response signal from the measuring object is received, and the measuring object transmits the response signal to the measuring device in response to the output signal from the measuring instrument. The control device is the time when the measurement start signal is output, the time when the response signal from the measurement object is received, and the time until the measurement device transmits the output signal according to the measurement start signal from the control device. The measuring instrument and the measuring object are based on the circuit delay time in the measuring instrument and the circuit delay time in the measuring object until the measuring object transmits a response signal in response to an output signal from the measuring instrument. Provided is a distance measuring device characterized by measuring a distance between them.

Further, the solution to the above problem is that the measuring instrument has a measuring instrument side communication circuit (MCI) with the control device, a measuring instrument side output circuit (MOC), and a first measuring instrument side input circuit (MIC1). It has a second measuring instrument side input circuit (MIC2) and a measuring instrument side time digital conversion circuit (MTDC), and the measuring object is a measuring object side communication circuit (OCI) with the control device and a measurement. It has an object side output circuit (OOC), a first measurement object side input circuit (OIC1), a second measurement object side input circuit (OIC2), and a measurement object side time digital conversion circuit (OTDC). The control device transmits a measurement start signal to the measuring instrument, and the measuring instrument bases the measurement start signal on the measuring instrument side output circuit (MOC) via the measuring instrument side communication circuit (MCI). ), The first start signal (ST1) is input to the time digital conversion circuit (MTDC) on the measuring instrument side, and the first start signal (ST1) is input to the output circuit (MOC) on the measuring instrument side. In response to the first activation signal (ST1), the output signal is transmitted to the second measurement object side input circuit (OIC2) of the measurement object, and a part of the output signal is the first. Is input to the measuring instrument side input circuit (MIC1), and the first measuring instrument side input circuit (MIC1) responds to the measuring instrument side delay signal (Measuring instrument side delay signal (MTDC) to the measuring instrument side time digital conversion circuit (MTDC). By inputting MDS1) and receiving the output signal from the measuring instrument, the second measuring object side input circuit (OIC2) of the measuring object is second to the measuring object side output circuit (OOC). The start signal (OST2) of the above is input, and the output circuit (OOC) on the measurement object side is input to the input circuit (MIC2) on the measurement instrument side of the second measuring instrument in response to the second start signal (OST2). While transmitting the response signal, a part of the response signal is input to the first measurement object side input circuit (OIC1), and accordingly, the first measurement object side input circuit (OIC1) receives the response signal. The measurement object side delay signal (ODS1) is input to the measurement object side time digital conversion circuit (OTDC), and the second measuring instrument side input circuit (MIC2) receives the response signal from the measurement object. Thereby, the stop signal (STS) is input to the measuring instrument side time digital conversion circuit (MTDC), and the control device is input to the measuring instrument side time digital conversion circuit (MTDC). The time of the signal (ST1), the delay signal (MDS1) on the measuring instrument side, the stop signal (STS), and the measurement. Between the measuring instrument and the measuring object based on the time of the second start signal (OST2) and the measuring object side delay signal (ODS1) input to the object side time digital conversion circuit (OTDC). It is achieved more effectively by measuring the distance.

Further, the solution to the above problem is that the distance measuring device includes the functions of the measuring instrument and the measured object, a distance measuring unit having a function changeover switch, and the control device, and the function changeover switch. By using at least one of the two distance measuring units as the measuring instrument and the other one as the measuring object, the distance between the distance measuring units can be measured, or the above. The distance measurement unit includes a communication circuit (CI) and an output circuit (OC) with the control device, a first input circuit (IC1), a second input circuit (IC2), and a time digital conversion circuit (TDC). And, by having the function changeover switch and switching the function between the measuring instrument and the measuring object by the operation by the function changeover switch by the control device, or by the control device, the measuring instrument and the said. The connection with the measuring object is more effectively achieved by a communication protocol based on the Bluetooth (registered trademark) communication standard, or by further providing a GPS receiving circuit between the measuring instrument and the measuring object. ..

Further, the solution to the above problem is a distance measurement method using the distance measuring device, in which the measuring instrument transmits the output signal to the measured object based on the measurement start signal from the control device. A step of recording the circuit delay time in the measuring instrument until the output signal is transmitted from the measuring instrument based on the measurement start signal from the control device, and the output signal from the measuring instrument. In the step of receiving and transmitting the response signal to the measuring instrument by the measuring object and in the measuring object from receiving the output signal from the measuring instrument to transmitting the response signal from the measuring object. The step of recording the circuit delay time, the time when the control device outputs the measurement start signal, the time when the response signal from the measurement object is received, the circuit delay time in the measuring instrument, and the measurement object. It is further effectively achieved by a distance measuring method comprising the step of measuring the distance between the measuring instrument and the measuring object based on the circuit delay time in.

In the present invention, when the measuring instrument and the measuring object are installed at each of the two points where the distance is to be measured and an output signal is transmitted from the measuring instrument to the measuring object by operation by the control device, the measuring object receives the output signal. It is configured to send a response signal to the measuring instrument.

Therefore, TOF (flight time measurement) is performed based on the response signal emitted by the measured object itself without using the reflection of the measured object. Therefore, according to the present invention, it is possible to perform measurement without being influenced by the reflectance, diffusivity, RCS, etc. of the measured object, unlike the conventional method using reflected light.

Further, when light is used, since the light can be directly used for the response from the measured object, the signal level is higher than that of the reflected light and it is resistant to noise. Thereby, according to the present invention, it is possible to obtain a highly accurate and stable measured value.

Further, when measuring a distance of a measurement object whose position is inaccurate, the conventional laser method requires an expensive mechanism for an operator to adjust the beam to the measurement object or scan the beam.

However, in the present invention, measurement is possible as long as the light (or radio wave) from the measuring instrument hits the object to be measured. Therefore, for example, as shown in FIG. 3, if a wide-diffusion LED or a radio wave is used, it is possible to measure a measured object at an arbitrary position with an inexpensive mechanism without an operator. And the measurement range can be expanded to 360 ° (omnidirectional).

In addition, even with the conventional methods other than the laser method, beam matching and beam scanning are not required if wide-diffusion LEDs and wide-angle antennas are used. However, that is the case when "there is no other object near the object to be measured". Therefore, if there is another object near the object to be measured, it cannot be distinguished from the object to be measured by the LED type, and even by the radio wave type, it cannot be distinguished unless the distance from the other object is several cm or more. The laser type is not affected by this, but has the above-mentioned problems.

However, according to the present invention, as shown in FIG. 4, even when there is another object near the object to be measured, the levels of response emission (response transmission) and reflected light (reflected wave) are considerable. Since there is a difference, it can be easily determined based on the difference.

Further, in the conventional method other than the laser method, if another object exists on the angle line close to the azimuth angle of the measured object, it cannot be distinguished from the measured object.

However, according to the present invention, as shown in FIG. 5, complete discrimination is possible by changing the wavelengths (frequency) of light emission (transmission) and response light emission (response transmission).

Therefore, according to the present invention, it is not necessary to align the beam with the measured object at the time of measurement, although the cost is low, and the measured object is in close proximity to another object or on an angle line close to the azimuth angle of the measured object. Even if the object is present, or the light (or radio wave) emitted from the measuring instrument that reaches the measuring object is weak, the distance between the measuring instrument and the measuring object can be easily measured. It is possible to provide a possible distance measuring device and distance measuring method.

It shows the conceptual diagram of the conventional optical distance measuring apparatus. It shows a conceptual diagram of a conventional radio wave type distance measuring device. It is a conceptual diagram which showed the measurement range at the time of performing the wide diffusion type transmission by this invention. According to the present invention, it is a conceptual diagram showing an example in which measurement is possible even when there is another object at a distance close to the object to be measured. According to the present invention, it is a conceptual diagram showing an example in which measurement is possible even when another object is present on an azimuth angle close to the object to be measured. An example of the configuration of the distance measuring device according to the example of the present invention is shown, (A) shows a block diagram of the control device and the measuring instrument, and (B) shows the control device and the measured object. It shows a block diagram. It is a flowchart which shows the outline of the series flow of the distance measurement in the distance measuring apparatus by the example of this invention. In the distance measuring device according to the example of the present invention, the signals input to the time digital conversion circuit on the measuring instrument side and the time digital conversion circuit on the measuring object side are represented in chronological order from the upper side. It is a block diagram which showed the example which configured the measuring instrument and the measuring object as a single distance measuring unit about the distance measuring apparatus by the example of this invention. An example of measuring a distance between two points by using a distance measuring device (5000) provided with a distance measuring unit (600) according to the example of the present invention is shown. It is a figure which showed the example of the multipoint plane measurement using the distance measuring apparatus (5000) provided with the distance measuring unit (U1 to U6) by the example of this invention. An example of performing multipoint stereoscopic measurement using a distance measuring device provided with a distance measuring unit (U1 to U6) according to the example of the present invention is shown, and (A) is a plane measurement using the distance measuring unit. Is a conceptual diagram showing an example in which the distance measurement unit is lifted by a known distance L'and three-dimensional measurement including the height is performed. (B) is a multi-point measurement in which the three-point measurement is performed. It is a conceptual diagram which showed the example in the same way as the case of FIG. It is a conceptual diagram which showed the example which applied the Bluetooth (registered trademark) mesh network to the distance measuring apparatus provided with the distance measuring unit by this invention.

The present invention relates to a distance measuring device for measuring the distance between a measuring instrument and a measuring object, and the response output of the measuring object itself is not affected by the reflection of the measured object with respect to the irradiation of light or radio waves from the measuring instrument. It is characterized by performing distance measurement using a measuring instrument, a measuring object, and a control device thereof.

In the present invention, the measuring object placed at the point to be measured is configured to have a function similar to that of the measuring instrument, and light (or radio wave) is output from the measuring instrument, and the measuring object receives (or receives) the light (or radio wave). ) Then, the object to be measured immediately emits a response (or transmits a response) and inputs it to the measuring instrument.

Further, in the present invention, distance measurement is performed by measuring the time difference between the output from the measuring instrument and the response signal input to the measuring instrument, and in that case, the delay time in the circuit between the measuring instrument and the measuring object is determined. It is configured to take into account, make corrections, and perform more accurate distance measurement.

Further, in a further different embodiment of the present invention, the measuring instrument and the measuring object are configured as a single unit, and the functions thereof are appropriately switched and used by the operation by the control device, and the distance measurement and the like are used. It is also possible to do.

Therefore, in the following, first, the basic form of the distance measuring device including the measuring instrument, the measuring object, and these control devices and the usage method thereof will be specifically described, and then the measuring instrument and the measuring object will be described. Mention the integrated distance measurement unit.

In the following description, the same symbols may be used for the same components even if they can take other forms, and the explanations and symbols of overlapping configurations may be partially omitted. .. In addition, some of the drawings may be omitted for the sake of clarity.

6A and 6B show a configuration example of the distance measuring device 1000 according to the example of the present invention, FIG. 6A shows a block diagram of the control device 100 and the measuring instrument 200, and FIG. 6B shows a block diagram of the measuring instrument 200. The block diagram of the control device 100 and the measurement object 300 is shown.

As shown in FIG. 6, the distance measuring device 1000 according to the example of the present invention includes a control device 100, a measuring device 200, and a measuring object 300 as basic components. (Note that in FIGS. 6A and 6B, the configuration including the GPS (Global Positioning System) satellite surrounded by the alternate long and short dash line and its receiving circuit is an optional configuration for using additional functions. It is an element.)
Among the components of the distance measuring device 1000 according to the example of the present invention, the control device 100 is a device that controls the measuring instrument 200 and the measured object 300 as the host of the distance measuring device 1000.

Therefore, the control device 100 has a wireless communication function with the measuring instrument 200 and the measuring object 300, and is generated by transmitting a measurement start signal described later and on the measuring instrument 200 side and the measuring object 300 side, respectively. It is possible to receive various data. The format of the wireless communication function is not particularly limited, but for example, it is possible to use a communication protocol based on the Bluetooth (Bluetooth, Bluetooth, is a registered trademark) communication standard.

Further, the control device 100 has a function of processing data transmitted from the measuring instrument 200 and the measuring object 300, and can perform distance calculation based on these data.

Further, the control device 100 has an input / output interface to the measuring instrument 200 and the measuring object 300 for the above purpose.

Therefore, in the distance measuring device 1000 according to the example of the present invention, as the control device 100, for example, in addition to a general personal computer (PC), various portable information terminals such as a smart phone and a tablet PC can be used. It is also possible to combine and use these as appropriate according to the object to be measured and the situation.

Next, among the constituent elements of the distance measuring device 1000 according to the example of the present invention, the measuring instrument 200 transmits an output signal by light, an electromagnetic wave, or the like to the measuring object 300 in response to the operation by the control device 100, and at the same time, It has a function of receiving a response signal from the measurement object 300, recording the timing of each transmission / reception and the delay time of the circuit in the measuring instrument 200, and transmitting these data to the control device 100.

Therefore, as shown in FIG. 6A, the measuring instrument 200 includes at least the measuring instrument side communication circuit (MCI), the measuring instrument side output circuit (MOC), and the first measuring instrument side input circuit (MIC1). ), A second instrument-side input circuit (MIC2), and an instrument-side time-digital conversion circuit (MTDC), and a central processing unit that controls these circuits inside the instrument 200. It has a device (CPU).

Among the components of the measuring instrument 200, the measuring instrument side communication circuit (MCI) is a circuit for transmitting and receiving between the measuring instrument 200 and the control device 100, and in the present invention, receiving a start signal from the control device 100. In addition to transmitting information on various signals based on the data input to the time digital conversion circuit (MTDC) on the measuring instrument side, which will be described later, to the control device 100 side, remote operation such as starting and stopping the measuring instrument 200 It is also possible to add a signal transmission / reception function for. The measuring instrument side communication circuit (MCI) has a transmission / reception function by wireless communication with the control device 100, but the format of the wireless communication function is not particularly limited. Corresponding to the configuration, it is also possible to use, for example, a communication protocol according to the Bluetooth (registered trademark) communication standard.

Similarly, among the components of the measuring instrument 200, the measuring instrument side output circuit (MOC) is a circuit for transmitting an output signal to the measuring object 300. The output signal may be a laser, a wide-diffusion LED, or other electromagnetic waves, and when electromagnetic waves are used, a wide-angle antenna can also be used, and can be arbitrarily used in advance depending on the object to be measured and the situation. It is possible to select it.

Similarly, among the components of the measuring instrument 200, the first measuring instrument side input circuit (MIC1) is input by feeding back a part of the output signal output by the measuring instrument side output circuit (MOC). It is a circuit. In the present invention, for accurate distance measurement, the measurement start signal (first start signal ST1) from the control device 100 is input in the measuring instrument 200, and then the output signal by the measuring instrument side output circuit (MOC). Is being measured for the time it takes to be sent. Since the measurement uses the measuring instrument side time digital conversion circuit (MTDC) provided in the measuring instrument 200, the measuring instrument side output circuit (MIC1) is used from the first measuring instrument side input circuit (MIC1). The delay signal (MDS1) on the measuring instrument side is output to the time digital conversion circuit (MTDC) on the measuring instrument side when the transmission is made by MOC).

Similarly, among the components of the measuring instrument 200, the second measuring instrument side input circuit (MIC2) is a circuit to which the response signal from the measuring object 300 is input, and when the response signal is input, the response signal is input. , Input the stop signal (STS) to the time digital conversion circuit (MTDC) on the measuring instrument side, which will be described later. Since the second input circuit (MIC2) on the measuring instrument side is basically a receiver for receiving the response signal, it depends on the type of response signal (electromagnetic wave such as light or radio wave) and the irradiation angle. An optimum configuration is made. For example, when the response signal from the measuring object 300 uses a wavelength different from the output signal from the measuring instrument 200, a receiving circuit corresponding to such a response signal is configured. ..

Similarly, among the components of the measuring instrument 200, the measuring instrument side time digital conversion circuit (MTDC) is a circuit that converts the input time or the difference between a plurality of signal input times into digital information.

Inside the measuring instrument 200, the start signal from the control device 100 is input to the measuring instrument side time digital conversion circuit (MTDC) as the first start signal (ST1), and the first measuring instrument side. From the input circuit (MIC1), when the output signal is transmitted by the output circuit (MOC), the delay signal (MDS1) on the measuring instrument side is input, and further, from the input circuit (MIC2) on the second measuring instrument side. , A stop signal (STS) is input with the reception of the response signal.

Therefore, in the time digital conversion circuit (MTDC) on the measuring instrument side, the first start signal (ST1) is used as the start signal (START), and the delay signal (MDS1) on the measuring instrument side is used as the first stop signal (STOP1). , The stop signal (STS) can be processed as a second stop signal (STOP2), and the elapsed time (time interval) between them can be accurately measured. Then, these measurement data are transmitted to the control device 100 via the measuring instrument side communication circuit (MCI) as described above.

Next, among the components of the distance measuring device 1000 according to the example of the present invention, the measuring object 300 has a function of transmitting a response signal to the measuring instrument 200 in response to the output signal from the measuring instrument 200, and also has an output signal. It has a function of measuring the delay time of the circuit in the measurement object 300 from the reception of the signal to the transmission of the response signal and transmitting the data to the control device 100.

Therefore, as shown in FIG. 6B, the measurement object 300 includes at least the measurement object side communication circuit (OCI), the measurement object side output circuit (OOC), and the first measurement object side input circuit (1). It has an OIC1), a second input circuit on the measurement object side (OIC2), and a time digital conversion circuit (OTDC) on the measurement object side, and also controls these circuits inside the measurement object 300. It has a processing unit (CPU).

Among the components of the measurement object 300, the measurement object side communication circuit (OCI) is a circuit that transmits / receives to / from the control device 100, and in the present invention, the measurement object side time digital conversion circuit (OTDC) is exclusively used. The data of the delay time of the circuit in the measurement object 300 is transmitted, and it is also possible to add a signal transmission / reception function for remote operation such as starting and stopping the measurement object 300. Therefore, the measurement object side communication circuit (OCI) has a transmission / reception function by wireless communication with the control device 100, but the format of the wireless communication function is not particularly limited. Corresponding to the configuration, it is also possible to use a communication protocol according to the Bluetooth (registered trademark) communication standard as in the case of the measuring instrument 200.

Similarly, among the components of the measuring object 300, the second measuring object side input circuit (OIC2) receives the output signal from the measuring instrument 200, and also has the measuring object side output circuit (OOC) described later and the measurement. It is a circuit that outputs a second start signal (OST2) to the object-side time-to-digital conversion circuit (OTDC). Since the second input circuit on the measurement object side (OIC2) is basically a receiver for receiving the output signal, it depends on the type of output signal (electromagnetic wave such as light or radio wave) and the irradiation angle. The optimum configuration is made.

Similarly, among the components of the measuring object 300, the measuring object side output circuit (OOC) is a circuit that transmits a response signal in response to the output signal from the measuring instrument 200. More specifically, a second start-up signal (OST2) from the second measurement object side input circuit (OIC2) is input to the measurement object side output circuit (OOC), and the measuring instrument responds accordingly. It is configured to transmit a response signal toward 200.

The response signal may be a laser, a wide-diffusion LED, or other electromagnetic waves as in the case of the measuring instrument 200, and when an electromagnetic wave is used, a wide-angle antenna can also be used for measurement. It is possible to arbitrarily select in advance according to the target and the situation.

Further, since the output circuit (OOC) on the measurement object side does not necessarily have to use the same wavelength as the output signal from the measuring instrument 200, for example, it is possible to transmit a response signal whose band is changed according to the usage situation. It is also possible to configure.

Similarly, among the components of the measurement object 300, the first measurement object side input circuit (OIC1) is input by feeding back a part of the output signal output by the above-mentioned measurement object side output circuit (OOC). It is a circuit. In the present invention, for accurate distance measurement, the time from the reception of the output signal from the measuring instrument 200 to the transmission of the response signal by the measurement object side output circuit (OOC) is measured in the measuring object 300. are doing. Since the measurement uses the time digital conversion circuit (OTDC) on the measurement object side provided in the measurement object 300, the output circuit on the measurement object side (OIC1) from the first input circuit on the measurement object side (OIC1) is used. When the response signal by OOC) is transmitted, the delay signal (ODS1) on the measurement object side is output to the time digital conversion circuit (OTDC) on the measurement object side.

Similarly, among the components of the measurement object 300, the measurement object side time digital conversion circuit (OTDC) is
Similar to the one provided in the measuring instrument 200, it is a circuit that converts an input time or a difference between a plurality of signal input times into digital information.

Then, inside the measurement object 300, the second start-up signal (OST2) from the second measurement object side input circuit (OIC2) is input to the measurement object side time digital conversion circuit (OTDC). The measurement object side delay signal (ODS1) is input from the first measurement object side input circuit (OIC1).

Therefore, in the time digital conversion circuit (OTDC) on the measurement object side, the second start signal (OST2) is used as a start signal (START), and the delay signal (ODS1) on the measurement object side is processed as a stop signal (STOP1). It is possible to accurately measure the elapsed time (time interval) during that period. Then, as described above, these measurement data are transmitted to the control device 100 via the measurement object side communication circuit (OCI).

Next, the procedure for measuring the distance between the measuring instrument 200 and the measuring object 300 in the distance measuring device 1000 configured as described above will be described with reference to FIGS. 7 and 8. Here, FIG. 7 is a flowchart showing an outline of a series of flow of distance measurement in the distance measuring device 1000 according to the example of the present invention, and FIG. 8 is also shown in FIG. 8 on the measuring instrument side in the distance measuring device 1000 according to the example of the present invention. The signals input to the time digital conversion circuit (MTDC) and the time digital conversion circuit (OTDC) on the measurement object side are represented in chronological order from the upper side.

As the present invention relates to the distance measuring device 1000 for measuring the distance between the measuring instrument 200 and the measuring object 300 as illustrated in the above description, these devices are arranged in advance at two points to be measured. When the arrangement is completed, the measurement start signal is transmitted from the control device 100 to the measuring instrument 200. Then, as shown in FIG. 7, in the measuring instrument 200, an output signal is transmitted from the measuring instrument side output circuit (MOC) toward the measuring object 300 (step S100).

At this time, on the measuring instrument 200 side, the measurement start signal is processed as a first start signal (ST1) and input to the measuring instrument side time digital conversion circuit (MTDC) as a START signal. Further, from the measuring instrument side output circuit (MOC) side that transmitted the output signal, the measuring instrument side delay signal (MDS1) is referred to as the first stop signal (MDS1) via the first measuring instrument side input circuit (MIC1). It is input as STOP1).

Therefore, on the measuring instrument 200 side, the time interval between the START signal and the STOP1 signal input to the measuring instrument side time digital conversion circuit (MTDC) is recorded as the circuit delay time in the measuring instrument 200 (step S110). The recorded data is transmitted to the control device 100.

Further, on the measuring object 300 side, the output signal from the measuring instrument side output circuit (MOC) of the measuring instrument 200 in step S100 is received, and the second measurement on the measuring instrument 200 side is performed from the measuring object side output circuit (OOC). A response signal is transmitted to the instrument side input circuit (MIC2) (step S120).

At this time, on the measurement object 300 side, the second activation signal (OST2) generated when the output signal is received by the second measurement object side input circuit (OIC2) is converted to time digital conversion on the measurement object side. From the measurement object side output circuit (OOC) side that was input to the circuit (OTDC) as a START signal and transmitted the response signal, the measurement object side delay signal is passed through the first measurement object side input circuit (OIC1). (ODS1) is input as a stop signal (STOP1) to the time digital conversion circuit (OTDC) on the measured object side.

Therefore, on the measurement object 300 side, the time interval between the START signal and the STOP1 signal input to the measurement object side time digital conversion circuit (OTDC) is recorded as the circuit delay time in the measurement object 300 (step S130). The recorded data is transmitted to the control device 100.

Further, on the measuring instrument 200 side, the response signal from the measuring object 300 is input to the second measuring instrument side input circuit (MIC2), and the stop signal (STS) is input from the second measuring instrument side input circuit (MIC2). ) Is input to the time digital conversion circuit (MTDC) on the measuring instrument side as a second stop signal (STOP2). Then, on the measuring instrument 200 side, the time interval between the START signal and the STOP2 signal input to the measuring instrument side time digital conversion circuit (MTDC) is recorded as the time required for transmission / reception between the measuring instrument 200 and the measuring object 300. The recorded data is transmitted to the control device 100 (step S140).

Then, due to the above progress, the time when the measurement start signal is output, the time when the response signal from the measurement object 300 is received, the circuit delay time in the measurement instrument 200, and the measurement object 300, which are sent to the control device 100, and the measurement object 300. Based on the circuit delay time in, the measurement calculation of the distance between the measuring instrument 200 and the measuring object 300 is performed (step S150), and the result is displayed on the control device 100.

That is, in the control device 100, the measuring instrument side time digital conversion circuit (MTDC) of the measuring instrument 200 and the measuring object side time digital conversion circuit of the measuring object 300, as shown in time series by (a) to (e) in FIG. Data by (OTDC) is input. Then, as shown in FIG. 8, a is the total from the start of the measurement by the first start signal (ST1) based on the measurement start signal to the end of the measurement by the stop signal (STS) in the measuring instrument 200. Time and b are from the start of measurement by the first start signal (ST1) based on the measurement start signal until the output signal is transmitted from the measuring instrument 200 and recorded as the delay signal (MDS1) on the measuring instrument side. The delay time of the circuit in the measuring instrument 200, c is the flight time of the transmission signal from the measuring instrument 200 to the measuring object 300, and d is the response after the second start signal (OST2) is generated on the measuring object 300 side. The delay time of the circuit in the measuring object 300 until the signal (ODS1) is generated, and e is the flight time of the response signal from the measuring object 300 to the measuring instrument 200.

Therefore, from the above, the distance L between the measuring instrument 200 and the measuring object 300 is measured as L = (ab-d) C / 2 when the propagation speed of light or radio wave is C. To.

In the present invention, as described above, if the time interval calculated by the respective time digital conversion circuit (TDC) is known between the measuring instrument 200 side and the measuring object 300 side, the control device 100 and the measuring instrument 200 are used. It is possible to exert the function without strictly synchronizing with the object 300.

Therefore, according to the present invention, it is possible to perform distance measurement by using the response output of the measured object itself without relying on the reflection of the measured object on the irradiation of light or radio waves from the measuring instrument, and further, the measurement can be performed. It is possible to perform more accurate distance measurement by making corrections in consideration of the delay time in the circuit of the instrument and the object to be measured.

Therefore, according to the present invention, it is not necessary to align the beam with the measured object at the time of measurement, although the cost is low, and the measured object is in close proximity to another object or on an angle line close to the azimuth angle of the measured object. Even if the object is present, or the light (or radio wave) emitted from the measuring instrument that reaches the measuring object is weak, the distance between the measuring instrument and the measuring object can be easily measured. It is possible to provide a possible distance measuring device and distance measuring method.

Next, as shown in FIG. 9, a distance measuring device according to the example of the present invention, in which a measuring instrument and a measuring object are configured as a single unit, and their functions are appropriately switched and used by operation by a control device. explain. Here, FIG. 9 shows an example of the distance measuring device (5000) in which the measuring instrument and the measured object are configured as a single distance measuring unit (600) as described above for the distance measuring device according to the example of the present invention. It is a block diagram which showed. Note that, in FIG. 9, as shown in FIG. 6, the configuration including the GPS satellite and its receiving circuit surrounded by the alternate long and short dash line is an optional component for using the additional function.

The distance measuring device (5000) as shown in FIG. 9 is basically composed of a control device 500 as a host and at least two distance measuring units (600). The reason why the number of units is at least two is that the distance measuring unit (600) uses a single housing as a measuring instrument and a measuring object by a function changeover switch. Therefore, when measuring a distance between at least two points, the distance is measured. This is because two units are required.

Therefore, the control device 500 used in the distance measuring device (5000) has a function of controlling at least two distance measuring units (600), and when performing multipoint measurement as described later, the control device 500 has a function of controlling at least two distance measuring units (600). It is equipped with the control function of more distance measuring units (600).

Next, the distance measuring unit (600) used in the distance measuring device (5000) basically has the same functions as the measuring instrument 200 and the measuring object 300 used in the distance measuring device (1000) described above. However, each function is switched and used by operating the function changeover switch (SW1, SW2). The function changeover switch (SW1, SW2) is basically operated by the operation of the control device 500.

Further, in the distance measuring unit (600), the measuring instrument 200 and the measuring object 300 are combined into one unit, so that the time digital conversion circuit (TDC) is also a single unit, and the above-mentioned function changeover switch is used. With (SW1, SW2), the functions of the time digital conversion circuit (MTDC) on the measuring instrument side and the time digital conversion circuit (OTDC) on the measuring object side in the distance measuring device (1000) described above are combined with a single time digital conversion circuit (TDC). ) Is configured to replace it.

Therefore, the distance measuring unit (600) used in the distance measuring device (5000) basically includes a communication circuit (CI), an output circuit (OC), and the same as the distance measuring device (1000) described above. It has a first input circuit (ICI), a second input circuit (IC2), a time digital conversion circuit (TDC), and the above-mentioned function changeover switches (SW1, SW2), and these distance measurement units are also included. It is equipped with a CPU controlled within (600).

Among the components of the distance measuring unit (600), the communication circuit (CI) transmits and receives to and from the control device in the same manner as in the case of the distance measuring device (1000).

Further, the output circuit (OC) transmits an output signal when the distance measuring unit (600) is used as a measuring instrument, and transmits a response signal when the distance measuring unit (600) is used as a measuring object.

Further, the first input circuit (IC1) is a circuit that feeds back and inputs a signal from the output circuit (OC), as in the case of the distance measuring device (1000). Therefore, when this distance measuring unit (600) is used as a measuring instrument, it is in the circuit from the first input circuit (IC1) until the output signal is transmitted based on the input feedback signal. A signal (MDS1) for measuring the delay time in is output. On the other hand, when the distance measuring unit (600) is used as a measuring object, the response signal is transmitted from the first input circuit (IC1) based on the input feedback signal. A signal (ODS1) for measuring the delay time in the circuit of is output.

Further, the second input circuit (IC2) is also the same as in the case of the distance measuring device (1000), and when the distance measuring unit (600) is used as a measuring object, it receives an output signal and is used as a measuring instrument. When used, it receives a response signal. Then, when the distance measuring unit (600) functions as a measuring instrument based on the received signal, a stop signal (STS) as described above is generated for the distance measuring device (1000) and used as a measuring object. If it works, it will generate a second activation signal (OTS2) as described above, which signal will be input to the time-to-digital converter (TDC).

Further, the function changeover switch (SW1, SW2) is a switch for switching whether the distance measuring unit (600) is used as a measuring instrument or as a measuring object, as described above.

Two such function changeover switches (SW1 and SW2) are described as SW1 and SW2 in the description of FIG. 9, and measurement is performed when each switch is connected to the a side in this distance measurement unit (600). It will function as a device, and when connected to the b side, it will function as a measuring object. However, the form and number of such function changeover switches are merely examples, and if the functions can be achieved in the distance measuring unit (600), there is no limitation on them.

Then, according to the distance measuring device 5000 using the distance measuring unit (600) as described above, for example, the measurement as shown in FIGS. 10 to 13 below is possible.

FIG. 10 shows an example in which the distance measuring unit (600) according to the present invention is used as UA and UB, and the distance L between two points is measured by using the distance measuring device (5000) that switches the functions respectively. , The basic function of the distance measuring device according to the example of the present invention is shown.

Therefore, even if the distance measuring device (5000) using the distance measuring unit according to the present invention is used, for example, even if the directions of the distance measuring unit (600) are deviated from each other or the horizontal or vertical is not obtained, there is no problem. It is possible to measure the distance between two points, UA and UB.

Further, FIG. 11 is a diagram showing an example of multipoint plane measurement using a distance measuring device 5000 including a distance measuring unit (U1 to U6) according to the present invention. In FIG. 11, U1 to U6 show an example in which distance measuring units (600) are arranged respectively, and a place to be measured in a plane is surrounded by a plurality of distance measuring units (U1 to U6) in this way, and a triangle is formed. It is possible to automatically measure the figure / length / angle / area by appropriately switching the function of each unit between the measuring instrument and the measuring object.

Further, FIG. 12 shows an example of performing multipoint three-dimensional measurement using a distance measuring device provided with a distance measuring unit according to the present invention, and FIG. 12A shows a plane measurement using the distance measuring unit U. It is a conceptual diagram which showed the example which lifted the distance measurement unit U by the known distance L', and performed the three-dimensional measurement including the height, and (B) is the multi-point measurement which performed the three-dimensional measurement. An example is shown in the same manner as in the case of FIG. As shown in FIG. 12A, for example, in the distance measuring device (5000), if the distance measuring unit U is lifted and measured again by a known distance after performing the plane measurement, the solid including the height is measured. It is possible to perform a survey. Therefore, if this is used for multipoint measurement, it is possible to perform multipoint measurement three-dimensionally as shown in FIG. 12B.

Therefore, even with the distance measuring device (5000) according to the example of the present invention having the distance measuring unit (600), when the measured object is close to another object or another object is on an angle line close to the azimuth angle of the measured object. Even when an object is present or the light (or radio wave) emitted from the measuring instrument that reaches the measuring object is weak, the distance between the measuring instrument and the measuring object can be easily measured. It is possible to provide a distance measuring device and a distance measuring method, and further, effective use such as multi-point measurement is possible.

In addition, the example described above shows an example of the practice of the present invention, and each component can be changed within the scope of the gist of the present invention.

Therefore, for example, in the control device described above, in addition to the transmission / reception function described above, for example, it may be possible to instruct the selection of the type of output signal and response signal and the frequency to be used, and the distance measurement unit may be used. When a plurality of connections are made, these operations may be automated and the switching of functions between the measuring instrument and the measuring object may be automated.

Further, in the present invention, it is also possible to calculate the absolute position and the absolute direction by adding the GPS receiving circuit as shown by the alternate long and short dash line in FIG. 6 or 9 to each configuration.

That is, the accuracy of GPS is only about 40 mm even with the highest performance RTK, and the accuracy is low, but in multipoint distance measurement, if at least two units can receive GPS, the absolute position and absolute orientation should be calculated for all points. Is also possible.

Further, in the present invention, although it is possible to use Bluetooth (registered trademark) communication, it is also possible to calculate the absolute position and the absolute orientation by applying it to multipoint measurement.

That is, in Bluetooth (registered trademark) 5.1, techniques for detecting the direction of radio waves such as AoA (Angle of Arrival) and AoD (Angle of Departure) have also been put into practical use. By using such Bluetooth (registered trademark) technology, the positional relationship (distance and angle) between the control device and the distance measurement unit can be specified by communicating with the host (control device) and any one or two distance measurement units. It is possible. Since the control device can know its own absolute position by implementing GPS, it is possible to calculate the absolute position and the absolute direction for all points with the position information of the control device as the base point.

Further, the measurement range of the distance measuring unit according to the present invention can be expanded as follows.

That is, in multipoint distance measurement, as long as the distance between the three surrounding units is within the maximum distance range (the maximum distance between the units determined by the signal strength of light or radio waves), it is possible to measure in any wide area. However, the distance to the host can be an issue. All units need to communicate with the host, but when measuring large areas, distant units may not be able to communicate with the host (control device).

Therefore, in such a case, the measurement range is expanded by using the Bluetooth (registered trademark) function between the control device and the distance measuring unit according to the present invention using Bluetooth (registered trademark) communication. It is also possible.

More specifically, in the present invention, by mounting Bluetooth (registered trademark) on all distance measuring units and constructing a Bluetooth (registered trademark) mesh network, the control device can also communicate with a distant distance measuring unit. .. A mesh network is a method in which information is sent to units (nodes) in the vicinity of oneself, and information is transmitted one after another like a bucket relay. In addition, this function enables the control device to be used not only as a high-performance product with a powerful Bluetooth (registered trademark) circuit such as class 1, but also as a popular product.

FIG. 13 is a conceptual diagram showing an example in which such a mesh network is applied to the distance measuring unit according to the present invention. The double circles in the figure indicate the distance measurement unit, the black line is the mesh network, and the shaded area is the area covered by Bluetooth (registered trademark) from the control device that is the host. The arrow in the figure shows an example of how the host data is transmitted from the unit α that the Bluetooth (registered trademark) of the control device reaches to the unit β that does not reach.

Therefore, in the present invention, it is possible to expand the measurement range by utilizing such a function.

100 500 Control device 200 Measuring instrument 300 Measuring object 600 U U1 to U6 UA UB Distance measuring unit 1000 5000 Distance measuring device
L Distance between the measuring instrument and the object to be measured
MCI measuring instrument side communication circuit
MOC measuring instrument side output circuit
MIC1 Input circuit on the first measuring instrument side
MIC2 2nd instrument side input circuit
MTDC measuring instrument side time digital conversion circuit
OCI measurement object side communication circuit
OOC measurement object side output circuit
OIC1 Input circuit on the first measurement object side
OIC2 2nd measurement object side input circuit
OTDC measurement object side time digital conversion circuit
ST1 1st start signal
MDS1 Instrument side delay signal
OST2 2nd start signal
ODS1 Measurement object side delay signal
STS stop signal
CI communication circuit (distance measurement unit)
OC output circuit (distance measurement unit)
IC1 1st input circuit (distance measurement unit)
IC2 2nd input circuit (distance measurement unit)
TDC time digital conversion circuit (distance measurement unit)

In order to solve the above problems, the present invention is a distance measuring device for measuring a distance between a measuring instrument and a measuring object, and the distance measuring device includes the measuring instrument, the measuring object, and a control device. The control device is wirelessly connected to the measuring instrument and the measuring object, and controls the measuring instrument and the measuring object, and the measuring instrument is based on the measurement start signal of the control device. , The output signal is transmitted to the measuring object and the response signal from the measuring object is received, and the measuring object transmits a response signal to the measuring instrument in response to the output signal from the measuring instrument. The control device outputs the measurement start signal, the time when the response signal from the measurement object is received, and the time until the measuring instrument transmits the output signal according to the measurement start signal from the control device. The measuring instrument and the measuring object are based on the circuit delay time in the measuring instrument and the circuit delay time in the measuring object until the measuring object transmits a response signal in response to an output signal from the measuring instrument. The measuring instrument measures the distance between the measuring instrument, the measuring instrument side communication circuit (MCI) with the control device, the measuring instrument side output circuit (MOC), the first measuring instrument side input circuit (MIC1), and the like. It has a second measuring instrument side input circuit (MIC2) and a measuring instrument side time digital conversion circuit (MTDC), and the measuring object is a measuring object side communication circuit (OCI) with the control device and a measuring object. It has a side output circuit (OOC), a first measurement object side input circuit (OIC1), a second measurement object side input circuit (OIC2), and a measurement object side time digital conversion circuit (OTDC). The control device transmits a measurement start signal to the measuring instrument, and the measuring instrument bases the measurement start signal on the measuring instrument side output circuit (MOC) via the measuring instrument side communication circuit (MCI). The first start signal (ST1) is input to the measuring instrument side time digital conversion circuit (MTDC), and the first start signal (ST1) is input to the measuring instrument side output circuit (MOC). In response to the first activation signal (ST1), the output signal is transmitted to the second measurement object side input circuit (OIC2) of the measurement object, and a part of the output signal is part of the first measurement object. It is input to the measuring instrument side input circuit (MIC1), and the first measuring instrument side input circuit (MIC1) responds to the measuring instrument side delay signal (MDS1) to the measuring instrument side time digital conversion circuit (MTDC). ) Is input, and the second measurement object side input circuit (OIC2) of the measurement object receives the output signal from the measuring instrument. By receiving, the second start signal (OST2) is input to the measurement object side output circuit (OOC), and the measurement object side output circuit (OOC) responds to the second start signal (OST2). , The response signal is transmitted to the measuring instrument side input circuit (MIC2) of the second measuring instrument, and a part of the response signal is input to the first measuring object side input circuit (OIC1). Accordingly, the first measurement object side input circuit (OIC1) inputs the measurement object side delay signal (ODS1) to the measurement object side time digital conversion circuit (OTDC), and the second measurement object side input circuit (OIC1). By receiving the response signal from the measurement object, the circuit (MIC2) inputs a stop signal (STS) to the time digital conversion circuit (MTDC) on the measuring instrument side, and the control device is on the measuring instrument side. The time of the first start signal (ST1), the delay signal (MDS1) on the measuring instrument side, and the stop signal (STS) input to the time digital conversion circuit (MTDC), and the time digital conversion on the measuring object side. Measuring the distance between the measuring instrument and the measuring object based on the time of the second start signal (OST2) and the delay signal on the measuring object side (ODS1) input to the circuit (OTDC). Provided is a distance measuring device characterized by.

Claims (7)

A distance measuring device that measures the distance between a measuring instrument and an object to be measured.
The distance measuring device includes the measuring instrument, the measured object, and a control device.
The control device is wirelessly connected to the measuring instrument and the measuring object, and is also connected to the measuring object.
Control the measuring instrument and the measured object,
The measuring instrument transmits an output signal to the measured object and receives a response signal from the measured object based on the measurement start signal of the control device.
The measuring object transmits a response signal to the measuring device in response to the output signal from the measuring instrument.
The control device outputs the measurement start signal, the time when the response signal from the measurement object is received, and the time until the measurement device transmits the output signal according to the measurement start signal from the control device. Based on the circuit delay time in the measuring instrument and the circuit delay time in the measuring object until the measuring object transmits a response signal in response to the output signal from the measuring instrument.
A distance measuring device characterized by measuring the distance between the measuring instrument and the measuring object. The measuring instrument includes a measuring instrument side communication circuit (MCI) with the control device, a measuring instrument side output circuit (MOC), a first measuring instrument side input circuit (MIC1), and a second measuring instrument side input. It has a circuit (MIC2) and a time digital conversion circuit (MTDC) on the measuring instrument side.
The measurement object includes a measurement object side communication circuit (OCI) with the control device, a measurement object side output circuit (OOC), a first measurement object side input circuit (OIC1), and a second measurement object side input. It has a circuit (OIC2) and a time-to-digital conversion circuit (OTDC) on the measurement object side.
The control device transmits a measurement start signal to the measuring instrument, and the control device transmits the measurement start signal to the measuring instrument.
Based on the measurement start signal, the measuring instrument inputs a first start signal (ST1) to the measuring instrument side output circuit (MOC) via the measuring instrument side communication circuit (MCI), and the above-mentioned The first start signal (ST1) is input to the time digital conversion circuit (MTDC) on the measuring instrument side, and the first start signal (ST1) is input.
The measuring instrument side output circuit (MOC) transmits the output signal to the second measuring object side input circuit (OIC2) of the measuring object in response to the first starting signal (ST1), and at the same time, the said A part of the output signal is input to the first measuring instrument side input circuit (MIC1), and accordingly, the first measuring instrument side input circuit (MIC1) is the measuring instrument side time digital conversion circuit (MIC1). Input the delay signal (MDS1) on the measuring instrument side to MTDC), and
The second measurement object side input circuit (OIC2) of the measurement object receives the output signal from the measuring instrument, so that the measurement object side output circuit (OOC) receives a second activation signal (OST2). And enter
The measurement object side output circuit (OOC) transmits the response signal to the measuring instrument side input circuit (MIC2) of the second measuring instrument in response to the second start signal (OST2), and the response signal. A part of the signal is input to the first measurement object side input circuit (OIC1), and accordingly, the first measurement object side input circuit (OIC1) is the measurement object side time digital conversion circuit (OTDC). ), Input the delay signal (ODS1) on the measurement object side,
The second measuring instrument side input circuit (MIC2) inputs a stop signal (STS) to the measuring instrument side time digital conversion circuit (MTDC) by receiving the response signal from the measuring object.
The control device has a time of the first start signal (ST1), the delay signal (MDS1) on the measuring instrument side, and the stop signal (STS) input to the time digital conversion circuit (MTDC) on the measuring instrument side. The measuring instrument and the measuring object are based on the time of the second start signal (OST2) and the delay signal (ODS1) on the measuring object side, which are input to the time digital conversion circuit (OTDC) on the measuring object side. The distance measuring device according to claim 1, which measures the distance between and. The distance measuring device according to claim 1 or 2.
The distance measuring device includes the functions of the measuring instrument and the measured object, a distance measuring unit having a function changeover switch, and the control device.
By using the function changeover switch, at least one of the two distance measuring units is used as the measuring instrument, and the other one is used as the measuring object to measure the distance between the distance measuring units. Device. The distance measuring unit includes a communication circuit (CI) and an output circuit (OC) with the control device, a first input circuit (IC1), a second input circuit (IC2), and a time-digital conversion circuit (TDC). ), And the distance measuring device according to claim 3, wherein the function of the measuring instrument and the measured object can be switched by the operation of the function switching switch by the control device. The distance measuring device according to any one of claims 1 to 4, wherein the connection between the measuring instrument and the measuring object by the control device is based on a communication protocol based on a Bluetooth (registered trademark) communication standard. The distance measuring device according to any one of claims 1 to 5, further comprising a GPS receiving circuit in the measuring instrument and the measuring object. A distance measuring method using the distance measuring device according to claim 1.
A step in which the measuring instrument transmits the output signal to the measuring object based on the measurement start signal from the control device.
A step of recording the circuit delay time in the measuring instrument until the output signal is transmitted from the measuring instrument based on the measurement start signal from the control device, and
A step of receiving the output signal from the measuring instrument and transmitting the response signal to the measuring instrument by the measuring object.
A step of recording the circuit delay time in the measured object from receiving the output signal from the measuring instrument to transmitting the response signal from the measured object.
The control device outputs the measurement start signal, receives the response signal from the measurement object, the circuit delay time in the measurement instrument, and the circuit delay time in the measurement object. A distance measuring method comprising a step of measuring a distance between a measuring instrument and the measured object.

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