JP2003028943A - Method and apparatus for delay time measurement in base station - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure delay time in a base station, which transmits a signal to a mobile terminal, in synchronization with the GPS system time. SOLUTION: In order to calculate the delay time in the base station as a measuring object, a dummy base station 100 and a mobile apparatus 200 are used. The station 100 comprises a GPS receiver simulator 101 and a base-station simulator 102. The simulator 102 transmits a signal synchronized with the GPS system time from the simulator 101; the mobile apparatus 200 receives signals transmitted from the base station as the measuring object and the station 100 and finds the time difference between both, on the basis of the reception timing of the signal transmitted from the station 100 and on the basis of the reception timing of the signal transmitted from the base station as the measurement object; the propagation time of the signal between the base station as the measuring object, and the mobile apparatus 200 is subtracted from the time difference; and the delay time in the base station as the measuring object is calculated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a delay time measuring method and a delay time measuring apparatus for measuring a delay time in a base station which transmits a signal to a mobile terminal in synchronization with GPS system time.

[0002]

2. Description of the Related Art In a mobile terminal (for example, a mobile terminal such as a mobile phone), a GPS signal from a GPS satellite and a signal transmitted from a peripheral base station in synchronization with GPS system time are received, and the received GPS signal and The mobile terminal grasps the current position by transmitting the signal from the base station to the position calculation server via the network, calculating the position of the mobile terminal with this position calculation server, and returning the calculation result to the mobile terminal. A system capable of doing so has been proposed (see FIG. 9).

[0003]

In the base station, the GP
When a signal is generated and transmitted in synchronization with the S system time, it is delayed by a predetermined time with respect to the GPS system time due to the delay due to the internal circuit element of the base station, the wiring delay in the cable (coaxial cable) to the antenna, etc. Then, the signal is transmitted. When such a delay time occurs, an error occurs when the pseudo distance from the base station to the mobile terminal is calculated based on the signal from the base station, and the position of the mobile terminal cannot be calculated accurately.

The present invention has been made in view of the above problems, and an object thereof is to measure a delay time generated in a base station.

Another object of the present invention is to enable the position of a mobile terminal to be accurately calculated based on a signal from a base station.

[0006]

In order to achieve the above object, the present invention employs the technical means described in each of the claims.

According to the invention described in claim 1,
A signal transmitted from the base station to be measured in synchronization with the GPS system time is received, and a time difference between the time when the signal from the base station is received and the GPS system time is obtained. Since this time difference corresponds to the sum of the delay time at the base station and the propagation time of the signal from the base station, the delay time at the base station is calculated by subtracting the propagation time of the signal from the base station from the above time difference. be able to.

According to the second aspect of the invention, the signal transmitted from the transmitting means for transmitting the signal synchronized with the GPS system time is received in a state where the propagation time of the signal is substantially zero. Also, it receives a signal transmitted from the base station to be measured in synchronization with the GPS system time. Then, the time difference between the time when the signal from the transmitting means is received and the time when the signal from the base station is received is obtained. Here, since the signal from the transmission means is received with the propagation time being substantially zero, the above-mentioned time difference is GP.
It represents the time difference from the S system time. Therefore, according to the present invention, the delay time at the base station can be calculated from the time difference described above, as in the case of the first aspect of the invention.

According to the invention described in claim 3, the signal transmitted from the base station to be measured in synchronization with the GPS system time is received. Then, in the present invention, the time difference between the time when the signal from the base station is received and the GPS system time by the GPS receiver is obtained by using the GPS system time by the GPS receiver. Therefore, according to the present invention, the delay time at the base station can be calculated from the time difference described above, as in the case of the first aspect of the invention.

According to the invention described in claim 4, the transmitting means for transmitting the signal synchronized with the GPS system time is arranged adjacent to the base station to be measured and receives the signal transmitted from the transmitting means. , Receives a signal transmitted from the base station in synchronization with GPS system time. Since the signal transmitted from the transmitting means is synchronized with the GPS system time, the base station is determined by the time difference between the time when the signal from the transmitting means is received and the time when the signal from the base station is received. The delay time at can be determined.

According to the invention described in claims 5 to 8, it is possible to provide an apparatus for measuring the delay time by using the delay time measuring method described in any one of claims 1 to 4.
Then, in those devices, if the data of the delay time is registered in the position calculation server as in the invention described in claim 9, the signal from the base station used when calculating the position of the mobile terminal is corrected. The position of the mobile terminal can be calculated accurately.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION (First Embodiment) Referring to FIG.
A method of measuring the delay time at the base station will be described. In addition, in this embodiment and various embodiments described later, the base station includes a mobile terminal and a CDMA (Code Divisi).
on Multiple Access) CDMA for communication
Each base station is a base station, and each base station transmits a signal in synchronization with the GPS system time by the GPS signal received by the GPS receiver. Further, among the base stations, a base station whose delay time is to be measured will be described as a measurement and measurement base station.

In this embodiment, in order to calculate the delay time of the measurement target base station, the pseudo base station 100 and the mobile unit 20 are
0 is used.

The pseudo base station 100 includes a GPS receiver simulator 101, a base station simulator 102, and an antenna 1.
And 03. The base station simulator 102 is a GPS
It is composed of a transmitter (transmitting means) for transmitting a signal synchronized with the GPS system time from the receiver simulator 101, and the timing for transmitting the signal from the antenna is G.
It is adjusted to be perfectly synchronized with the PS system time. That is, the timing of outputting the signal from the base station simulator 102 is adjusted so that the timing of transmitting the signal from the antenna 103 matches the GPS system time. As the GPS receiver simulator 101, a GPS receiver that receives GPS signals from GPS satellites can be used, as well as a device that generates a GPS system time, such as a high-precision clock.

The mobile device 200 is a receiver 2 that receives signals transmitted from the measurement target base station and the pseudo base station 100.
02, the time difference between the two is calculated from the reception timing of the signal transmitted from the pseudo base station 100 and the reception timing of the signal transmitted from the measurement target base station. In addition,
If the signal transmitted from the pseudo base station 100 is perfectly synchronized with the GPS system time, the time difference obtained as described above represents the time difference from the GPS system time. Further, it is assumed that the antenna 103 of the pseudo base station 100 and the antenna 201 of the mobile device 200 are located close to each other, and the signal propagation time from the pseudo base station 100 to the mobile device 200 is substantially zero (substantially zero). Then,
The delay time at the measurement target base station can be calculated by subtracting the signal propagation time between the measurement target base station and the mobile device 200 from the above-mentioned time difference. The delay time calculation unit 203 calculates the delay time.

The above-mentioned measurement target base station and mobile unit 2
The signal propagation time between 00 can be obtained from the distance between the measurement target base station and the mobile device 200. The distance between the measurement target base station and the mobile device 200 is set by the user using the key operation unit 2
By performing an input operation on 04, the delay time calculation unit 20
3 can be entered. In addition, the mobile device 200 is GP
If it is possible to detect its own position (latitude, longitude, altitude) with the S receiver, the position of the measurement target base station (latitude, latitude,
By obtaining (longitude, altitude), the distance between the measurement target base station and the mobile device 200 may be calculated. The position of the base station can be obtained from a server that holds the position information of each base station or directly from the base station.

The mobile device 200 outputs the delay time data calculated by the delay time calculation unit 203 from the delay time output unit 205 and registers it in the position calculation server shown in FIG. 9 via the network. By performing such measurement for each base station, the base station and the delay time data in the base station are stored in the position calculation server in association with each other.

The position calculation server, when performing positioning calculation based on the GPS signal from the mobile terminal and the signal from the base station, uses the delay time data registered for the base station for the signal from the base station. Make a correction. That is, the position calculation server corrects the signal from the base station using the delay time data registered in the position calculation server as a correction value. By performing such a correction, the position of the mobile terminal can be accurately calculated even when the signal from the base station is used for the positioning calculation.

Next, a procedure for measuring the delay time in the above-described measurement target base station will be described with reference to the flowchart shown in FIG. 2 and the timing chart shown in FIG.

First, in the pseudo base station 100, the base station simulator 102 is synchronized with the GPS system time (step 101). Specifically, the base station simulator 102 is adjusted so that the GPS receiver simulator 101
The base station simulator 102 is accurately time-synchronized, and the timing of transmitting a signal from the antenna 103 is matched with the GPS system time. Next, the PN number of the measurement target base station is input into the neighbor list of the base station simulator 102 (step 102).
In the communication using the CDMA system, the base station with the PN number in the neighbor list can be the search target. Next, the pseudo base station 100 and the mobile device 200 are placed close to each other so that the signal propagation time from the pseudo base station 100 to the mobile device 200 becomes almost zero (step 103).

After that, the pseudo base station 10 is added to the mobile unit 200.
Receive radio waves transmitted from 0 (step 10
4). In this case, the timing at which the mobile device 200 receives the radio wave transmitted from the pseudo base station 100 is almost completely synchronized with the GPS system time (see the base station simulator transmission wave in FIG. 3).

Next, the mobile device 200 is caused to search for the measurement target base station using the PN number of the measurement target base station in the neighbor list of the base station simulator 102, and to receive the radio wave transmitted from the measurement target base station. (Step 10
5). In this case, the timing of receiving the radio wave transmitted from the measurement target base station is delayed from the GPS system time by a time difference T ₀ , as shown in FIG.

The mobile device 200 has a measurement target base station and a mobile device 2 input by a user or calculated based on the position of the measurement target base station and the position of the mobile device 200.
The propagation time T _A of the signal between the measurement target base station and the mobile device 200 is obtained from the distance between 00 (step 106). Since the time difference T ₀ described above corresponds to the sum of the delay time T and the propagation time T _{A at} the measurement target base station as shown in FIG. 3, by subtracting the propagation time T _A from the time difference T ₀ , the measurement target base station The delay time T at the station is calculated (step 107). The mobile device 200 registers the calculated delay time T in the position calculation server as the delay time of the measurement target base station (step 108).

In the above embodiment, the mobile unit 20
Although a measurement device for calculating the delay time T is shown as 0, the measurement device is configured by the mobile device 200 and the personal computer 300 as shown in FIG. The reception timing signal from the pseudo base station 100 may be output and input to the personal computer 300, and the personal computer 300 may calculate the delay time T. Therefore, the personal computer 300 receives the reception timing signal from the mobile device 200, the reception timing signal input unit 301, the key operation unit 302, the delay time calculation unit 302 that calculates the delay time T, and the delay time T. And a delay time output unit 304 for performing an output for registration in the calculation server. (Second Embodiment) A second embodiment of the present invention will be described with reference to FIG. In the second embodiment, the delay time T in the measurement target base station is calculated without using the pseudo base station 100 as in the first embodiment.

For this reason, the mobile device 200 has a GPS receiver 206. The delay time calculation unit 203 uses the receiver 20
When the radio wave is received from the measurement target base station by 2, the time difference T ₀ from the GPS system time by the GPS receiver 206 is obtained from the reception timing. The subsequent operation is similar to that of the first embodiment. FIG. 6 shows a timing chart in this embodiment.

In this embodiment, as shown in FIG. 5, a plurality of base stations (base station A, base station B, ...) Can be measured simultaneously and their respective delay times T can be obtained at the same time. (Third Embodiment) A third embodiment of the present invention will be described with reference to FIG. In the third embodiment, a transmitter (transmitting means) 4 dedicated to measurement, which receives a GPS signal and transmits a signal (for example, a pilot signal) synchronized with the GPS signal with high accuracy.
00 is arranged adjacent to the measurement target base station. Mobile 2
In 00, the receiver 202 receives the signal from the transmitter 400 and the signal from the measurement target base station.

In this case, as shown in the timing chart of FIG. 8, the pilot signal from the transmitter 400 is GP
Since it is transmitted in synchronization with the S system time with high accuracy,
The mobile device 200 receives the signal with a delay of the propagation time T _A. Further, the signal from the measurement target base station is received with a delay of the delay time and the propagation time T _{A at} the measurement target base station. Therefore, the delay time calculation unit 203 can calculate the delay time T in the measurement target base station by obtaining the time difference T ₀ between the reception timings of the two signals. The subsequent operation is similar to that of the first embodiment.

In order to distinguish the pilot signal from the transmitter 400 and the pilot signal included in the signal from the measurement target base station, the PN which is not normally used as the pilot signal from the transmitter 400. Use a number (for example, number 0).

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a delay measuring device in a base station according to a first embodiment of the present invention.

FIG. 2 is a flowchart showing a procedure for measuring a delay time at a measurement target base station using the device shown in FIG.

FIG. 3 is a timing chart for explaining the operation of the device shown in FIG.

FIG. 4 is a diagram showing a modified example of the device shown in FIG.

FIG. 5 is a diagram showing a configuration of a delay measuring device in a base station according to a second embodiment of the present invention.

FIG. 6 is a timing chart used to explain the operation of the apparatus shown in FIG.

FIG. 7 is a diagram showing a configuration of a delay measuring device in a base station according to a third embodiment of the present invention.

8 is a timing chart provided for explaining the operation of the apparatus shown in FIG.

FIG. 9: Calculates the position of the mobile terminal in the position calculation server,
It is a figure which shows the outline | summary of the system which enabled a mobile terminal to grasp | ascertain a present position by returning the calculation result to a mobile terminal.

[Explanation of symbols]

100 ... Pseudo base station, 101 ... GPS receiver simulator, 102 ... Base station simulator, 103 ... Antenna,
200 ... mobile unit, 201 ... antenna, 202 ... receiver,
203 ... Delay time calculation unit, 204 ... Key operation unit, 205
... Delay time output section.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Michio Shamoto             1-1, Showa-cho, Kariya city, Aichi stock market             Inside the company DENSO F-term (reference) 5J062 AA08 AA13 BB05 CC07 DD12                       EE01                 5K022 EE01 EE36                 5K042 AA06 BA08 CA11 CA12 DA15                       EA01 EA13 FA11 GA12 LA11                 5K067 CC10 DD19 DD25 DD30 EE02                       EE10 EE12 EE23 FF03 FF05                       HH21 JJ56 JJ64 LL11

Claims (9)

[Claims] 1. A base station as a measurement target receives a signal transmitted in synchronization with a GPS system time, obtains a time difference between the time when the signal from the base station is received and the GPS system time, and determines the base. A delay time measuring method characterized by calculating a delay time at the base station by subtracting a propagation time of a signal from the station from the time difference. 2. A GPS system is received from a base station to be measured by receiving a signal transmitted from transmitting means for transmitting a signal synchronized with GPS system time, in a state where the propagation time of the signal is substantially zero. Receiving the signal transmitted in synchronization with the time, while determining the time difference between the time when the signal from the transmission means is received and the time when the signal from the base station is received,
A delay time measuring method, wherein a delay time at the base station is calculated by subtracting a propagation time of a signal from the base station from the time difference. 3. A signal transmitted from a base station to be measured in synchronization with GPS system time is received, and a time difference between the time when the signal from the base station is received and the GPS system time by a GPS receiver is obtained. A delay time measuring method, wherein a delay time in the base station is calculated by subtracting a propagation time of a signal from the base station from the time difference. 4. A transmitting means for transmitting a signal synchronized with a GPS system time is arranged adjacent to a base station to be measured, receives a signal transmitted from the transmitting means, and transmits the GPS system time from the base station. The signal transmitted synchronously is received, and the time difference between the time when the signal from the transmitting means is received and the time when the signal from the base station is received is set as the delay time in the base station. Delay time measurement method. 5. A means for receiving a signal transmitted from a base station to be measured in synchronization with GPS system time, and a time difference between the time when the signal from the base station is received and the GPS system time, A delay time measuring device, comprising means for calculating a delay time in the base station by subtracting a propagation time of a signal from the base station from the time difference. 6. A transmission device for transmitting a signal synchronized with GPS system time, and a measuring device for receiving the signal transmitted from the transmission device in a state where the propagation time is substantially zero. The measuring device receives the signal transmitted from the transmitting unit and the signal transmitted from the measurement target base station in synchronization with the GPS system time, the time when the signal is received from the base station simulator, and the base. And a time difference with the time when the signal from the station is received, and subtracting the propagation time of the signal from the base station from the time difference, means for calculating the delay time in the base station Time measuring device. 7. A means for receiving a signal transmitted in synchronization with a GPS system time from a base station to be measured, a GPS receiver, a reception time point of the signal transmitted from the base station, and the GPS.
A delay time measuring device comprising means for calculating a delay time at the base station by obtaining a time difference from the GPS system time by the receiver and subtracting a propagation time of a signal from the base station from the time difference. . 8. A base station to be measured is arranged adjacent to the base station,
Transmitting means for transmitting a signal synchronized with the GPS system time; means for receiving the signal transmitted from the transmitting means and the signal transmitted from the base station in synchronization with the GPS system time; and a signal from the transmitting means Means for setting a time difference between a time point when the signal is received and a time point when the signal from the base station is received as a delay time in the base station. 9. A signal from the base station transmitted from a mobile terminal that receives a signal transmitted from the base station in synchronization with GPS system time is received, and the position of the mobile terminal is calculated based on the signal. In order to correct the signal from the base station used when the position calculation server calculates the position of the mobile terminal, the delay time data is transmitted to the position calculation server that returns the calculation result to the mobile terminal. 9. A means for registering is provided.
The delay time measuring device according to any one of 1.