KR102106488B1 - Apparatus and method of measuring receive sensitivity using frame control message slot of hipass terminal, conputer readable medium - Google Patents

Abstract

The apparatus for measuring the reception sensitivity of a high-pass terminal using FCMS according to an embodiment of the present invention modulates the FCMS test data and transmits the modulated FCMS test data at a predetermined cycle according to a predetermined transmission power, and the modulated FCMS A high-pass terminal that receives and demodulates test data and counts the number of demodulated FCMS test data, and a controller that calculates the reception rate of FCMS test data based on the number of FCMS test data counted during a preset time and a preset period. ;, The controller sets the reception sensitivity of the high-pass terminal according to the received rate of the calculated FCMS data, and the FCMS test data includes preamble items, payload items, and cyclic redundancy in which arbitrary data of a predetermined size is input. Consists of one FCMS data containing CRC items for check, high pass In the end, when the random data input to the preamble item among the demodulated FCMS test data matches and the cyclic redundancy check by the CRC item is completed, it is determined that the FCMS test data has been received, thereby quantitative RF based on the actual FCMS data. It is possible to measure the reception sensitivity, and it is possible to set the reception sensitivity more quickly and accurately.

Description

A device, method, and recording medium for measuring the sensitivity of a high-pass terminal using FCMS.

The present application relates to an apparatus, method, and recording medium for measuring reception sensitivity of a high-pass terminal using FCMS.

Intelligent Transport System (ITS) is a new transport system that improves the mobility, stability, efficiency and transportation environment of transportation by combining the existing transportation system with advanced technologies such as information and communication, electronics, control, and computers. It is for alleviating congestion, reducing traffic accidents, expanding the use of public transportation, and reducing logistics costs.

A research group (ISP / TC204 WG15) was formed in 1992 by the International Standard Organization (ISO), which is an on-board equipment (OBE) and a roadside station installed on the roadside (RSE). ; Road Side Equipment).

The new Dedicated Short Range Communication (DSRC) introduced to provide such an intelligent transportation system service is a vehicle equipped with a roadside base station (OBE) installed on the side of the road, traveling at a high speed within 10 to 100 m. It refers to a system that performs two-way communication using a high-speed wireless packet in the communication area. Through this DSRC method, various ITS services are available, such as automatic toll collection service, roadside search, traffic information collection and provision, and traffic signal transmission. Wireless methods that are being considered as DSRC communication include infrared, beacon, and RF, but Korea is using the RF method and the infrared method. In particular, the RF method is mainly used.

In particular, in the high-pass method of the RF method, it is necessary to accurately measure the quantitative RF reception sensitivity based on actual FCMS data of the high-pass terminal in order to secure a communication area.

Korean Patent Publication No. 2009-0041282 (“A device and method for measuring the reception sensitivity of a mobile communication base station”, published date: April 28, 2009)

According to an embodiment of the present invention, in order to secure a communication area, an apparatus for measuring reception sensitivity of a high-pass terminal using FCMS capable of more quickly and accurately measuring quantitative RF reception sensitivity based on actual FCMS data of a high-pass terminal, Methods and recording media are provided.

According to an embodiment of the present invention, a modulator for modulating FCMS (Frame Control Message Slot) test data and transmitting the modulated FCMS test data at a predetermined cycle according to a predetermined transmission power; A high-pass terminal receiving and demodulating the modulated FCMS test data and counting the number of demodulated FCMS test data; And a controller that calculates a reception rate of the FCMS test data based on the number of the FCMS test data counted for a preset time and the preset period, wherein the controller is configured according to the calculated reception rate of the FCMS data. The reception sensitivity of the high-pass terminal is set, and the FCMS test data is composed of one FCMS data including a preamble item, a payload item, and a CRC item for cyclic redundancy check, into which random data of a predetermined size is input. , If the high-pass terminal is matched with any data input to the preamble item among the demodulated FCMS test data, and the cyclic redundancy check by the CRC item is completed, it is determined that the FCMS test data has been received. A device for measuring the reception sensitivity of a high-pass terminal using FCMS is provided.

According to another embodiment of the present invention, the instrument, the first step of modulating the FCMS (Frame Control Message Slot) test data, and transmits the modulated FCMS test data in a predetermined cycle according to a predetermined transmission power; A second step of receiving and demodulating the modulated FCMS test data and counting the number of demodulated FCMS test data in a high pass terminal; And a controller, calculates a reception rate of the FCMS test data based on the number of the FCMS test data counted for a preset time and the preset period, and receives sensitivity of the high-pass terminal according to the calculated reception rate of the FCMS data. A third step of setting; includes, wherein the third step, the received transmission rate of the instrument when the received rate of the calculated FCMS test data has a value between 80% and 95% of the high-pass terminal Sensitivity, and the FCMS test data is composed of one FCMS data including a preamble item, a payload item, and a CRC item for cyclic redundancy check, into which random data of a predetermined size is input, and the high-pass terminal. In the demodulated FCMS test data, random data input to the preamble item matches, and the CRC item When the cyclic redundancy check is completed, a method for measuring reception sensitivity of a high-pass terminal using FCMS is provided, which is determined to have received the FCMS test data.

According to another embodiment of the present invention, there is provided a computer-readable recording medium on which a program for executing the above-described reception sensitivity measurement method is recorded.

According to an embodiment of the present invention, by setting the transmission power of the instrument to the reception sensitivity of the high-pass terminal based on the FCMS data, quantitative RF reception sensitivity based on the actual FCMS data of the high-pass terminal for securing a communication area is determined. Can be measured.

In addition, according to an embodiment of the present invention, since the reception sensitivity is set based on the reception rate of the actually received FCMS test data without calculating a separate bit error rate (BER), more quickly and accurately setting the reception sensitivity This is possible.

1 is a configuration diagram of a reception sensitivity measuring apparatus of a high-pass terminal using FCMS according to an embodiment of the present invention.
2 is a diagram showing the structure of FCMS test data according to an embodiment of the present invention.
3 is a flowchart for explaining a method for measuring reception sensitivity of a high-pass terminal using FCMS according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited only to the embodiments described below. The shape and size of elements in the drawings may be exaggerated for a more clear description, and elements indicated by the same reference numerals in the drawings are the same elements.

1 is a block diagram of a receiving sensitivity measuring apparatus 100 of a high-pass terminal using a CMS according to an embodiment of the present invention, the receiving sensitivity measuring apparatus 100 includes a measuring instrument 110, a high-pass terminal 120 and a controller It may include (130). Meanwhile, FIG. 2 is a diagram showing the structure of FCMS test data according to an embodiment of the present invention.

Hereinafter, with reference to FIGS. 1 to 2, the reception sensitivity measuring apparatus 100 of a high-pass terminal using FCMS according to an embodiment of the present invention will be described in detail.

First, as shown in FIG. 1, the instrument 110 modulates the frame control message slot (FCMS) test data under the control of the controller 130 and presets the modulated FCMS test data according to the preset transmission power. It can be transmitted periodically. The preset period may be set differently according to the situation of the roadside base station (RSE).

In general, if the measurement period of FCMS data is shortened, quick reception sensitivity can be set, but the number of received FCMS data may be small and accuracy may be deteriorated. You can set the reception sensitivity.

In relation to this, the roadside base station (RSE) transmits FCMS data at a period of approximately 6.5 ㎳, and according to an embodiment of the present invention in consideration of this actual transmission period, the above-described preset period has a value of 4 ㎳ to 10 ㎳. Can have It is needless to say that the above-described preset period may be changed according to the roadside base station (RSE) situation.

The above-described FCMS data is used to provide various information on channel use from a roadside equipment (RSE) to a vehicle terminal (On Board Equipment, OBE), and is the frontmost part of a DSRC (Dadicated Short Range Communication) frame. It is located only once, and is used exclusively for downlink, that is, communication from the roadside station to the vehicle terminal.

Meanwhile, the FCMS test data 200 according to an embodiment of the present invention has a structure as shown in FIG. 2.

That is, as shown in FIG. 2, the FCMS test data 200 includes preamble items (PR, 201), payload items 202, and CRC items for cyclic redundancy check, in which arbitrary data of a predetermined size is input ( CRC, 203), and the length (unit: octets) of each item is shown in the lower part of FIG. 2.

Among them, the preamble items (PR, 201) and CRC items 203 each have a length of 2 octets (16 bits), and the payload items 202 are UW1 (Unique Word), SIG (Transmission Channel Control Field), and the like. It can contain multiple items.

According to an embodiment of the present invention, the preamble item PR, 201 may be input with arbitrary data having a predetermined size, for example, 2 octets (16 bits), and the high-pass terminal 120 may then demodulate the FCMS. If the random data input to the preamble items (PR, 201) among the test data match, and the cyclic redundancy check by the CRC item 203 is completed, it is determined that the FCMS test data has been received and the number can be counted. .

In addition, according to an embodiment of the present invention, instead of the above-described detailed items, simple 4-bit arbitrary data, such as 0000, 1111, 0101, 0011, may be input to the payload item 202. 202) has the advantage of being able to test in various cases by entering and transmitting arbitrary data.

The high-pass terminal 120 may receive and demodulate the modulated FCMS test data, and count the number of demodulated FCMS test data.

Specifically, the high-pass terminal receives the FCMS test data when the random data input to the preamble items (PR, 201) among the demodulated FCMS test data matches and the cyclic redundancy check by the CRC item 203 is completed. You can count the number by judging it as one. The counted number of FCMS data may be transmitted to the controller 130.

Finally, the controller 130 may calculate the reception rate of the FCMS test data according to Equation 1 below based on the number of FCMS test data counted for a preset time and a preset period.

[Equation 1]

R = (F_R / F_N) × 100

Here, R is the reception rate of the FCMS test data, F_R is the number of FCMS test data counted during the preset time, F_N is the number of FCMS test data to be received during the preset time, and F_N is the value obtained by dividing the preset time by a preset cycle. have.

In addition, according to an embodiment of the present invention, the controller 130 increases the preset transmission power of the instrument when the received rate of the calculated FCMS test data is less than a preset value, and the received rate of the calculated FCMS test data is set to a preset value. If exceeded, it may be configured to lower the preset transmission power of the instrument.

In addition, according to another embodiment of the present invention, the controller 130 increases the reception sensitivity of the high-pass terminal 120 itself when the received rate of the calculated FCMS test data is less than a preset value, and the received rate of the calculated FCMS test data If it exceeds a preset value, it may be configured to lower the reception sensitivity of the high-pass terminal 120 itself. This case may be applied when the high-pass terminal 120 itself includes a reception sensitivity calibration function.

The above-described controller 130 may be embodied as a personal computer or notebook equipped with a measurement program.

According to an embodiment of the present invention, the controller 130 receives the transmission power of the instrument 110 when the reception rate of the calculated FCMS test data has a value between 80% and 95% of the high-pass terminal 120 Sensitivity can be set.

In particular, according to one embodiment of the present invention, the reception rate (value between 80% and 95%) of the above-described FCMS test data is the minimum FCMS data to be received for charging success within the communication area of the high-pass terminal 120. It may be determined in consideration of the number and length of the communication area, the speed of the vehicle passing through the communication area, and the transmission period of the FCMS data transmitted from the roadside base station.

According to the Korea Expressway Corporation, the length of the communication base area of the roadside station is approximately 13 meters, the maximum speed of the vehicle passing through the communication area is approximately 160 km / h, the recommended speed is approximately 30 km / h, and for charging success within the communication area The minimum number of FCMS data to be received is 38, and the transmission period of FCMS data transmitted from the roadside base station is approximately 6.5 ms.

In view of the above, theoretically, the number of FCMS data that can be received in the communication area may be 45 according to the communication area / (movement distance per second × FCMS transmission cycle).

Accordingly, if the minimum number of FCMS data (38) to be received for billing success in the communication area and theoretically the number of FCMS data (45) that can be received in the communication area are expressed as a percentage, it is approximately 85%. In consideration of this, the reception rate of FCMS test data according to an embodiment of the present invention may be set to a value between 80% and 95%.

As described above, according to an embodiment of the present invention, the reception rate of the FCMS test data is communicated with information on the real road, that is, the minimum number of FCMS data to be received for charging success within the communication area of the high-pass terminal 120. By setting in consideration of the length of the area, the speed of the vehicle passing through the communication area, and the transmission period of the FCMS data transmitted from the roadside base station, there is an advantage that more accurate reception sensitivity can be set.

On the other hand, the above-described measuring instrument 110 and the high-pass terminal 120 may be connected through an RF cable, between the measuring instrument 110 and the controller 130 and between the measuring instrument 110 and the high-pass terminal, for example, USB and It may be connected through the same serial communication or local area network (LAN).

As described above, according to one embodiment of the present invention, the transmission power of the instrument is set to the reception sensitivity of the high-pass terminal based on the FCMS data, thereby quantitatively based on the actual FCMS data of the high-pass terminal for securing a communication area. The RF reception sensitivity can be measured.

In addition, according to an embodiment of the present invention, since the reception sensitivity is set based on the reception rate of the actually received FCMS test data without calculating a separate bit error rate (BER), more quickly and accurately setting the reception sensitivity This is possible.

Meanwhile, FIG. 3 is a flowchart for explaining a method for measuring reception sensitivity of a high-pass terminal using FCMS according to an embodiment of the present invention.

Hereinafter, a method for measuring reception sensitivity of a high-pass terminal using FCMS according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. However, for the sake of simplicity of the invention, the description of the content previously described in FIGS. 1 to 2 and the overlapped information will be omitted.

As shown in FIG. 3, the instrument 110 modulates the FCMS (Frame Control Message Slot) test data under the control of the controller 130 and transmits the modulated FCMS test data at a predetermined cycle according to a preset transmission power. It can be (S301). The preset period may be set differently according to the situation of the roadside base station (RSE).

Next, the high-pass terminal 120 may receive and demodulate the modulated FCMS test data, and count the number of demodulated FCMS test data (S302).

Specifically, the high-pass terminal 120, if the random data input to the preamble items (PR, 201) of the demodulated FCMS test data matches, and the cyclic redundancy check by the CRC item 203 is completed, the FCMS test The number can be counted by determining that the data has been received. The counted number of FCMS data may be transmitted to the controller 130.

Finally, the controller 130 may calculate the reception rate of the FCMS test data according to Equation 1 described above based on the number of FCMS test data counted for a preset time and a preset period, and then the calculated FCMS data The reception sensitivity of the high-pass terminal 120 may be set according to the reception rate of (S203).

Specifically, the controller 130 sets the reception sensitivity of the high-pass terminal according to the received rate of the calculated FCMS data, but the transmission power of the instrument when the received rate of the calculated FCMS test data has a value between 80% and 95% Can be set as the reception sensitivity of the high-pass terminal.

To this end, according to an embodiment of the present invention, the controller 130 increases the preset transmission power of the instrument when the received rate of the calculated FCMS test data is less than a preset value, and the received rate of the calculated FCMS test data is a preset value. If it exceeds, it may be configured to lower the preset transmission power of the instrument.

Or, according to another embodiment of the present invention, the controller 130 increases the reception sensitivity of the high-pass terminal 120 itself when the received rate of the calculated FCMS test data is less than a preset value, and the received rate of the calculated FCMS test data If it exceeds a preset value, it may be configured to lower the reception sensitivity of the high-pass terminal 120 itself. This case can be applied to the case where the high-pass terminal 120 itself includes a reception sensitivity calibration function.

As described above, according to one embodiment of the present invention, the transmission power of the instrument is set to the reception sensitivity of the high-pass terminal based on the FCMS data, thereby quantitatively based on the actual FCMS data of the high-pass terminal for securing a communication area. The RF reception sensitivity can be measured.

In addition, according to an embodiment of the present invention, since the reception sensitivity is set based on the reception rate of the actually received FCMS test data without calculating a separate bit error rate (BER), more quickly and accurately setting the reception sensitivity This is possible.

The method for measuring the reception sensitivity of the high-pass terminal using the FCMS according to the embodiment of the present invention described above may be manufactured as a program to be executed on a computer and stored in a computer-readable recording medium. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, optical data storage devices, and the like. In addition, the computer-readable recording medium can be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion. And functional programs, codes, and code segments for implementing the above method can be easily inferred by programmers in the technical field to which the present invention pertains.

The present invention is not limited by the above-described embodiment and the accompanying drawings. It is intended to limit the scope of rights by the appended claims, and that various forms of substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention as set forth in the claims to those skilled in the art. It will be self-evident.

100: receiving sensitivity measuring device
110: measuring instrument
120: high pass terminal
130: controller

Claims (9)

An instrument for modulating FCMS (Frame Control Message Slot) test data and transmitting the modulated FCMS test data at a predetermined cycle according to a predetermined transmission power;
A high-pass terminal receiving and demodulating the modulated FCMS test data and counting the number of demodulated FCMS test data; And
It includes a controller for calculating the reception rate of the FCMS test data based on the number of the FCMS test data counted for a predetermined time and the predetermined period,
The controller sets the reception sensitivity of the high-pass terminal according to the calculated reception rate of the FCMS data,
The FCMS test data is composed of one FCMS data including a preamble item, a payload item, and a CRC item for cyclic redundancy check, into which random data of a predetermined size is input,
The high-pass terminal determines that the FCMS test data is received when the random data input to the preamble item among the demodulated FCMS test data matches and the cyclic redundancy check by the CRC item is completed. A device for measuring the reception sensitivity of a high-pass terminal using a.
According to claim 1,
The controller,
A device for measuring the reception sensitivity of a high-pass terminal using FCMS, which sets the transmission power of the instrument as the reception sensitivity of the high-pass terminal when the calculated reception rate of the FCMS test data has a value between 80% and 95%.
delete According to claim 1,
The reception rate of the FCMS test data,
The following equation:
R = (F_R / F_N) Х 100
It is calculated according to, where R is the reception rate of the FCMS test data, F_R is the number of FCMS test data counted during the preset time, F_N is a high pass using FCMS, which is the number of FCMS test data to be received during the preset time. Device for measuring the reception sensitivity of a terminal.
According to claim 1,
The controller,
If the received rate of the calculated FCMS test data is less than the preset value, the preset transmit power of the instrument is increased,
When the reception rate of the calculated FCMS test data exceeds the preset value, the reception sensitivity measuring apparatus of the high-pass terminal configured to lower the preset transmission power of the instrument.
According to claim 1,
The controller,
If the received rate of the calculated FCMS test data is less than the preset value, the reception sensitivity of the high-pass terminal itself is increased,
When the reception rate of the calculated FCMS test data exceeds the preset value, the reception sensitivity measuring apparatus of the high-pass terminal configured to lower the reception sensitivity of the high-pass terminal itself.
According to claim 1,
The reception rate of the FCMS test data,
The minimum number of FCMS test data to be received for charging success within the communication area of the high-pass terminal, the length of the communication area, the speed of the vehicle passing through the communication area and the transmission of the FCMS test data transmitted from the roadside base station A device for measuring reception sensitivity of a high-pass terminal determined in consideration of a period.
A first step of modulating the FCMS (Frame Control Message Slot) test data and transmitting the modulated FCMS test data at a predetermined cycle according to a predetermined transmission power;
A second step of receiving and demodulating the modulated FCMS test data and counting the number of demodulated FCMS test data in a high pass terminal; And
The controller calculates a reception rate of the FCMS test data based on the number of the FCMS test data counted for a preset time and the preset period, and increases the reception sensitivity of the high-pass terminal according to the calculated reception rate of the FCMS data. The third step of setting; includes,
In the third step, the transmission power of the instrument when the received rate of the calculated FCMS test data has a value between 80% and 95% is set as the reception sensitivity of the high-pass terminal,
The FCMS test data is composed of one FCMS data including a preamble item, a payload item, and a CRC item for cyclic redundancy check, into which random data of a predetermined size is input,
The high-pass terminal determines that the FCMS test data is received when the random data input to the preamble item among the demodulated FCMS test data matches and the cyclic redundancy check by the CRC item is completed. How to measure the reception sensitivity of a high-pass terminal using a.
A computer-readable recording medium recording a program for executing the method of claim 8.

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