JPH07104409B2 - Wireless receiver - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a wireless reception device that receives a microwave carrier wave transmitted from a wireless transmission device and operates the carrier wave as a driving power source.

(Prior Art) In recent years, a response device has been carried by a person or attached to a moving object,
This responding device stores appropriate information of the person who owns it or appropriate information of an attached moving object, and transmits a question signal by microwave from the interrogating device to be fixed to this responding device,
The response device that receives this inquiry signal transmits an appropriate response signal to the inquiry device by microwave, and the inquiry device compares the received response signal by appropriate means to identify a person or a moving object. Is proposed. The personal information stored in the response device enables the response device to function as an ID card or a driver's license. In addition, in a manufacturing plant that performs high-mix low-volume production, a semi-finished product on the manufacturing line is equipped with this response device that stores specification data, and the inquiring device fixed in each process inquires the response device for specifications. If the work is performed according to this specification, the response device can function as an electronic specification instruction sheet.

Here, when the response device is made to function as the above-mentioned ID card, driver's license, specification instructions, etc., it is inconvenient to supply drive power from a commercial AC power supply to a mobile phone or a mobile phone, and a built-in battery If the driving power is supplied from the device, it is not possible to obtain sufficient satisfaction in terms of downsizing and weight reduction of the response device and life.

Therefore, a technique in which the energy of microwaves transmitted from an external interrogator to a response device is used as a drive power source is disclosed in Japanese Patent Laid-Open Nos. 56-140486 and 63.
-54023, etc. An outline of the system including the conventional response device and interrogation device shown in these figures will be described with reference to the block circuit diagram of FIG.

In FIG. 2, a first oscillating circuit 2 for oscillating a _first frequency f ₁ (for example, 2440 MHz) in the microwave band in the interrogator 1
And a second frequency slightly different from this frequency f _1.
A _second oscillator circuit 3 that oscillates f ₂ (for example, 2455 MHz) is provided. The first frequency f ₁ output from the first oscillating circuit 2 is amplified by the amplifier 4 and remains unmodulated, and the energy wave having the first frequency f ₁ as a carrier wave from the antenna 5 by vertical polarization, for example. Is transmitted to the response device 6. The second frequency f ₂ output from the second oscillator circuit 3 is A1 modulated by the interrogation signal in the modulator circuit 7,
Further, it is amplified by the amplifier 8 and transmitted from the antenna 9 to the response device 6 as an inquiry signal wave having the second frequency f ₂ as a carrier by horizontal polarization. Then, in the interrogation device 1,
Second harmonic of the _first frequency f ₁ transmitted from the response device 6
An antenna 10 is provided for receiving a response signal wave having 2f ₁ as a carrier wave. A response signal is demodulated from the response signal wave received by the antenna 10 through the bandpass filter 11 and the low noise block down converter 12. In addition,
The interrogation apparatus 1 includes a microprocessor or the like (not shown) and identifies whether or not the demodulated response signal is appropriate for the interrogation signal, or performs an operation corresponding to the response signal. Output signals etc.

The response device 6 is provided with an antenna 13 for receiving the energy wave transmitted from the antenna 5, and the energy wave received by this antenna 13 is converted and output to DC power + B via a rectifier circuit 14 and a low-pass filter 15. . This DC power is used as a drive power source for the response device 6. Further, the energy wave received by the antenna 13 is converted into the second harmonic wave 2f by the multiplier circuit 16 such as a diode, and is given to the modulation circuit 18 as a carrier wave of the response signal wave through the bandpass filter 17. The second harmonic 2f ₁ is A1 modulated by the response signal in the modulation circuit 18, and is transmitted from the antenna 19 to the interrogation apparatus 1 as a response signal wave. In addition, an antenna 20 for receiving the interrogation signal wave transmitted from the antenna 9 to the response device 6
Is provided, and the interrogation signal is demodulated from the interrogation signal wave received by the antenna 20 through the detection circuit 21 and the high-pass filter 22. It should be noted that the response device 6 includes a microprocessor or the like (not shown), stores appropriate information, and outputs an appropriate response signal in accordance with the demodulated interrogation signal.

(Problems to be Solved by the Invention) By the way, in the response device 6 described above, the interrogation device 1
The longer the distance from, the weaker the electric field strength of the energy wave that can be received by the response device 6. Then, the capacity of the DC power obtained via the rectifier circuit 14 and the low-pass filter 15 is reduced accordingly. As a result, a situation occurs in which an appropriate operating voltage of the built-in microprocessor or the like cannot be obtained. Therefore, due to the strength of the energy wave radiated from the antenna 5 of the interrogation apparatus 1 and the like, the response apparatus 6 is limited in the distance from the interrogation apparatus 1 that can properly communicate.

Obviously, the longer the communicable distance is, the more convenient it is when the response device 6 functions as an ID card or the like. However, the strength of the energy wave that can be radiated from the interrogation apparatus 1 is limited by laws and regulations. In addition, the response device 6
From the viewpoint of reducing the size and weight of the antenna, there is a limit to the size of the antenna 13 for receiving energy waves and the array thereof. Therefore, the communicable distance of the response device 6 cannot be sufficiently obtained, and it is desired to improve the distance.

The present invention has been made in view of the circumstances of the system including the above-described conventional response device and interrogation device, and provides a wireless receiver that can be applied to the response device and can appropriately increase the communicable distance. The purpose is to

(Means for Solving the Problems) In order to achieve such an object, a radio receiving apparatus of the present invention has an energy transmitted from a radio transmitting apparatus by two carrier waves having different frequencies or at least one of polarization planes. A radio receiving apparatus for receiving a wave and a signal wave, a first antenna for receiving the energy wave, a first rectifying circuit for rectifying a carrier wave of the energy wave received by the first antenna, and the signal A second antenna for receiving a wave, a second rectifier circuit for rectifying a carrier wave of the signal wave received by the second antenna, and a DC power output from the first and second rectifier circuits. An adder circuit for adding the output power of the adder circuit as a drive power source for the wireless reception device, and a high power generated by the rectification of the first rectifier circuit. It is configured to utilize the harmonic as the carrier wave of the response wave.

(Function) A second antenna for receiving a signal wave is provided with a rectifier circuit for rectifying a carrier wave of the signal wave, and DC power by an energy wave
Since the DC power due to the signal wave is added and used as the driving power supply for the wireless reception device, the power capacity of the driving power supply increases by the amount due to the signal wave. As a result, the communicable distance of the response device to which the wireless reception device of the present invention is applied becomes longer.

Further, since the response wave is a harmonic wave generated by rectifying the energy wave in the first rectifier circuit, a circuit for generating the carrier wave is unnecessary.

(Example) Hereinafter, an example of the present invention will be described with reference to FIG. FIG. 1 is a block circuit diagram showing an outline of a system of a response device and an interrogation device to which an embodiment of a wireless reception device of the present invention is applied. In FIG. 1, circuit blocks that are the same as or equivalent to those in FIG. 2 are assigned the same reference numerals and overlapping explanations are omitted.

1 is different from that shown in FIG. 2 in the following points.

First, the interrogation signal wave received by the antenna 20 of the response device 30 is rectified by the detection and rectification circuit 31, and its output is given to the high-pass filter 22 and the low-pass filter 32. From this high pass filter 22, the interrogation signal is demodulated as in FIG. Then, from the low pass filter 32, the carrier wave of the interrogation signal wave is converted into DC power and output. The direct-current power of the carrier wave of the interrogation signal wave and the direct-current power of the carrier wave of the energy wave output from the low-pass filter 15 are given to the adder circuit 33, and the direct-current power output from the adder circuit 33 is wireless according to the present invention. It is used as a driving power source for the response device 30 to which the receiving device is applied. Further, if a diode or the like is used as the rectifying circuit 14 for rectifying the energy wave, a harmonic is generated due to the rectifying action. Therefore, the second harmonic 2f generated in the rectifier circuit 14 is the bandpass filter.
It is extracted at 17 and given to the modulation circuit 18 as a carrier wave of the response wave.

In such a configuration, the DC power of the conventional energy wave is added to the DC power of the interrogation signal wave which has not been conventionally used to be used as a driving power source, so that the power capacity is increased by the interrogation signal wave. Therefore, the response device 30
The communication distance becomes longer than that of the conventional one.
Further, since the second harmonic generated by the rectification function for rectifying the energy wave is used as the carrier wave of the conversion circuit 18, the conventional multiplication circuit 16 can be omitted.

By the way, in the embodiment shown in FIG. 1, the responding device 30 individually transmits the antenna 1 to the energy wave and the interrogation signal wave.
3,20 are provided. Therefore, no matter which polarization plane the energy wave and the interrogation signal wave are transmitted on, the antennas 13 and 20 capable of receiving the radio wave may be provided.

(Effects of the Invention) Since the present invention is configured as described above, it has the effects described below.

In addition to the DC power obtained by rectifying the carrier wave of the energy wave, the DC power obtained by rectifying the carrier wave of the signal wave is also used as the drive power source, so the power capacity of the drive power source is increased and the distance for proper reception is increased accordingly. You can

Further, since the harmonic wave generated by rectifying the energy wave by the first rectifier circuit is used as the carrier wave of the response wave, the conventional multiplier circuit or the like becomes unnecessary, and the number of parts can be reduced accordingly.

[Brief description of drawings]

FIG. 1 is a block circuit diagram showing an outline of a system of a response device and an interrogation device to which an embodiment of a wireless reception device of the present invention is applied, and FIG. 2 is composed of a conventional response device and interrogation device. It is a block circuit diagram which shows the outline of a system. 13,20,40,50: Antenna, 14: Rectifier circuit, 31,52: Detection and rectifier circuit, 33: Adder circuit, 41, 42, 51: Feed line.

Front page continued (72) Inventor Yoshikazu Kawashima 1-12-2 Kawana, Fujisawa-shi, Kanagawa Yamatake Honeywell Co., Ltd. Fujisawa Plant (72) Inventor Isao Ishikawa 1-2-12 Kawana, Fujisawa, Kanagawa Yamatake Honeywell Co., Ltd. Fujisawa Factory (56) References JP 63-54023 (JP, A) JP 63-5287 (JP, A)

Claims (1)

[Claims] 1. A radio receiving apparatus for receiving an energy wave and a signal wave respectively transmitted from a radio transmitting apparatus by two carrier waves having different frequencies or at least one of polarization planes, the first wave receiving the energy wave. An antenna, a first rectifier circuit that rectifies a carrier wave of the energy wave received by the first antenna, a second antenna that receives the signal wave, and the signal received by the second antenna. A second rectifier circuit for rectifying the carrier wave of the wave; and an adder circuit for adding the DC power output from the first and second rectifier circuits, wherein the output power of the adder circuit is used by the wireless receiver device. A radio receiver characterized in that it is used as a driving power supply and also used as a carrier wave of a response wave, which is a harmonic generated by rectification of the first rectifier circuit. Apparatus.