JP2012114662A - Wireless device - Google Patents

Abstract

A radio apparatus capable of reducing noise generated in a radio signal due to a clock signal of a radio transmission circuit is provided.
A repeater 30 for a crime prevention system that receives a signal from a terminal device, a radio transmission / reception unit 31 having an antenna 35, and a control based on the content of the signal received by the radio transmission / reception unit 31. And a control unit 34 for performing. The wireless transmission / reception unit 31 includes a first basic processing unit 37b and a second basic processing unit 38b that process a signal received via the antenna 35. The clock frequency of the first basic processing unit 37b and the second basic processing unit 38b is set to a frequency other than a fraction of an integer with respect to the basic frequency and the intermediate frequency of the frequency band of the signal received via the antenna 35.
[Selection] Figure 3

Description

  The present invention relates to a wireless device for receiving a wireless signal.

  In general homes and the like, crime prevention systems that monitor for abnormalities such as the presence of intruders and fires, and notify the abnormality when an abnormality is detected have become widespread. In particular, in recent years, a wireless crime prevention system that transmits a signal wirelessly from a detection sensor, receives the transmitted signal by a receiving device, and performs abnormality notification or the like has been put into practical use.

  FIG. 7 is an explanatory diagram for explaining a configuration of a conventional wireless crime prevention system. As shown in FIG. 7, a wireless crime prevention system 100 includes a wireless opening / closing sensor 101 that detects the open / closed state of a door or window, a wireless fire sensor 102 that detects a fire, and a wireless security sensor that detects a human body. It is configured to include a human sensor 103, a wireless abnormality alarm lamp 104 for informing the outdoors of an abnormality, a repeater 105 that wirelessly relays signals transmitted from these sensors 101 to 103, and a receiving device 106. Yes. The receiving device 106 receives the signals transmitted from the sensors 101 to 103 via the repeater 105 or directly receives the signals, thereby monitoring the presence / absence of the abnormality and detecting the abnormality when detecting the abnormality. A warning signal is transmitted to the lamp 104 wirelessly to notify the abnormality, and if necessary, the abnormality occurrence is transferred to the security company by wire or wirelessly (for example, Patent Document 1 discloses an abnormality detection means. A security system for houses is disclosed).

  In such a wireless crime prevention system 100, since wireless transmission is performed at a short distance of about several meters to several tens of meters, the frequency band for wireless transmission is a 426 MHz band that is a specific low-power security wireless band. It was used. Here, in ARIB STD-30, which is a standard for this specific low-power security radio, carrier sense is not obliged when using radio waves having a frequency of 426.250 MHz or more and 426.8375 MHz or less. Carrier sense refers to sensing the received signal strength of the received power of another radio wave having the same frequency as the carrier frequency in the wireless transmission when performing wireless transmission, and when the received signal strength is equal to or greater than a predetermined threshold. This means that no wireless transmission is performed. Since it has been specified that such carrier sense is not necessary, in the conventional wireless crime prevention system, each of the sensors 101 to 103 performs wireless transmission without performing carrier sense.

Japanese Patent Laid-Open No. 2003-115085

  However, in the conventional wireless crime prevention system 100, only one frequency band such as the 426 MHz band is used as the frequency band for wireless transmission, so the communication speed is as slow as 1,200 bps, for example. It takes time for the wireless signal transmitted from 103 to reach the receiving apparatus 106, and in particular, it takes time to reach the receiving apparatus 106 via the repeater 105.

  In addition, since each sensor 101 to 103 performs wireless transmission without performing carrier sense, when the number of sensors 101 to 103 is increased, the probability that signals collide due to wireless transmission being performed at the same timing. There is a possibility that a signal having a high radio wave intensity does not reach the repeater 105 or the receiving device 106 due to the increase.

  In order to solve such a problem, 1) a carrier sense function is added to each of the sensors 101 to 103, 2) a wireless transmission frequency band of each sensor has a higher communication speed than the 426 MHz band, and It may be possible to change to a frequency band (for example, 950 MHz band) where carrier sense is obligatory. However, in order to change the functions and frequency bands of the sensors 101 to 103 in this way, the existing sensors 101 to 103 with a large number of installations are replaced, or the new sensors 101 to 103 with many types are designed. It needs to be changed and is not realistic.

  Therefore, the inventor of the present application does not perform carrier sense in the 426 MHz band in the wireless transmission from each of the sensors 101 to 103, and on the other hand, the frequency band of the wireless transmission from the repeater 105 to the receiving device 106 We focused on solving the above problems by setting the 950 MHz band to 950 MHz. That is, when the 950 MHz band is used as described above, the communication speed from the repeater 105 to the receiving apparatus 106 can be improved to, for example, 9,600 bps, and wireless transmission from the repeater 105 or the receiving apparatus 106 is possible. Sometimes, by performing carrier sense, a radio signal can surely reach the receiving apparatus 106, and communication reliability can be improved. In particular, in this case, only the functions of the repeater 105 and the receiving device 106 need to be changed. Since the number and types of the repeater 105 and the receiving device 106 are small compared to the sensors 101 to 103, Easy to apply in reality.

  However, when wireless transmission is performed in this manner, a new problem that the possibility of noise occurring in the wireless transmission circuit that performs the wireless transmission increases may arise. That is, depending on the relative relationship between the clock frequency of the radio transmission circuit and the radio transmission frequency band, the clock signal or its harmonic component causes noise in the radio transmission circuit, for example, when there is no radio signal. However, there is a possibility of causing various troubles such as erroneously recognizing that a weak radio signal exists. In particular, when performing wireless transmission in a plurality of frequency bands as described above, it is necessary to use a plurality of wireless transmission circuits in accordance with the frequency bands, which may increase problems caused by the clock signal of the wireless transmission circuit. There is sex.

  The present invention has been made in view of the above, and an object of the present invention is to provide a wireless device that can reduce noise generated in a wireless signal due to a clock signal of a wireless transmission circuit.

  In order to solve the above-described problems and achieve the object, a wireless device according to claim 1 is a wireless device that receives a signal from a terminal device, and includes a wireless transmission / reception unit including an antenna, and the wireless transmission / reception unit A control unit that performs control based on the content of the signal received by the wireless transmission / reception unit, a signal processing unit that processes a signal received via the antenna, and a clock frequency of the signal processing unit Is a frequency other than a fraction of an integer with respect to a fundamental frequency and an intermediate frequency in a frequency band of a signal received via the antenna.

  The wireless device according to claim 2 is the wireless device according to claim 1, wherein the wireless transmission / reception unit performs wireless transmission / reception by switching between the first frequency band and the second frequency band, The signal processing unit includes a first signal processing unit that processes the signal of the first frequency band and a second signal processing unit that processes the signal of the second frequency band, and the clock of the first signal processing unit Each of the frequency and the clock frequency of the second signal processing unit is a frequency other than an integral fraction of the basic frequency and intermediate frequency of the first frequency band, and the basic frequency and intermediate of the second frequency band A frequency other than an integral fraction of the frequency was used.

  According to a third aspect of the present invention, in the wireless device according to the first or second aspect, the control unit is housed in a first housing, and the wireless transmission / reception unit is attached to or detached from the first housing. It was provided in a freely configured second casing.

  Moreover, the radio | wireless apparatus of Claim 4 is a radio | wireless apparatus as described in any one of Claim 1 to 3, The said radio | wireless apparatus transmits the signal from a security sensor directly or the relay for disaster prevention It is a receiver which receives via.

  According to the wireless device of the first aspect, it is possible to reduce the influence of the clock signal of the signal processing unit or its harmonic component on the wireless signal, and to improve the wireless quality.

  According to the wireless device of the second aspect, when wireless transmission / reception is performed by switching between the first frequency band and the second frequency band, a plurality of signals such as a first signal processing unit and a second signal processing unit are provided. Even when the processing unit is provided, the influence of the clock signal of the first signal processing unit or the second signal processing unit or its harmonic component on the radio signal can be reduced, and the radio quality can be improved. it can.

  In addition, according to the wireless device of the third aspect, by unitizing the wireless transmission / reception unit, only the wireless transmission / reception unit is provided for the specific low power security wireless standard necessary for transmitting / receiving a 950 MHz band wireless signal. What is necessary is just to acquire as a target, and since it becomes unnecessary to acquire a radio | wireless standard in the whole radio | wireless apparatus, it becomes possible to acquire a radio | wireless standard easily. In addition, the wireless transmission / reception unit can be unitized to provide versatility, and the wireless transmission / reception unit can be easily attached to a wireless device or repeater having a configuration different from that of the wireless device. Become. Further, each part of the wireless device excluding the wireless transmission / reception unit may be configured to handle only the control of the signal of the 426 MHz band as in the conventional case, so that the improvement associated with the handling of the signal of the 950 MHz band is unnecessary. Become.

  Further, according to the wireless device of the fourth aspect, since it is not necessary to provide a control unit for each frequency band in the receiving device that receives a signal from the security sensor, the receiving device is configured simply and inexpensively. Can do.

It is explanatory drawing for demonstrating the structure of the wireless crime prevention system which concerns on embodiment of this invention. It is a block diagram which shows the electric constitution of a portable setting apparatus. It is a block diagram which shows the electric constitution of a repeater. It is a block diagram which shows the electric constitution of a receiver. It is a disassembled perspective view for demonstrating the attachment / detachment structure of the radio | wireless transmission / reception part with respect to a receiver. It is explanatory drawing for demonstrating transmission / reception of the signal in a crime prevention system. It is explanatory drawing for demonstrating the structure of the conventional radio | wireless crime prevention system.

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. However, the present invention is not limited by this embodiment.

(Overview)
First, the outline of the wireless crime prevention system will be described. FIG. 1 is an explanatory diagram for explaining a configuration of a wireless crime prevention system according to the present embodiment. As shown in FIG. 1, a wireless crime prevention system 1 includes an open / close sensor 10, a fire sensor 11, a human sensor 12, an abnormality notification lamp (outdoor indicator lamp) 13, a repeater 30, and a receiver (a crime prevention receiver). , Center device) 40. Among these, each apparatus except the abnormality notification lamp 13 is disposed indoors in the house, and the abnormality notification lamp 13 is installed outside the house (for example, near the entrance). In the following description, the opening / closing sensor 10, the fire sensor 11, and the human sensor 12 are collectively referred to as “security sensor 2” as necessary, and the security sensor 2 and the abnormality notification lamp 13 are referred to as “ Collectively referred to as “security terminal 3”. Here, one each of the open / close sensor 10, the fire sensor 11, the human sensor 12, the abnormality notification lamp 13, and the repeater 30 are provided, but any plurality may be provided.

  The security system 1 is different from the conventional security system shown in FIG. 7 and includes a portable setting device (mini-controller) 20. The portable setting device 20 is setting means for setting the crime prevention state of the receiving device 40. For example, the portable setting device 20 is carried by a user or used in an arbitrary place within a range where radio waves reach the indoor repeater 30 or receiving device 40. In particular, when the receiving device 40 is installed in the living room and the living room is away from the entrance, it takes time until the user releases the security mode in the living receiving device 40 after the user returns home. Since there is a possibility that the crime prevention mode cannot be canceled in time, the convenience of the user can be improved by arranging the portable setting device 20 in the vicinity of the entrance.

  In this security system 1, two frequency bands are used in combination as frequency bands for transmitting and receiving signals. Specifically, the 426 MHz band is used between the security terminal 3 and the repeater 30 or the receiving device 40. Further, the 950 MHz band is used among the portable setting device 20, the repeater 30, and the receiving device 40. That is, the repeater 30 and the receiving device 40 transmit and receive signals in two frequency bands, a 426 MHz band (first frequency band) and a 950 MHz band (second frequency band). In this way, by using the 950 MHz band in addition to the conventional 426 MHz band, high-speed processing of setting information and the like is achieved by improving the communication speed, and communication reliability is improved. In particular, the security terminal 3 communicates only in the conventional 426 MHz band, so there is no need to replace existing ones or change the design. On the other hand, the repeater 30 and the receiving device 40 need to transmit and receive signals in two frequency bands, but by providing only one control unit 44 to be described later for signal processing, it is simple and inexpensive. The structure allows two frequency bands to be used together. A specific structure for this will be described later.

(Configuration-security terminal)
Next, the configuration of the wireless crime prevention system 1 will be described. First, the configuration of the security terminal 3 will be described. However, since the open / close sensor 10, the fire sensor 11, the human sensor 12, and the abnormality notification lamp 13 can be configured in the same manner as in the past, only the outline thereof will be described here. The open / close sensor 10 is a wireless open / close detection means for detecting the open / closed state of the door or window by magnetism or the like. When the open / close sensor 10 detects that the door or window is open, a signal to that effect is wirelessly transmitted. Send in. The fire sensor 11 is a fire detection means for detecting the occurrence of a fire by detecting smoke or heat. When a fire occurrence is detected, a signal to that effect is transmitted wirelessly. The human sensor 12 is a human body detection unit that detects a human body by detecting infrared rays. When a human body is detected, the human sensor 12 wirelessly transmits a signal to that effect. The abnormality notification lamp 13 is an abnormality occurrence notifying means for notifying the occurrence of an abnormality such as a fire outdoors by turning on or blinking when a transfer signal is received from the receiving device 40. However, the detection principle in these security terminals 3 is arbitrary, and other known principles can be used.

(Configuration-portable setting device)
The portable setting device 20 is a wireless device for setting a crime prevention state in the receiving device 40 by transmitting a wireless signal to the receiving device 40. FIG. 2 is a block diagram showing an electrical configuration of the portable setting device 20. As shown in FIG. 2, the portable setting device 20 includes various button groups 22 and an indicator lamp group 23 on the front surface of the housing, and a wireless transmission / reception unit 24, a speaker 25, and a storage unit inside the housing. 26, a power supply unit 27, and a control unit 28 are accommodated.

  The button group 22 includes an emergency button 22a, a start button 22b, a security button 22c, and a release button 22d. The indicator lamp group 23 includes an emergency lamp 23a, an alarm lamp 23b, an OK lamp 23c, an NG lamp 23d, a guard lamp 23e, and a release lamp 23f.

  The wireless transmission / reception unit 24 transmits and receives wireless signals in the 950 MHz band, and includes a dedicated antenna 24a in the 950 MHz band. The speaker 25 outputs an alarm sound. The storage unit 26 is configured by, for example, a flash memory (the same applies to storage units 32 and 42 described later), and stores programs and parameters necessary for control of the portable setting device 20. The power supply unit 27 includes a battery (not shown), and supplies power supplied from the battery to each unit of the portable setting device 20. The control unit 28 includes, for example, a CPU (Central Processing Unit) (not shown) and a program executed on the CPU. In particular, the control unit 28 includes a signal processing unit 28a. When transmitting a radio signal, the signal processing unit 28a performs carrier sense by a known method, and transmits the radio signal only when radio in the same frequency band is not detected.

  In the portable setting device 20 configured as described above, when the emergency button 22a is pressed, an emergency signal is transmitted to the receiving device 40 via the wireless transmission / reception unit 24, and the emergency light 23a is turned on or blinking (hereinafter referred to as “emergency light”). The lighting or flashing is simply described as lighting). When the emergency signal is received by the receiving device 40, the emergency signal is transferred from the receiving device 40 to the security company, and the security guard rushes to the house.

  When the security button 22c is pressed, the security lamp 23e is turned on. When the start button 22b is pressed in this state, a security request signal is transmitted via the wireless transmission / reception unit 24. When the guard request signal is received by the receiving device 40, the crime prevention mode of the receiving device 40 is set to the outing guard mode. Here, the outing security mode is a mode in which the security company performs monitoring when the user goes out. When an abnormality occurs, an abnormal signal is transferred from the receiving device 40 to the security company, and the security guard rushes to the house. . When the crime prevention mode of the receiving device 40 is set to the outing security mode in this way, a security confirmation signal is transmitted from the receiving device 40, and this security confirmation signal is transmitted via the wireless transmission / reception unit 24 of the portable setting device 20. If received, the OK lamp 23c is turned on. On the other hand, when the security confirmation signal is not received by the portable setting device 20 within a predetermined time after the start button 22b is pressed, the NG lamp 23d is turned on.

  When the release button 22d is pressed, the release lamp 23f is turned on. When the start button 22b is pressed in this state, a release request signal is transmitted via the wireless transmission / reception unit 24. When the release request signal is received by the receiving device 40, the crime prevention mode of the receiving device 40 is released. When the crime prevention mode is released in this way, a release confirmation signal is transmitted from the receiving device 40, and when this release confirmation signal is received via the wireless transmission / reception unit 24 of the portable setting device 20, the OK light 23c. Lights up. On the other hand, when the release confirmation signal is not received by the portable setting device 20 within a predetermined time after the start button 22b is pressed, the NG lamp 23d is turned on.

(Configuration-repeater)
1 is a relay means for receiving a signal wirelessly transmitted from the security sensor 2 and transmitting the received signal to the portable setting device 20 or the receiving device 40. It is a radio device for a security system to receive. The repeater 30 is also a relay unit that receives a signal wirelessly transmitted from the receiving device 40 and transmits the signal to the portable setting device 20 or the abnormality notification lamp 13. The repeater 30 is disposed between the security sensor 2 and the receiving device 40, or is disposed between the receiving device 40 and the abnormality notification lamp 13.

  FIG. 3 is a block diagram showing an electrical configuration of the repeater 30. As shown in FIG. 3, the repeater 30 includes a wireless transmission / reception unit 31, a storage unit 32, a power supply unit 33, and a control unit 34. The wireless transmission / reception unit 31 transmits / receives signals in the 426 MHz band and the 950 MHz band. Details of the wireless transmission / reception unit 31 will be described later. The storage unit 32 stores programs and parameters necessary for controlling the repeater 30. The power supply unit 33 includes a battery (not shown), and supplies power supplied from the battery to each unit of the repeater 30. The control unit 34 is a control unit that controls each unit of the repeater 30.

  Here, details of the wireless transmission / reception unit 31 will be described. The wireless transmission / reception unit 31 includes an antenna 35, an antenna side connection unit 36, a first signal processing unit 37, a second signal processing unit 38, and a control unit side connection unit 39. Only one antenna 35 is provided, and this antenna 35 is used in combination for transmission and reception of signals in two frequency bands of the 426 MHz band and the 950 MHz band. That is, the total length L of the antenna 35 is determined to be a quarter wavelength of 426 MHz and a fifth wavelength of 950 MHz so that the 426 MHz band and the 950 MHz band can be used together. The antenna side connection part 36 is a connection terminal connected to the antenna 35.

  The first signal processing unit 37 processes a 426 MHz band signal, and includes an LPF (low-pass filter) 37a and a first basic processing unit 37b. The LPF 37a is a first frequency band passing means that allows only signals below the vicinity of the 426 MHz band to pass. The LPF 37a may be a BPF (band pass filter) that allows only the vicinity of the 426 MHz band to pass. The first basic processing unit 37b converts the signal in the first frequency band received by the antenna 35 and input through the antenna side connection unit 36 into a signal of a predetermined first method, and controls the control unit side connection unit 39. The first system signal input from the control unit 34 via the control unit side connection unit 39 is output to the antenna 35 via the antenna side connection unit 36 in the first frequency band. A first signal processing unit.

  The second signal processing unit 38 processes a 950 MHz band signal, and includes an HPF (High Pass Filter) 38a, a second basic processing unit 38b, and a compatible processing unit 38c. The HPF 38a is a first frequency band passing means that allows only signals in the vicinity of the 950 MHz band or higher to pass. The HPF 38a may be a BPF (band pass filter) that passes only the vicinity of the 950 MHz band. The second basic processing unit 38b converts the second frequency band signal received by the antenna 35 and input via the antenna side connection unit 36 into a predetermined second system signal and outputs the second system signal. Is a second signal processing unit that outputs the above signal to the antenna 35 via the antenna side connection unit 36 in the second frequency band. The compatible processing unit 38c converts the signal output from the second basic processing unit 38b into the second system signal and converts the signal into the first system signal, and sends it to the control unit 34 via the control unit side connection unit 39. In addition to outputting, the first system signal input from the control unit 34 via the control unit side connection unit 39 is converted into a second system signal and output to the second basic processing unit 38b.

  In particular, the first signal processing unit 37 transmits a radio signal in the 426 MHz band without performing carrier sense, and the second signal processing unit 38 performs a carrier sense in a known method when transmitting a radio signal in the 950 MHz band. The radio signal is transmitted only when radio in the same frequency band is not detected.

  Of the components of the wireless transmission / reception unit 31 configured as described above, the components other than the antenna 35 are mounted on both surfaces of the same base and modularized. More specifically, for example, the first basic processing unit 37b and the second basic processing unit 38b are each configured by a wireless IC, and the compatible processing unit 38c is configured by a microcomputer, and the wireless IC and the microcomputer are the same. It is mounted on both sides of the board.

Here, the relationship between the clock frequency of each of the first basic processing unit 37b and the second basic processing unit 38b and the frequency bands for transmitting and receiving radio signals (here, the above-described two bands of the 426 MHz band and the 950 MHz band). Will be described. First clock frequency fc ₁ the clock frequency of the first basic processing unit 37b, when the clock frequency of the second basic processing unit 38b and the second clock frequency fc _2, these first clock frequency fc ₁ and the second clock frequency fc ₂ Are frequencies other than a fraction of an integer for the fundamental frequency and intermediate frequency of the 426 MHz band, and are frequencies other than an integer of 1 for the fundamental frequency and intermediate frequency of the 950 MHz band.

  The clock frequency of the first basic processing unit 37b is an operating frequency of the IC constituting the first basic processing unit 37b, and is determined by an oscillator (not shown) provided in the first basic processing unit 37b. The clock frequency of the second basic processing unit 38b is the operating frequency of the IC that constitutes the second basic processing unit 38b, and is determined by an oscillator (not shown) provided in the second basic processing unit 38b.

  The fundamental frequency of the 426 MHz band is each frequency of 48 channels set by dividing the frequency from 426.2500 MHz to 426.8375 MHz by the 12.5 kHz width when the occupied frequency bandwidth is 8.5 kHz or less, When the occupied frequency band exceeds 8.5 kHz and is 16 kHz or less, the frequencies of 24 channels are set by dividing the range from 426.2500 MHz to 426.8375 MHz into 25 kHz widths. The intermediate frequency of the 426 MHz band is a superheterodyne method or a double frequency using a PLL (not shown) provided in the first basic processing unit 37 b in order to amplify or filter the signal of the basic frequency of the 426 MHz band. The frequency of the intermediate signal generated by down-conversion using the superheterodyne method, for example, 21.7 MHz and 455 kHz.

  On the other hand, the fundamental frequency of the 950 MHz band is the center frequency of each of the 24 unit channels set by dividing the 5 MHz band from 950.8 MHz to 955.8 MHz by the 200 kHz width, from 951.0 MHz to 955.6 MHz. Up to 24 frequencies specified in increments of 0.2 MHz. The intermediate frequency of the 950 MHz band refers to a superheterodyne method or a double frequency using a PLL (not shown) provided in the second basic processing unit 38b in order to amplify and filter the signal of the basic frequency of the 950 MHz band. The frequency of the intermediate signal generated by down-conversion by the superheterodyne method, for example, the frequency of 1/9 of the fundamental frequency, and about 105.7 MHz for 951.0 MHz. However, the intermediate frequency can be set to other numerical values so as to be fixed or adjustable. For example, the intermediate frequency may be set to a frequency obtained by up-converting the basic frequency.

For example, the first clock frequency fc ₁ and 21.25 MHz are set, and the second clock frequency fc ₂ is set to 12.8 MHz. In this case, the first clock frequency fc ₁ = 21.25 MHz and the second clock frequency fc ₂ = 12.8 MHz are any of 426.2500 MHz, 21.7 MHz, 455 kHz, 951.0 MHz, and 105.7 MHz. On the other hand, it is other than 1 / integer. For this reason, when the clock frequency becomes 1 / integer of the transmission / reception frequency, it is possible to reduce noise caused by the clock signal or its harmonics. Note that the numerical values of the clock frequencies listed here are merely examples, and other clock frequencies can be adopted as long as the above conditions are met.

  As such noise countermeasures, various countermeasures can be taken in addition to the above-described clock frequency setting. For example, the antenna 35 and the noise source (for example, the first basic processing unit 37b and the second basic frequency unit 2) The oscillator 35 (not shown) provided in the basic processing unit 38b is disposed as far away as possible, the antenna 35 and the noise source are connected via a coaxial cable, the first basic processing unit 37b and the second basic processing unit 38b For example, a dedicated regulator may be used as a power source.

(Configuration-Receiver)
Next, the receiving device 40 in FIG. 1 will be described. The receiving device 40 is a control device that monitors the presence or absence of an abnormality by receiving a signal transmitted from the security sensor 2 via the repeater 30 or by directly receiving the signal. The signal from the security sensor 2 Is a wireless device for a crime prevention system that receives When the receiving device 40 detects an abnormality, the abnormality notification lamp 13 is wirelessly transmitted to the abnormality notification lamp 13 to notify the abnormality, and if necessary, an abnormality occurrence is wired or wirelessly to the security company. It is also a wireless repeater for transferring information. The receiving device 40 is installed, for example, in a place (typically, an entrance or a living room) that is easy for a user to visually recognize indoors.

  FIG. 4 is a block diagram illustrating an electrical configuration of the receiving device 40. As shown in FIG. 4, the reception device 40 is configured to accommodate a wireless transmission / reception unit 41, a storage unit 42, a power supply unit 43, and a control unit 44. The storage unit 42 stores programs and parameters necessary for controlling the receiving device 40. The power supply unit 43 supplies power supplied from a commercial power supply to each unit of the receiving device 40. The control unit 44 controls each unit of the receiving device 40.

  The wireless transmission / reception unit 41 is a wireless transmission / reception unit that transmits and receives signals in the 426 MHz band and the 950 MHz band. The antenna 45, the antenna side connection unit 46, the first signal processing unit 47, the second signal processing unit 48, and the control unit side A connection unit 49 is provided. The first signal processing unit 47 includes an LPF 47a and a first basic processing unit 47b, and the second signal processing unit 48 includes an HPF 48a, a second basic processing unit 48b, and a compatibility processing unit 48c. Since each part of these radio | wireless transmission / reception parts 41 can be comprised similarly to each part of the same name in the radio | wireless transmission / reception part 31 of the repeater 30, except the structure to mention specially, the detailed description is abbreviate | omitted.

  In particular, the clock frequency of the first basic processing unit 47b and the clock frequency of the second basic processing unit 48b are both frequencies other than a fraction of an integer relative to the basic frequency and intermediate frequency of the 426 MHz band, and the 950 MHz band. The fundamental frequency and the intermediate frequency are set to frequencies other than an integer.

  Here, the attachment / detachment structure of the wireless transmission / reception part 41 with respect to the receiver 40 is demonstrated. FIG. 5 is an exploded perspective view for explaining the attachment / detachment structure of the wireless transmission / reception unit 41 with respect to the reception device 40. As shown in FIG. 5, the housing (first housing) 40a of the receiving device 40 is formed with a housing portion 40b which is a recess for detachably housing the wireless transmission / reception unit 41. The unit 40b is provided with a connection terminal 40c (not shown in FIG. 4) for connecting to the control unit side connection unit 49 of the wireless transmission / reception unit 41. On the other hand, the wireless transmission / reception unit 41 is a housing different from the housing 40a of the receiving device 40, and is provided in a housing (second housing) 41a having an outer shape corresponding to the housing unit 40b. Specifically, the antenna side connection unit 46, the first signal processing unit 47, and the second signal processing unit 48 of the wireless transmission / reception unit 41 are accommodated inside the housing 41a, and an antenna is provided outside the housing 41a. 45 and the control part side connection part 49 are arrange | positioned. And in the state which accommodated the radio | wireless transmission / reception part 41 in the accommodating part 40b, the radio | wireless transmission / reception part 41 is connected to the control part 44 by connecting the control part side connection part 49 to the connection terminal 40c.

  Thus, the effect of unitizing the wireless transmission / reception unit 41 is as follows. That is, as described above, the control unit 44 of the receiving device 40 only needs to control the 426 MHz band signal as in the conventional case, and does not need to control the 950 MHz band signal. The signal may be processed and controlled only by the wireless transmission / reception unit 41. Therefore, by unitizing the wireless transmission / reception unit 41, the specific low-power security wireless standard necessary for transmitting / receiving a wireless signal in the 950 MHz band may be acquired only for the wireless transmission / reception unit 41. Since it is not necessary to acquire the wireless standard as a whole, it is possible to easily acquire the wireless standard. In addition, the wireless transmission / reception unit 41 can be unitized so as to have versatility, and the wireless transmission / reception unit 41 can be easily attached to a reception device or a repeater having a configuration different from that of the reception device 40. Is possible. In addition, by adopting the same shape as the unit of the wireless transmission / reception unit of the conventional receiving device 106 only for the 426 MHz band, even when the 950 MHz band is added as the frequency band of the signal to be used, the transmission / reception unit becomes the 950 MHz band compatible unit of the present application. By replacing, it is possible to construct a crime prevention system that can easily transmit and receive in a plurality of bands. Furthermore, each part of the receiving device 40 except the wireless transmission / reception unit 41 may be configured to handle only the control of the 426 MHz band signal, etc., as in the prior art, so there is an improvement associated with handling the 950 MHz band signal. It becomes unnecessary.

  In particular, when the wireless transmission / reception unit 41 is unitized in this way, it is necessary to mount each part of the wireless transmission / reception unit 41 close to each other because of a request for downsizing of the unit. It is considered that the influence of noise is increased. For this reason, as described above, the clock frequency of the first basic processing unit 47b and the clock frequency of the second basic processing unit 48b are set to a frequency other than an integral fraction of the basic frequency and intermediate frequency of the 426 MHz band and 950 MHz band. This increases the need for noise reduction.

(processing)
Next, the process which the crime prevention system 1 comprised as mentioned above performs is demonstrated. FIG. 6 is an explanatory diagram for explaining transmission and reception of signals in the security system 1. In the following, “step” is abbreviated as “S”.

  As shown in FIG. 6, the security sensor 2 transmits an abnormality detection signal without performing carrier sense in the 426 MHz band (SA1). When the abnormality detection signal is received by the repeater 30, the first basic processing unit 37b of the first signal processing unit 37 of the repeater 30 converts the abnormality detection signal into a command of the first command system and converts it into a control unit. 34, the control unit 34 determines whether or not the abnormality detection signal is relayed based on this command. When relaying, the control unit 34 transmits a relay instruction based on a command of the first command system to the first basic processing unit 37b, and the first basic processing unit 37b receiving the relay instruction transmits the abnormality detection signal to the carrier sense. Without being transmitted to the receiver 40 in the 426 MHz band which is the same frequency band as the signal received via the antenna 35 (SA2).

  When the abnormality detection signal from the security sensor 2 is directly received by the reception device 40 or when it is received via the repeater 30, the first signal processing unit is used in the wireless transmission / reception unit 41 of the reception device 40. 47, the first basic processing unit 47b converts the abnormality detection signal into a command of the first command system and transmits it to the control unit 44. The control unit 44 performs a predetermined response according to the content of the abnormality detection signal based on the command. Process. When the abnormality detection signal from the security sensor 2 is received via the repeater 30, the second basic processing unit 48b of the second signal processing unit 48 detects the abnormality in the wireless transmission / reception unit 41 of the receiving device 40. The signal is converted from the second command system to a command of the first command system and transmitted to the control unit 44, and the control unit 44 performs a predetermined process according to the content of the abnormality detection signal based on the command. As part of such processing, the control unit 44 of the receiving device 40 transmits an instruction to turn on the abnormality notification lamp 13 to the first basic processing unit 47b as a command of the first command system as necessary, and this relay Upon receiving the instruction, the first basic processing unit 47b transmits a transfer signal in the 426 MHz band via the antenna 45 without performing carrier sense, and the abnormality notification lamp 13 that has received the transmission signal displays an abnormality notification. (SA3).

  In addition, the portable setting device 20 transmits a request signal after performing carrier sense in the 950 MHz band in which the transmission speed is set faster than the 426 MHz band (SA4). When this request signal is received by the repeater 30, the second basic processing unit 38b of the second signal processing unit 38 of the repeater 30 converts the request signal into a command of the second command system, and the compatible processing unit 38c. The compatibility processing unit 38c converts the command of the second command system into a command of the first command system and transmits it to the control unit 34. The control unit 34 determines whether the request signal needs to be relayed based on the command. Make a decision. When relaying, the control unit 34 transmits a relay instruction by a command of the first command system to the compatible processing unit 38c, and the compatibility processing unit 38c converts the command of the first command system into a command of the second command system. Is output to the second basic processing unit 38b, and the second basic processing unit 38b performs carrier sensing on the request signal and then transmits it to the receiving device 40 in the 950 MHz band, which is the same frequency band as the signal received via the antenna 35. To send (SA5).

  When the request signal from the portable setting device 20 is directly received by the receiving device 40 or when the request signal is received via the repeater 30, the wireless transmission / reception unit 41 of the receiving device 40 performs the second signal processing. The second basic processing unit 48b of the unit 48 converts the request signal into a command of the second command system and outputs it to the compatibility processing unit 48c. The compatibility processing unit 48c converts the command of the second command system of the first command system. It converts into a command and transmits to the control part 44, and the control part 44 performs the predetermined process according to the content of the request signal based on this command. As a part of such processing, the control unit 44 of the receiving device 40 transmits a confirmation signal transmission instruction by a command of the first command system to the compatible processing unit 48c as necessary, and the compatible processing unit 48c The command of the first command system is converted into the command of the second command system and output to the second basic processing unit 48b, and the second basic processing unit 48b receives the confirmation signal via the antenna 45 after performing carrier sense. Is transmitted in the 950 MHz band, which is the same frequency band as the received signal (SA6).

  When this confirmation signal is received by the repeater 30, the second basic processing unit 38b of the second signal processing unit 38 of the repeater 30 converts this confirmation signal into a command of the second command system, and the compatible processing unit 38c. The compatibility processing unit 38c converts the command of the second command system into a command of the first command system and transmits the command to the control unit 34. The control unit 34 determines whether the confirmation signal needs to be relayed based on the command. Make a decision. When relaying, the control unit 34 transmits a relay instruction by a command of the first command system to the compatible processing unit 38c, and the compatibility processing unit 38c converts the command of the first command system into a command of the second command system. Is output to the second basic processing unit 38b, and the second basic processing unit 38b performs carrier sensing and transmits the confirmation signal in the 950 MHz band via the antenna 35 (SA7).

  When the confirmation signal from the receiving device 40 is directly received by the portable setting device 20 or when it is received by the portable setting device 20 via the repeater 30, the portable setting device 20 receives the confirmation signal. Is processed by the control unit 28, and predetermined processing corresponding to the content of the confirmation signal is performed.

(effect)
Thus, according to the present embodiment, the clock signal or the harmonic component thereof is related to the first basic processing unit 37b, the second basic processing unit 38b, the first basic processing unit 47b, and the second basic processing unit 48b. The influence on the radio signal can be reduced, and the radio quality can be improved.

  Further, when wireless transmission / reception is performed by switching between the 426 MHz band and the 950 MHz band, a plurality of signal processing units such as the first basic processing unit 37b and the second basic processing unit 38b are provided, or the first basic processing unit 47b. And the second basic processing unit 48b, even if a plurality of signal processing units are provided, the influence of the clock signals or their harmonic components of the first basic processing unit 37b and the second basic processing unit 38b on the radio signal Or the influence of the clock signals of the first basic processing unit 47b and the second basic processing unit 48b or their harmonic components on the radio signal can be reduced, thereby improving the radio quality. Can do.

  Further, by unitizing the wireless transmission / reception unit 41, a specific low-power security wireless standard necessary for transmitting / receiving a wireless signal in the 950 MHz band may be acquired only for the wireless transmission / reception unit 41, and the receiving device Since it is not necessary to acquire the wireless standard for 40 as a whole, it is possible to easily acquire the wireless standard. In addition, the wireless transmission / reception unit 41 can be unitized so as to have versatility, and the wireless transmission / reception unit 41 can be easily attached to a wireless device or a repeater having a configuration different from that of the reception device 40. Is possible. Furthermore, each part of the receiving device 40 except the wireless transmission / reception unit 41 may be configured to handle only the control of the 426 MHz band signal, etc., as in the prior art, so there is an improvement associated with handling the 950 MHz band signal. It becomes unnecessary.

  In addition, since it is not necessary to provide a control unit for each frequency band in the receiving device 40 that receives a signal from the security sensor, the receiving device 40 can be configured simply and inexpensively.

[Modifications to Embodiment]
Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention can be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. it can. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved.

(About the purpose and type of communication system)
In the above embodiment, the crime prevention system has been described. However, the present invention can be applied to a communication system of any purpose and type other than this, for example, a wireless residential fire as a terminal device in a disaster prevention system. Communication from a warning device or other battery-powered small wireless device to a receiver as a receiving device, or communication from a portable setting device as a terminal device to an engine starter as a receiving device in an automobile control system Even in this case, the present invention can be applied. Alternatively, the function of the repeater 30 may be built in the portable setting device 20.

(About signal transmission and reception)
In the above embodiment, each of the repeater 30 and the receiving device 40 performs both reception and transmission of signals in two frequency bands, but it is sufficient that only reception of signals in at least two frequency bands can be performed. For example, the repeater 30 receives a signal transmitted from the security sensor 2 in the 426 MHz band and receives a signal transmitted from the receiving device 40 or the portable setting device 20 in the 950 MHz band. You may make it perform with only the 950 MHz band with respect to the apparatus 40 or the portable setting apparatus 20. FIG. The receiving device 40 receives a signal transmitted from the security sensor 2 in the 426 MHz band and receives a signal transmitted from the repeater 30 or the portable setting device 20 in the 950 MHz band. You may make it perform signal transmission to a security company etc. with a wire communication if necessary.

(Signal frequency band)
In the above embodiment, the 426 MHz band and the 950 MHz band are used together, but the other two frequency bands may be used together. Further, the transmission frequency band to be subjected to carrier sense can also be changed according to the combined frequency. In the above embodiment, the second frequency band uses a higher frequency band than the first frequency band, but may be a band having a higher communication speed than the first frequency band. Not exclusively. Or you may make it set the frequency band which performs carrier sense more reliable than signal transmission / reception of a 1st frequency band as a 2nd frequency band.

(Clock frequency selection target)
In the above embodiment, the clock frequencies of the first basic processing unit 37b, the second basic processing unit 38b, the first basic processing unit 47b, and the second basic processing unit 48b have been described. Similarly, the compatibility processing unit 38c The clock frequency is a frequency other than a fraction of an integer with respect to the fundamental frequency and the intermediate frequency of the 426 MHz band, and a frequency other than an integer of 1 with respect to the fundamental frequency and the intermediate frequency of the 950 MHz band, or a compatible processing unit 48c. The clock frequency may be a frequency other than 1 / integer with respect to the fundamental frequency and intermediate frequency in the 426 MHz band, and may be a frequency other than 1 / integer with respect to the basic frequency and intermediate frequency in the 950 MHz band.

(About clock frequency setting)
When the clock frequency can be dynamically changed by a known mechanism, for example, when transmission / reception is performed in the 426 MHz band, the clock frequency is a frequency other than an integral fraction of the basic frequency and intermediate frequency in the 426 MHz band. In the case where transmission / reception is performed in the 950 MHz band, the clock frequency may be dynamically changed to a frequency other than a fraction of an integer with respect to the basic frequency and the intermediate frequency in the 426 MHz band.

(About modularization)
In the above embodiment, only the wireless transmission / reception unit 41 of the receiving device 40 is unitized, but the wireless transmission / reception unit 31 of the repeater 30 may be unitized by the same structure as the wireless transmission / reception unit 41. Alternatively, as with the wireless transmission / reception unit 31, the wireless transmission / reception unit 41 may be incorporated into the reception device 40 without being unitized.

DESCRIPTION OF SYMBOLS 1,100 Security system 2 Security sensor 3 Security terminal 10, 101 Opening / closing sensor 11, 102 Fire sensor 12, 103 Human sensor 13, 104 Abnormal alarm light 20 Portable setting apparatus 40a, 41a Case 22 Button group 22a Emergency button 22b Start button 22c Security button 22d Release button 23 Indicator light group 23a Emergency light 23b Warning light 23c OK light 23d NG light 23e Security light 23f Release light 24, 31, 41 Radio transceiver 24a, 35, 45 Antenna 25 Speaker 26, 32, 42 Storage unit 27, 33, 43 Power supply unit 28, 34, 44 Control unit 28a Signal processing unit 30, 105 Repeater 36, 46 Antenna side connection unit 37, 47 First signal processing unit 37a, 47a LPF
37b, 47b First basic processing unit 38, 48 Second signal processing unit 38a, 48a HPF
38b, 48b Second basic processing unit 38c, 48c Compatible processing unit 39, 49 Control unit side connection unit 40, 106 Receiver 40b Housing unit 40c Connection terminal

Claims (4)

A wireless device that receives a signal from a terminal device,
A wireless transceiver comprising an antenna;
A control unit that performs control based on the content of the signal received by the wireless transmission and reception unit,
The wireless transmission / reception unit includes a signal processing unit that processes a signal received via the antenna,
The clock frequency of the signal processing unit is set to a frequency other than an integer with respect to the fundamental frequency and the intermediate frequency of the frequency band of the signal received via the antenna.
Wireless device. The wireless transmission / reception unit performs wireless transmission / reception by switching between a first frequency band and a second frequency band, and as the signal processing unit, a first signal processing unit that processes a signal of the first frequency band; A second signal processing unit for processing the signal of the second frequency band,
Each of the clock frequency of the first signal processing unit and the clock frequency of the second signal processing unit is a frequency other than an integral fraction of the basic frequency and the intermediate frequency of the first frequency band, and the first The frequency is set to a frequency other than 1 / integer with respect to the fundamental frequency and the intermediate frequency of the two frequency bands.
The wireless device according to claim 1. The control unit is accommodated in the first housing,
The wireless transceiver is provided in a second housing configured to be detachable from the first housing,
The wireless device according to claim 1 or 2. The wireless device is a receiving device that receives a signal from a security sensor directly or via a disaster prevention repeater,
The radio | wireless apparatus as described in any one of Claim 1 to 3.

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