KR910001847B1 - Microwave data transmission apparatus - Google Patents

Abstract

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Description

Ultra High Frequency Data Transmission Device

1 is a block circuit diagram of an ultra-high frequency data communication apparatus according to a first embodiment of the present invention.

2 is a waveform diagram related to the first furnace.

3 is a circuit diagram of a power supply CPU used in the first furnace.

4 (a) to 4 (f) are waveform diagrams related to FIG.

5 is a block circuit diagram of an ultra-high frequency data transmission apparatus according to a second embodiment of the present invention.

6 is a waveform diagram related to the fifth furnace.

7 is a circuit diagram of a conventional ultra-high frequency data transmission apparatus.

* Explanation of symbols for the main parts of the drawings

101: call answering machine 102: identification tag

272 amplifier 273 C-MOS microprocessor

277: C-MOS NOR gate 278: capacitor

301: call answering machine 302: transceiver

401: identification tag 417: modulator

523: control modulation signal 524: unmodulated carrier

The present invention relates to an ultra-high frequency data transmission apparatus adapted to transmit and receive information by ultra-high frequency. In the related art, a high frequency data transmission apparatus having a structure as shown in FIG. 7 and transmitting and receiving information by ultra high frequency has been used. In FIG. 7, the identification tag 2 is configured such that the interrogator 1 responds with an ultrahigh frequency signal waveform. The hochun answering machine (1) is supplied from a signal generator (3) for generating an ultra-high frequency signal therein, a transmission antenna (4) for transmitting a signal output from the signal generator (3) to the air like waves, and an identification tag (2). And a demodulator 6 for demodulating the ultra-high frequency from the receiving antenna 5 and the receiving antenna 5 for receiving the ultra-high frequency signal. In addition, the identification tag (2) is a receiving antenna (7) for receiving the ultra-high frequency supplied from the call answering machine (1). A demodulator 9 for demodulating the ultra-high frequency received by the receiving antenna 7, a signal generator 10 for generating a carrier in the ultra-high frequency band, and storing fixed code information to generate a code information signal according to the output of the demodulator 9 Of the mixer 12 and the mixer 12, which may be a modulator for mixing the load information signal supplied from the load generator 11, the code generator 11, with the carrier signal supplied from the signal generator 10, It consists of transmission antennas 8 for transmitting the output signal.

In the conventional high frequency data transmission apparatus having the above structure, the signal obtained from the signal generator 3 installed in the call answering machine 1 is transmitted from the transmission antenna 4 toward the identification tag 2. The transmission signal is received by the receiving antenna 7 of the identification tag 2 and then demodulated by the demodulator 9. The demodulation signal from the demodulator 9 serves as a control signal for controlling the code generator 11 and the signal generator 10. The code information signal is supplied from the load generator 11 into the mixer 12 under the control of the demodulation signal. do. In addition, the carrier wave of the ultra high frequency band is supplied from the signal generator 10 into the mixer 12. In the mixer 12, the carrier of the ultra-high frequency band is modulated as a code information signal. The modulated signal is transmitted by the transmitting antenna 8 of the identification tag 2 into the air toward the call answering machine 1. In the call answering machine 1, the ultra-high frequency from the identification tag 2 is received by the receiving antenna 5. ) Is received. Therefore, the fixed information already stored in the identification tag 2 is taken out by the demodulation operation by the demodulator 6. However, since the signal generator 10 for transmitting the carrier in the ultra-high frequency band must be installed in the identification tag 2 of the ultra-high frequency data transmission apparatus, a relatively large power supply must be installed to drive the signal generator 10. Therefore, the structure of the identification tag 2 becomes more complicated and larger. Furthermore, the conventional apparatus does not consider changing the memory content of the code information in the code generator 11, and as a result, flexibility and application of There was an extreme limitation. It is therefore an object of the present invention to provide a novel ultra-high frequency data transmission device, which makes the identification tag more compact in size and lighter in weight, as well as quite convenient in setting up the operation for use in various applications.

In order to achieve this object, according to the present invention, an ultra-high frequency data transmission apparatus is transmitted from a call answering device and a call answering device having a transmission means for transmitting an ultra-high frequency signal having a modulation period and a non-modulation period, and a receiving means for receiving an ultra-high frequency signal. Since an ultra high frequency signal is detected and modulated based on data of a memory unit of a carrier during an unmodulated period of an ultra high frequency signal, an identification tag including a transmission means for transmitting a high frequency signal after modulation is provided to the call answering machine. The present invention will be described in detail with reference to the accompanying drawings. 1 shows a block circuit diagram of a first embodiment of an ultra-high frequency transmission apparatus according to the present invention.

Referring to the drawings, as shown in FIG. 1, the microwave data transmission apparatus includes a call answering machine 101 including a transceiver 21 and a transceiver antenna 22, an identification tag 2 including a transceiver antenna, and a modulator 24. ), A call answering machine (101) consisting of a receiving signal line (25), a transmitting signal line (26) and a power supply CPU (27). Note that the reception signal line 25 and the previous transmission line 26 can be used as the same signal line. FIG. 2 shows a waveform diagram of the ultra-high frequency at which the identification tag 102 is radiated from the call answering machine 101. As shown in FIG. 2, the ultra-high frequency power supply start signal 51 is shown. It consists of a control signal 52 and an unmodulated waveform 53 (or a waveform for storing data, etc.), and these signal waveforms can be radiated repeatedly every period (v). The operation of such a microwave data transmission device is as follows. First, a series of ultra-high frequency signals are repeatedly emitted from the transmit / receive antenna 22 of the call answering machine 101 in the period Y shown in FIG. The power supply start signal 51 is a signal for activating the power supply of the power installation CPU 27 of the identification tag 108. When the identification tag 102 is installed in a vehicle, a transporter, or the like to operate while moving, the power is normally applied, which is unnecessary. In order to reduce the identification tag 102, it is better to reduce the power consumption. Also, when the call answering machine 101 is fixedly used at a specific position near the front door of the parking lot or the robot of the production line, the identification state: L 102 The power supply of may be sufficient only when the start-up operation is performed only in the monitoring region in the reach of the radiating ultra-high frequency from the call answering machine 101. The power consumption can be adjusted to the minimum range of the surveillance area, thereby saving power consumption.

At this time, the control signal 52 following the power start signal reads data in which the instruction content of the call answering machine 101 is stored in the memory of the power installation CPU 27 or the data in the memory. Is a signal that asks whether or not the memory is stored. When the control signal 52 acts as a read control signal of data in the memory, an unmodulated ultra-high frequency of length is transmitted after the control signal 52. In addition, when this control signal 52 acts as a write control signal in the memory, the write data is transmitted after this signal 521. When the CPU performs a read operation only by the power start signal 51, the read control signal is deleted. 2 shows how a series of signals are generated by amplifying modulation of a carrier having a frequency f. Frequency modulation or phase modulation can be used as a modulation method under a carrier of frequency f. As shown in the figure, a series of signals radiated from the call answering machine 101 are received by the transmit / receive antenna 23 of the identification tag 102, and each of these signals is demodulated by the demodulator 24 to receive a signal line 25 Is transmitted to the power supply CPU 27. The power supply CPU 27 detects the power start signal 51 of the demodulation signal, turns the power on, and then continuously transmits control signals to all transmission lines. (26) If a read control signal to the modulation and demodulation so as to drive group (24) according to the data information via tee fetches the data stored in the memory.

The unmodulated ultra-high frequency received from the transmission antenna 23 following the control signal 52 by this driving operation is demodulated by the read data read from the memory of the power supply CPIJ 27 and radiated again from the transmission / reception antenna 23. The ultra-high frequency demodulated and re-radiated by the modulator 24 is received by the transmit / receive antenna 22 of the call answering machine 101. On the other hand, when the control signal 52 after the power source start signal 51 is a write control signal, the write data signals transmitted after the control signal 52 are input into the power installation CPU 27 via the receive signal line 25. It is written to a predetermined area of the memory for the memory operation. The data transfer operation of the selective writing or reading of information is performed by a series of operations on the identification tag from the call answering machine 101. Also, the identification tag 102 can be turned on only when it is in the surveillance area of the call answering machine 101. And turn off the power automatically, except in the case of forming a "start standby" state to save power consumption. One example of a detailed circuit of the power supply CPU 27 is shown in FIG. This CPIJ 27 is a power source 271 such as a battery or a rechargeable battery. Amplifiers 272, C-MOS microprocessors 273, transistors 274, for example, C-MOS operational amplifiers. Resistors 275, 276, and 279, a C-MOS NOR gate 277, a Caterpillar A'R rotor 278, and oscillators 281 such as ceramics and crystals.

In FIG. 3, power is supplied into the back up terminals of the amplifier 272, the NOR gate 277 and the microprocessor 273. In FIG. The backup terminal for the microprocessor 273 is a terminal arranged to hold memory data stored in the internal RAM. The power dissipation by these devices is very low at 30 # W at best, and the supply voltage is around 3V and the heavy amplifier 272 amplifies up to the voltage needed to drive the C-MOS NOR gate 277. The low level (ground potential) is output from the output terminal during inactivity. Although not shown, a C-MOS comparator may be disposed at the output of the amplifier 272.

4 (a) to 4 (f) show voltage waveforms for respective circuit portions of the power supply CPU 27 in FIG. The operation of the CPU 27 will be described in detail with reference to the voltage waveform of FIG. The ultrahigh frequency signal 4 (a) from the call answering machine 101 received by the transmit / receive antenna 23 is expanded by the modulator 4 (figure 4 (b)) and input to the amplifier 272. The transistor 274 is turned off and thus the two input terminals of the NOR gate 277 are both at a low level with no signal. When the microwave signal is received, the output of the amplifier 272 is shown in FIG. The start signal is brought to a high level (power supply potential), and the output of the NOR gate 277 is low level, which causes the transistor 274 to reduce the base voltage to be in an on state (Fig. 4 (c)). As a result, the power supply voltage is applied by the transistor 274 to the V _DD terminal (FIG. 4 (d)) to generate a clock signal having the oscillation frequency of the oscillator 281 in the microprocessor, and to go from low level to high level. Is inputted, and at the same time, the capacitor 280 discharges to apply a discharge voltage to the reset terminal, thereby causing the microprocessor 273 to be reset.

The microprocessor 273 then starts to operate according to its own setup program and sets the output terminal OUTI to a high level. If the output terminal of the NOR gate 277 is kept at a low level, even if the output of the other input terminal, that is, the amplifier 272 is at a low level, the power supply voltage is input to the VuD terminal so that the microprocessor 273 continues to operate. . At this time, the microprocessor 273 detects the output of the amplifier 272 input to the input terminal IN according to its own program. The control signal 52 is determined as a read control signal. The write data 53 following the control signal is then input into the input terminal IN and stored in the memory of the CPU.

The data stored in the memory can be stored continuously by the power supply voltage applied to the backup terminal even when the power supply of the microprocessor 273 is turned off because the transistor 274 is turned off. After the series of operations is completed, the microprocessor 273 sets the output terminal! OUTI to a low level according to its own program (Fig. 4 (e)).

After the idle state in which no operation is performed, both input terminals of the NOR gate 277 become low level, and the output of the NOR gate 277 becomes high level to turn the transistor off. Thus, the microprocessor 273 stops operating. While one embodiment of the power installation CPU 273 has been described above, it will be appreciated that various circuit structures can be realized within the scope of the present invention.

A detailed embodiment of the automatic identification system in which the call answering machine exchanges data by the ultra-high frequency data transmission apparatus using the identification tag will be described in detail below. This type of device can be used for production control in a factory, warehouse control, entrance control for parking lots, coordination for entry rooms or exits.

Specifically, in production control in a factory, a small identification tag is installed in each component moving on the production line, and a call answering machine for reading memory data of the identification tag is installed near this line. Information about each part in proximity to the call answering machine is read by an identification tag to control movement on the part line according to this information. Production control of these components can be performed precisely in this way.

According to the first embodiment, various signals can be transmitted and received by comparing time zones using any one type of work signal frequency, so that an automatic identification system having various functions can be realized, and therefore, a wide range of applications can be achieved. But a very practical system can be realized.

Example 2

5 is a block diagram of a second embodiment of the ultra-high frequency transmission apparatus according to the present invention. In FIG. 5, the interrogator 301 is a transceiver 302 consisting of a transmission circuit for transmitting the ultra-high frequency signal shown in FIG. It is provided with a polarization ultra-high frequency separating and coupling member 314 for transmitting by the first and second polarity ultra-high frequencies having the same frequency as the control modulation signal 523 and the unmodulated carrier 524 shown in FIG. The other extreme ultrahigh frequencies are specifically a combination of a right polarized ultra high frequency wave and a full polarized ultra high frequency wave, a circular polar high frequency wave and a pickled polar high frequency wave and a 0 "linear straight polar high frequency wave. It is regarded as the coupling between linear polarized ultrahigh frequencies in the direction. Transmit and receive ultra high frequency signals in the air or in the air. The antenna 313 is connected with the call answering machine 301. The identification tag 401 is a lock modulator 416 for demodulating the polarization ultra-high frequency transmission coupling member 415 and the control modulated signal 523 for inputting the ultrasonic signal emitted from the call answering machine 301. A signal processing member 415 comprising a modulator 417 for continuously inserting the modulation ultra-high frequency 524 into the control modulation signal 523 and a low power consumption C-MOS integrated circuit for performing each type of signal processing operation. ) In addition, the transceiver antenna 419 for transmitting and receiving the ultra-high frequency signal from the atmosphere is advanced with the identification tag (401). Operation of the ultra-high frequency data transmission device is described in detail later.

The ultra-high frequency non-modulated wave is modulated by the modulated signal from the call answering machine 301 shown in FIG. 6 and input as a wireless ultra-high frequency by the transmission antenna 31 ::.

The modulation signal shown in FIG. 6 is a control modulation signal 523 having a direction of a first polarity ultra high frequency, for example, a circular polarity ultra high frequency wave of right handedness and an unmodulated ultra-high frequency wave direction of a second polarity ultrahigh frequency, for example a circular shape of a left handed direction. It is a signal composed of a polarized ultra high frequency, and is generated repeatedly with a predetermined period T. Transmitted by the transmit / receive antenna 313. The wireless ultrahigh frequency wave is transmitted by the transmit / receive antenna 419 on the side of the identification tag 401 when the distance between the call answering machine 301 and the identification tag 401 becomes somewhat or shorter and the reception electric field level is somewhat or higher. Received. The furnace is input to the ultra-high frequency separation coupling member 415! At this time, the control modulated signal 523 to be inputted first is demodulated by the lock modulator 416, and is then input into the signal processing member 418. .

The signal processing member 418 is in a standby state when no signal from the call answering machine 301 is received. This standby state is the minimum limiting power consumption required to hold information of the RAM in the signal processing member 418. It is a non-operational state that is made only and does not occur in many circuits with high power supply. When the data information held in the identification tag 401 is requested to be read first in such a state, the signal processing member 418 sends a control signal (Fig. 6) from the call answering machine 301 via the demodulator 416. When the signal 523a for power-up start use of 523 is received, it becomes an operation state. This processing is used to detect the next read command signal 23b so as to read out the data information. In the signal processor 418, the CPU inputs the data information stored in the RAM to the demodulator 417 by the recognition operation for the time of the next unmodulated carrier 524. The modulator 417 is a polar ultrasonic coupling member 415. The modulated ultra-high frequency 524 is modulated by data information. The modulated ultra-high frequencies are radiated from the transmit / receive antenna 419 toward the call answering machine 301 so that these signals are transmitted by the transmit / receive antenna 313. 301). The oscillated ultra-high frequency is detected by the transceiver 302 to retrieve the data information stored in the signal processing member 418. In order to convert the data information held in the identification tag 401, the call answering machine 30t transmits the pair modulated signal 523 composed of the ultra high frequency in the polarity ultra high frequency direction via the transmit / receive antenna 313 as an untrusted ultra high frequency. The transmit / receive antenna 313 transmits a write data signal 524 composed of ultra-high frequency signals in the same first polarization ultra-high frequency direction as a radio ultra high frequency. When the write data signal 524 is transmitted from the transceiver antenna 31: 1 as a radio ultra high frequency, the antenna 419 of the identification tag 401 receives the radio ultra high frequency, and the demodulator 415 is the polar excess frequency separating coupling member 415. Demodulate the received signal via < RTI ID = 0.0 >) < / RTI >

At this time, the signal processing member 418 receives the pre-start signal 523a of the modulation signal 523 for control and becomes an operating state, while performing data information conversion processing according to the signal direction of the write command signal 523b. The contents of the memory data stored in the internal RAM can be rewritten according to the demodulation signal. Although an example is shown in which the read command signal used by the call answering machine 301 during the read operation has the above structure, this read command signal is omitted when the CPU is designed to be read only by the signal 523a for power start control. Can be. Also, only part of the call answerer can be controlled by setting up read operations, but the entire call answering machine cannot be used only for write and read control.

The ultra-high frequency data transmission apparatus can be applied to the production control, warehouse control, entrance control of the parking lot in the factory and adjustment for leaving the room by the person with the identification tag. For example, for use in production control in a factory, call answering machines are installed on each part, in which individual data is input in advance in the memory of the answering machine. The data here is the code number on the production line, the working process. Includes transport routes. The call answering machine is installed in the main position on the production line. The call answering machine controls the movement of the line while transmitting the very high frequency to read the internal data as above for the identification tag installed on each part moving on the production line. Outputs As microwaves penetrate plastics and lumber, identification tags do not need to be specifically placed on the surface of each part. According to the second embodiment, since the identification tag has low power consumption, a high performance ultra high frequency data transmission apparatus that is compact and light can be realized.

Claims (3)

In an ultra-high frequency data transmission apparatus, an ultra-high frequency signal transmitted from a call answering device and a call answering device comprising a transmitting means for transmitting an ultra-high frequency signal having a modulation period and a non-modulating period, and a receiving means for receiving an ultra-high frequency signal, and modulating an ultra-high frequency signal to be modulated. An ultra-high frequency data transmission apparatus comprising an identification tag having a transmission means for performing modulation on a carrier ultra-high frequency based on data in a memory unit and transmitting an ultra-high frequency signal to a call answering machine after modulation. In the ultra-high frequency data transmission apparatus, a call answering device and a call answering device comprising a transmission means for transmitting an ultra-high frequency signal having a first and second polarity ultra-high frequency directions different from each other in a time zone comparison, and a receiving means for receiving an ultra-high frequency signal having a second polarity ultra-high frequency direction It consists of identification tags that detect the first high frequency microwave signal transmitted from the transponder, modulate the second polarity based on the data in the memory unit, and transmit the second high frequency microwave signal in the second polarity ultra high frequency direction to the call answering machine after the modulation. Ultra high frequency data transmission device. 2. An apparatus according to claim 1, wherein circularly polarized microwaves in the same winding direction and two different circularly polarized microwaves in the winding direction are used between the call answering machine and the identification tag.

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