JPH0614118B2 - Mobile object position zone detection device - Google Patents

Description

Description: TECHNICAL FIELD [0001] The present invention is connected to a fixed central office side of a wireless communication circuit using a small electric power or a weak electric wave whose propagation medium is space, or a wireless communication line using a leaky coaxial cable. Further, the present invention relates to a mobile body position zone detection device that receives a radio wave transmitted from a mobile child device of a communication partner with a distributed receiver and detects a position where the mobile child device is present.

(Prior art and its problems) When a plurality of mobile small devices and a fixed station communicate with each other in a relatively narrow range by small power, weak radio waves, leaky coaxial cable, etc., the fixed station is used to expand the service area. There is used a system in which a plurality of distributed receivers connected by wire or the like are distributed and arranged, and the transmission radio waves of a plurality of mobile slave units are received by each distributed receiver and transmitted to a central fixed station.

In such a system, it is necessary to detect the current position of the mobile unit, and the distributed receiver side receiving the radio wave from the mobile unit determines whether the mobile unit is within the service area of the distributed receiver. Had made a unique decision. When using low power or weak radio waves, an omnidirectional antenna is usually used as the antenna of the distributed receiver that receives radio waves from mobile units, and its service area is centered on the antenna and is almost circular on a horizontal plane. Area. Conventionally, in order to make an alternative judgment as to whether or not the mobile station is located within this substantially circular service area, the reception input reference level of the preset distributed receiver and the mobile station from the mobile station have been preset. For example, the circuit configuration is such that a squelch operation is performed so that the received output is obtained when the received level exceeds the reference level by comparing the received level.

However, in recent years, low-power radios have come to be used for so-called premises radios such as telecontrol telemeter systems for business use and homes, premises paging systems, power transmission data transmission systems, communication systems for communication, etc. It has become necessary to detect the existing position in detail and to provide an accurate communication service from a fixed station to a mobile unit corresponding to a fine position. However, in the conventional receiving method, it is only possible to determine whether or not the mobile station is within the reception service area of the distributed receiver. However, there is a drawback that it is not possible to detect whether it is in or away, and accurate communication contact or emergency communication service corresponding to a fine position could not be performed.

(Object of the invention) In order to make up for such drawbacks, an object of the present invention is to provide a plurality of zones within the reception service area of a distributed receiver, and to detect in which zone a mobile unit exists. It is an object of the present invention to provide a mobile body position zone detection device capable of providing a more accurate communication service to a child device.

(Structure and Operation of the Invention) The moving body position zone detecting apparatus according to the present invention is the first to n-th (n ≧ 1) branching the output of the high frequency amplifier connected to one antenna or one leaky coaxial cable. , Integer) output is input to one of the input terminals via an attenuator having a predetermined attenuation amount (n-1) α, and the first to n-th comparators. The mobile terminal includes a reference level generator that generates a reference level that is input to the other input terminal of the comparator, and a determination circuit that is connected to the output side of the first to nth comparators. When a radio wave is received, the service area of the one antenna or the leaky coaxial cable is sequentially divided from near the one antenna or the leaky coaxial cable to a distance corresponding to a desired division of the reception level of the radio wave. Was (n + 1) It is characterized in that the zone division signals said mover unit corresponds to either position In any of the zones is configured to be output from the decision circuit.

The above-mentioned determination circuit is connected so as to obtain an output when the input level input to one input terminal of each of the first to nth comparators is higher than the reference level.
AND gate and the input levels of the first to mth (m <n) comparators are higher than the reference level and the input levels of the (m + 1) th to nth comparators are lower than the reference level. The second to nth AND gates are connected so as to obtain an output respectively, and are connected so as to obtain an output when the input levels of the first to nth comparators are all smaller than the reference level. The (n +
1) AND gate.

The present invention will be described in detail below with reference to the drawings.

FIG. 1 shows the first embodiment of the present invention, in which the service area is divided into two zones. Fig. 1 (1)
FIG. 4 is a circuit configuration example diagram of a zone detection circuit unit 7 that is branched and connected to an antenna 4 of the distributed receiver 2. The zone detection circuit unit 7 may be mounted inside the distributed receiver 2 or may be housed in an independent case as an additional device. Fig. 1 (2)
FIG. 3 is a plan view of reception service areas 5 and 6 having a substantially circular shape centered on the omnidirectional antenna 4, and FIG. 1 (3) shows an antenna reception input level vs. distance characteristic which is a substantially conical shape around the antenna 4. FIG. The vertical axis represents the antenna input level, and the horizontal axis represents the distance from the center O point to the left and right from the antenna. In the figure, assuming that the maximum transmission output of the mobile unit and the propagation state of the spatial radio wave are both constant, the reception input level of the antenna 4 is the center of the horizontal axis indicating the distance of the mobile unit in Fig. 1 (3). It decreases as it moves away from the position of the antenna 4 at the point O, and exhibits a conical input level characteristic as shown by the ridgeline 1. This input level distance characteristic 1 is
It indicates the upper limit of the reception level from the mobile device.

Now, the reception antenna 4 receives the radio waves sent from the mobile device.
The reception input received at is passed through the high frequency amplifier 8 and the rectifier 9
At the same time as being input to the A terminal of the comparator 13 rectified by, the output branched from the high frequency amplifier 8 is attenuated by αdB by the attenuator 10 and input to the B terminal of the comparator 14 via the rectifier 11. The reference level E ₀ is input from the reference level generator 12 to the other input terminal C of each of the comparators 13 and 14.

The reference level E ₀ is the zone detection circuit 7 depending on the line design.
The value is set to a value close to the maximum sensitivity of, and the service area 6 is specified, and the inside and outside (outside zone Z ₀ ) of the service area 6 is clarified. In addition, the attenuation amount α of the attenuator 10 is the first zone Z in which the inside of the service area 6 is shown as two zones, that is, a substantially circular zone 5 close to the antenna.
_The value is set so as to be divided into ₁ and the second doughnut-shaped zone Z _{2 on} the outside thereof. That is, the position O of the antenna
The input level of the conical input level distance characteristic 3 is set to a value approximately midway between the maximum input level at the point and the above-mentioned reference level E ₀ , and a value lower by α dB than the maximum input level at the point O is the reference. The first zone Z ₁ that exceeds the level E ₀ can be identified.

Since the reference level E ₀ and the attenuation amount α are set as described above, the level input to the A terminal of the comparator 13 is the level corresponding to the maximum input level characteristic 1, and the B terminal of the comparator 14 The level input to is the level corresponding to the input level characteristic 3 that is αdB attenuated from the maximum input level characteristic 1. These comparators 13 and 14 compare the levels input to the respective input terminals, and when A terminal level> E ₀ , S ₁ terminal, A terminal level <S ₀ terminal, S ₂ terminal, B terminal level> When E _0, an output appears at the S ₃ terminal, and when B terminal level <E ₀ , an output appears at the S ₄ terminal, which are led to the AND gates 16, 17 and 18 of the gate circuit section 15. The AND gate 16 receives the outputs from the S ₁ and S ₃ terminals, the AND gate 17 receives the outputs from the S ₁ terminal and the S ₄ terminal, and the AND gate 18 receives the outputs from the S ₂ terminal and the S ₄ terminal. Added respectively.

In the embodiment having such a circuit configuration, when the antenna ₁ receives the f ₁ radio wave from the mobile handset M ₁ located in the first zone Z ₁ , the reception level a shown in the reception input characteristic 1 is input. Is rectified by the rectifier 9 through the high frequency amplifier 8 and applied to the A terminal of the comparator 13 and exceeds the reference level E ₀ , so that an output appears at the S ₁ terminal. On the other hand, the output branched from the high-frequency amplifier 8 is attenuated by α dB in the attenuator 10 to a level corresponding to the level a ′ shown in the reception input characteristic 3, and is input to the B terminal of the comparator 14 via the rectifier 11. Since the reference level E ₀ is exceeded, an output appears at the S ₃ terminal. S
_The AND gate 16 is opened by the outputs from the ₁ terminal and the S ₃ terminal, and an output signal indicating the first zone Z ₁ is obtained.

Next, f from the mobile child device M ₂ located in the second zone Z _{2
When one} radio wave is received by the antenna 4, the input of the reception level b shown in the reception input characteristic 1 is branched via the high frequency amplifier 8 and is attenuated by αdB by the rectifier 9 and the attenuator 10.
Be led to. The level introduced to the rectifier 11 corresponds to the level b'shown on the reception input characteristic 3. In this case, the level b> E ₀ and the level b ′ <E ₀ are satisfied, and the outputs from the S ₁ and S ₄ terminals of the comparators 13 and 14 open the AND gate 17 to provide an output signal indicating the second zone Z _2. .

Similarly, the reception levels d and d'of radio waves from the mobile child device M ₃ located in the zone Z ₀ outside the zone are level d <E ₀ and level d '
In the relationship of <E _0, the AND gate 18 is opened by the outputs from the S ₂ and S ₄ terminals of the comparators 13 and 14, and the output signal indicates Z ₀ outside the zone.

With the above operation, the outputs of the AND gates 16, 17, and 18 can be specified as the Z ₁ zone signal and the Z ₂ zone signal Z ₀ zone signal, respectively, and these are processed by the known circuit such as the display circuit and the control circuit. Can be utilized.

According to the above-described first embodiment of the present invention, the reception service area is divided into two zones and the current position of the mobile terminal is detected, so that the mobile terminal is twice as fine as the conventional one. It is possible to perform accurate communication corresponding to the position.

Next, as a second embodiment of the present invention, FIG. 2 shows a circuit configuration example of the zone detection circuit section 36 when the reception service area of the distributed receiver is divided into three zones.

In FIG. 2, the reception input from the reception antenna 33 is amplified by the high-frequency amplifier 37 of the zone detection circuit section 36, and then 3
The first one is directly rectified by the rectifier 38 and the comparator 44.
Input to the A terminal of. This signal becomes a signal that specifies the first zone Z ₁ that indicates the section closest to the antenna 33. Next, the second branch output of the high-frequency amplifier 37 is attenuated by αdB by the attenuator 39 to become a signal for identifying the second zone Z ₂ outside the first zone Z ₁ and the rectifier 40 and then the comparator 45. Input to B terminal. Next, the third branch output of the high frequency amplifier 37 is attenuated by (2 × α) dB by the attenuator 41,
The signal becomes a signal for specifying the third zone Z ₃ outside the second zone Z ₂ and is input to the D terminal of the comparator 46 via the rectifier 42.
The outside of the third zone Z _{3 is} the outside zone Z ₀ . In this way, the attenuation amount α dB preset in the attenuator 39 and the attenuator 41 is set.
The service area can be divided into three zones by and (2 × α) dB. The reference level E ₀ for zone division is input from the reference level generator 43 to the other C terminals of the respective comparators 44, 45, 46, and the A terminal, B terminal, D
It is compared with the input of the terminal respectively, and when it is larger than the reference input level E ₀ , the output appears at the terminals T ₁ , T ₃ , T ₅ and when it is smaller than the reference input level E ₀ , the output at the terminals T ₂ , T ₄ , T ₆ Is obtained. The AND gate circuit section 47 has an AND gate 48 connected to the output terminals of the comparators T ₁ , T ₃ , and T ₅ .
It operates only when there is a signal from all three, and operates in the first zone Z ₁
An output is obtained that identifies The AND gate 49 is connected to the output terminals of the comparators T ₁ , T ₃ and T ₆ and is similarly connected to the second zone Z.
An output specifying ₂ is obtained. The AND gate 50 is connected to the outputs of the terminals T ₁ , T ₄ and T ₆ of the comparator, and similarly an output for specifying the third zone Z ₃ is obtained. The AND gate 51 is connected to the outputs of the terminals T ₂ , T ₄ and T ₆ of the comparator, and similarly an output for identifying the outside zone Z ₀ is obtained.

By the above operation, the outputs of the AND gates 48, 49, 50 and 51 are respectively Z ₁ zone, Z ₂ zone, Z ₃ zone, Z
_It is specified as each signal in the ₀ zone, and these signals can be processed by a circuit such as a display circuit and a control circuit to be used for a desired purpose.

According to the second embodiment described above, the current position of the mobile handset can be detected with three times the fineness of the conventional one by dividing it into three zones of the reception service area, and more accurate communication is performed. be able to.

Furthermore, the number of attenuators, rectifiers, comparators, and AND gates is increased, and the attenuation of the attenuators is αdB, (2 × α) dB, (3 × α) dB ……
If (n × α) dB is set, the reception service area can be further divided into smaller areas, and more detailed communication services can be provided.

The attenuator can be easily implemented using, for example, a conventional fixed resistor, and the resistor value can be adjusted to the site terrain to set the zone division. Also, the attenuation α
Is the zone detection side because the transmission output of the mobile unit fluctuates due to the voltage drop of the battery and the expensive body of the string antenna, and the spatial radio waves fluctuate under the influence of the metal structures around the mobile unit. It is set to a value larger than the fluctuation width value of the reception input of. Further, the number and size of zones to be divided can be set arbitrarily according to the situation of the installation place.

The mobile body position zone detection apparatus shown in the first and second embodiments of the present invention described above is used by being added to a plurality of distributed receivers in a low power indoor radio system, but one distributed receiver. position sensing, communication coverage is substantially circular area with a radius of about 30M～200m, and each campus buildings site area of the plant factory 100,000m ² ~300,000m ^2, building, for each room such as a hospital In the case of distributed arrangement, the service areas of adjacent distributed receivers are often arranged so as to partially overlap each other so that a dead zone of communication service does not occur, and more precise position detection can be performed. FIG. 3 is a block diagram for explaining a case where the zone detecting devices of the first embodiment shown in FIG. 1 are arranged at points F and G adjacent to each other. In the figure, the zone detection device 25 at the F point sends the position detection information divided into the first zone FZ ₁ , the second zone FZ ₂ and the outside zone FZ ₀ to the central fixed station, and the zone detection device at the G point.
26 sends the position detection information classified into the first zone GZ ₁ , the second zone GZ ₂ , and the outside zone GZ ₀ to the central fixed station.
The central fixed station can distinguish the zones at the respective points by the position information thus sent, and further can distinguish where the mobile slaves M ₅ , M ₆ , and M ₇ are located. . That is, in the case of M ₅ , FZ ₂ signal and G
Z ₀ signal, FZ ₂ signal and GZ ₂ signal in case of M ₆ , M ₇
In the case of, the position of the mobile unit can be specified when the FZ ₀ signal and the GZ ₂ signal are simultaneously received. FIG. 3 shows the case of two adjacent zone detection devices, and the case where the service area is divided into two zones in the first embodiment, but in practice, a large number of zone detection devices are distributed and arranged. Since the number of zone divisions can be further increased, a synergistic effect of position detection can be obtained in the entire system, and the safety of on-site workers and the on-site security such as a gas generation alarm can be achieved more reliably.

FIGS. 4 (1) and 4 (2) are circuit block diagrams of zone detection circuit units 27 and 28 which are modifications of the embodiment of the present invention shown in FIGS. 1 and 2. FIG. 4 (1) shows an attenuator 10 for the output branched from the single antenna 4 and the high frequency amplifier 8 in FIG.
Instead of being attenuated by α dB, antennas 19 whose ground height is lower than that of antenna 4 are provided close to each other so that the input level of antenna 4 is α dB lower, and that antenna 19 is a high frequency amplifier 20 equivalent to high frequency amplifier 8. The circuit is configured so as to be input to the other circuit, and all other parts have exactly the same configuration as the circuit of FIG. 1 (1). Thus the work zone division signal of the input level range characteristic in the same manner receive signals having a difference in αdB is input to both the high-frequency amplifier 8 and _{20 Z 1, Z 2, Z} 0 is obtained.

Further, FIG. 4 (2) shows the zone divisions Z ₁ , Z ₂ , Z _{3 of} FIG.
In place of the attenuators 39 and 41 for providing the antennas, high-frequency amplifiers 31 and 32 equivalent to the high-frequency amplifier 37 are provided, and antennas 34 and 35 having height differences such that the input level is lower than the antenna 33 by α dB and 2α dB, respectively. Is the zone detection circuit section 28, and all other portions have the same circuit configuration as in the case of FIG. Therefore, the operation is
Similar to the case of FIG. 1A, it has one more zone division function.

FIG. 5 shows a third embodiment according to the present invention. This third
In this embodiment, a leaky coaxial cable 21 is provided instead of the antenna 4 shown in FIG. 1, and 22 is a terminating resistance thereof. It is well known that the electromagnetic field leaking from the leaky coaxial cable 21 is electromagnetically coupled to the mobile unit to perform communication.
The input level-distance characteristic of this leaky coaxial cable 21 is
As shown in FIG. 5 (3), the leaky coaxial cable has a shape in which a vertical cross section perpendicular to the lengthwise direction is a substantially isosceles triangle, and the zone detection circuit section 7 is formed as shown in FIG. By providing a circuit that is exactly the same as that of the above embodiment, it is possible to divide the strip-shaped service area along the leaky coaxial cable 21 into two zones Z ₁ and Z ₂ by the reference level E ₀ . Z ₀ is outside the zone. Therefore, the operation in this case is exactly the same as that of the first embodiment shown in FIG. ₁ , and it is possible to obtain the band-shaped signals of the first zone Z ₁ , the second zone Z ₂ and the outside zone Z ₀ .

As a modification of the third embodiment, it is conceivable to provide a plurality of leaky coaxial cables having different intensities of leaking electromagnetic fields close to each other as in the case of the plurality of antennas shown in FIG.

The length of the leaky coaxial cable in this third embodiment is about
The service area is 200m wide and the band-shaped service area is about 30m wide, which is especially effective when installing a low-power position detection system indoors where it is difficult to secure a service area by radio waves. In the leaky coaxial cable in this case, it is apparent that the communication system is further expanded by providing the relay amplifier.

(Effects of the Invention) As described in detail above, by adding the mobile unit position zone detection device of the present invention to a distributed receiver that communicates with a plurality of mobile slave units by low power radio, The reception service area is further divided into a plurality of zones, and the current position of the moving body can be accurately detected. Therefore, it is possible to more accurately detect the current position of the on-site worker in the on-site wireless system, and also to accurately detect the danger occurrence point such as the occurrence of a gas abnormality, improving the reliability of the on-site security system. The practical effect is great.

In addition, inside buildings such as skyscrapers, hospitals, nursing homes,
The reliability of an indoor security system is improved by using a leaky coaxial cable as a security system for indoors where radio wave propagation is poor such as in an underground shopping street.

Further, it is obvious that the economical efficiency of the apparatus is excellent in that one antenna or leaky coaxial cable, which is one of the features of the present invention, can be divided into an arbitrary number of zones.

[Brief description of drawings]

FIG. 1 is a block diagram of a circuit of a first embodiment according to the present invention, a plan view of an antenna service area and a sectional view of an input level distance characteristic, and FIG. 2 is a circuit block diagram showing a second embodiment according to the present invention. FIG. 3 is a plan view of the antenna service area, FIG. 3 is a block diagram when the zone detection device of the present invention is adjacently arranged, FIG. 4 is a circuit block diagram showing a modification of FIG. 1, and FIG. It is a circuit block diagram of a 3rd example, a service area top view, and a sectional view of an input level distance characteristic. 1, 3 ... Input level distance characteristics, 2 ... Distributed receiver,
4,19,33,34,35 …… Antenna, 5,6,23,24 ……
Zone division line, 7, 27, 28, 36 ... Zone detection circuit section,
8, 20, 31, 32, 37 ... High-frequency amplifier, 9, 11, 40, 42
...... Rectifier, 10, 39, 41 …… Attenuator, 12, 43 …… E ₀ generator, 13, 14, 44, 45, 46 …… Comparator, 15, 47 …… AN
D-gate, 16, 17, 18, 48, 49, 50, 51 …… AND gate, 21 …… Leaky coaxial cable, 22 …… Terminal resistor, 2
5,26 …… Zone detection device.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Yoichi Kawabe 1-25, Ogawa Higashi, Akigawa-shi, Tokyo 6 Kokusai Electric Engineering Co., Ltd. (72) Inventor Atsushi Mizukami 2-1-1, Shinmeidai, Hamura-cho, Nishitama-gun, Tokyo Kokusai Electric Co., Ltd. Hamura Factory

Claims (4)

[Claims] 1. A receiver having an approximately circular receiving service area connecting a point farthest from the antenna with the maximum receiving sensitivity of the receiver centering on the receiving antenna of the receiver receives radio waves from a mobile unit. Then, in order to detect whether the current position of the mobile unit is located outside the reception service area or in two zones that are divided into concentric circles inside the reception service area, the reception signal is connected to the reception antenna. A high-frequency amplifier that amplifies and outputs, a reference level generator that generates and outputs a reference signal of a level equal to the received signal level from the mobile unit on the circumference of the circular reception service area, and is input to one input terminal. And comparing the rectified voltage of the received signal from the high-frequency amplifier with the voltage of the reference signal input to the other input terminal, and when the rectified voltage of the received signal is high, the first output terminal And a signal indicating that the rectified voltage of the received signal is high, and a signal indicating that the rectified voltage of the received signal is low is output from the second output terminal when the rectified voltage of the received signal is low. And an attenuator that outputs the branched output of the high-frequency amplifier by giving an attenuation amount α that is approximately a half of the difference between the highest receiving sensitivity level and the reference signal level at the installation point of the receiving antenna, The rectified voltage of the α-attenuated received signal from the attenuator input to one input terminal is compared with the voltage of the reference signal input to the other input terminal, and the rectified voltage of the α-attenuated received signal is compared. When is high, a signal indicating that the rectified voltage of the α-decayed received signal is high is output from the first output terminal,
a second comparator that outputs a signal indicating that the rectified voltage of the α-decayed received signal is low from the second output terminal when the rectified voltage of the α-decayed received signal is low; and the first comparator. Of the first reception terminal of the second comparator and the first output terminal of the second comparator, the mobile unit has approximately ½ the diameter of the circular reception service area.
A first AND gate that outputs a signal indicating that it is located in a zone inside the circumference of the diameter of the first comparator, a first output terminal of the first comparator and a second comparator of the second comparator. When there is an output from the output terminal, the mobile unit is located in a zone between the circumference of the circular receiving service area and the circumference having a diameter of approximately 1/2 the diameter of the circular receiving service area. And a second AND gate for outputting a signal indicating that the mobile unit is output from the second output terminal of the first comparator and from the second output terminal of the second comparator. And a third AND gate that outputs a signal indicating that the vehicle is located outside the circular reception service area. 2. A receiver having a strip-shaped receiving service area which shows the maximum receiving sensitivity of the receiver centering on the leaky coaxial cable for the receiving antenna of the receiver and which connects the points farthest from the leaky coaxial cable. When a radio wave is received from a moving mobile device, the current position of the mobile device is located in either of two zones, which are divided by the distance from the leaky coaxial cable outside or inside the receiving service area. In order to detect whether or not, a high-frequency amplifier connected to the leaky coaxial cable for amplifying and outputting the received signal, and a reference signal having a level equal to the received signal level from the mobile unit on the outer edge of the band-shaped receiving service area. A reference level generator for generating and outputting the rectified voltage of the received signal from the high frequency amplifier input to one input terminal and the other input terminal. A signal indicating that the rectified voltage of the received signal is high is output from the first output terminal when the rectified voltage of the received signal is high, and a second value when the rectified voltage of the received signal is low. A first comparator that outputs a signal indicating that the rectified voltage of the received signal is low from an output terminal of the high frequency amplifier, and a branch output of the high frequency amplifier, the highest receiving sensitivity level at the installation position of the leaky coaxial cable, and the reference. An attenuator that outputs by giving an attenuation amount α that is approximately a half of the difference from the signal level, a rectified voltage of the α-attenuated received signal from the attenuator input to one input terminal, and the other A signal indicating that the rectified voltage of the α-attenuated received signal is high from the first output terminal when the rectified voltage of the α-attenuated received signal is high by comparing with the voltage of the reference signal input to the input terminal. And output
a second comparator that outputs a signal indicating that the rectified voltage of the α-decayed received signal is low from the second output terminal when the rectified voltage of the α-decayed received signal is low; and the first comparator. From the first output terminal of the second comparator and the first output terminal of the second comparator, the mobile unit is separated from the dividing line having a width of approximately ½ of the width of the strip-shaped reception service area. There is an output from a first AND gate that outputs a signal indicating that it is located in the inner zone, an output from the first output terminal of the first comparator, and an output from the second output terminal of the second comparator. A second AND gate that outputs a signal indicating that the mobile unit is located in a zone between the outer edge of the strip-shaped reception service area and the partition line; and a second AND gate of the first comparator. From the second output terminal of the second comparator and from the second output terminal of the second comparator And a third AND gate that outputs a signal indicating that the mobile device is located outside the band-shaped reception service area when there is a moving object position zone detection device. 3. A receiver having a substantially circular reception service area connecting a point farthest from the first antenna with the highest reception sensitivity of the receiver centered around the first reception antenna of the receiver. When receiving a radio wave from a mobile device, in order to detect whether the current position of the mobile device is located in two zones concentrically divided outside or inside the reception service area, A first high frequency amplifier connected to one reception antenna for amplifying and outputting a reception signal; and a first high frequency amplifier having a level equal to the reception signal level of the first reception antenna from the mobile unit on the circumference of the circular reception service area. A reference level generator that generates and outputs a reference signal, and the reception level is lowered by a level difference α that is approximately ½ of the difference between the maximum reception sensitivity level of the first reception antenna and the reference signal level. A second antenna, which is installed near the first receiving antenna with its height reduced, and a received signal is amplified with an amplification degree equal to that of the first high-frequency amplifier connected to the second receiving antenna. A second high-frequency amplifier for outputting, a rectified voltage of a received signal input to one input terminal by rectifying the output of the first high-frequency amplifier, and a voltage of the reference signal input to the other input terminal. In comparison, when the rectified voltage of the received signal is high, a signal indicating that the rectified voltage of the received signal is high is output from the first output terminal, and when the rectified voltage of the received signal is low, the received signal is output from the second output terminal. A first comparator that outputs a signal indicating that the rectified voltage is low, and a rectified voltage of the received signal input to one input terminal by rectifying the output of the second high frequency amplifier and the other input terminal Input voltage of the reference signal When the rectified voltage of the received signal is high, a signal indicating that the rectified voltage of the received signal is high is output from the first output terminal, and when the rectified voltage of the received signal is low, the signal is output from the second output terminal. A second comparator that outputs a signal indicating that the received signal has a low rectified voltage, an output from the first output terminal of the first comparator, and an output from the first output terminal of the second comparator When there is, the mobile handset has approximately half the diameter of the circular reception service area.
A first AND gate that outputs a signal indicating that it is located in a zone inside the circumference of the diameter of the first comparator, a first output terminal of the first comparator and a second comparator of the second comparator. When there is an output from the output terminal, the mobile unit is located in a zone between the circumference of the circular receiving service area and the circumference having a diameter of approximately 1/2 the diameter of the circular receiving service area. And a second AND gate for outputting a signal indicating that the mobile unit is output from the second output terminal of the first comparator and from the second output terminal of the second comparator. And a third AND gate that outputs a signal indicating that the vehicle is located outside the circular reception service area. 4. A receiver having a strip-shaped reception service area centered around a first leaky coaxial cable of the receiver and connecting a point farthest from the first leaky coaxial cable with the highest reception sensitivity of the receiver. When receiving a radio wave from the mobile child device, in order to detect whether the current position of the mobile child device is located outside the receiving service area or in one of two zones divided into strips, A first high frequency amplifier connected to a first leaky coaxial cable for amplifying and outputting a received signal; and a received signal level of the first leaky coaxial cable from a mobile terminal on an outer edge of the band-shaped receiving service area. A reference level generator for generating and outputting a level reference signal, and a level difference α that is approximately ½ of a difference between the maximum reception sensitivity level of the first leaky coaxial cable and the reference signal level.
A second leaky coaxial cable which is installed close to the first leaky coaxial cable by lowering the strength of the leaky electromagnetic field so that the reception level becomes low, and is connected to the second leaky coaxial cable. A second high-frequency amplifier that amplifies and outputs a received signal with an amplification degree equal to that of the first high-frequency amplifier; a rectified voltage of the received signal input to one input terminal by rectifying the output of the first high-frequency amplifier and the other The voltage of the reference signal input to the input terminal of the received signal is compared, and when the rectified voltage of the received signal is high, a signal indicating that the rectified voltage of the received signal is high is output from the first output terminal. A first comparator that outputs a signal indicating that the rectified voltage of the received signal is low from the second output terminal when the rectified voltage is low, and rectifies the output of the second high frequency amplifier to one input terminal. Of the received signal that is input The reference voltage input to the other input terminal is compared, and when the rectified voltage of the received signal is high, a signal indicating that the rectified voltage of the received signal is high is output from the first output terminal. A second comparator that outputs a signal indicating that the rectified voltage of the received signal is low when the rectified voltage of the received signal is low, and a first output terminal of the first comparator And when there is an output from the first output terminal of the second comparator, the mobile unit is located in a zone inside a dividing line having a width of approximately 1/2 of the width of the strip-shaped reception service area. And a second AND gate for outputting a signal indicating that the mobile unit is output from the first output terminal of the first comparator and the second output terminal of the second comparator. The zone between the outer edge of the band-shaped reception service area and the division line A second AND gate for outputting a signal indicating that the second comparator is located, a second output terminal of the first comparator and a second output terminal of the second comparator. And a third AND gate that outputs a signal indicating that the mobile child device is located outside the band-shaped reception service area.