HU204138B - Information system of high intelligency, economizing on energy, favourably for identifying objects - Google Patents

Abstract

In the system according to the invention, both the respondent (1) and the reader (2) can move relative to one another and several respondents (1) can be placed on an object to be identified. (Fig. 1) Fig. 1 Scope of the description: 5 pages, Fig. 9

Description

BACKGROUND OF THE INVENTION The present invention relates to a highly intelligent information system, preferably for identifying objects, and responding to objects that may be moving blinds has an energy-saving design, that is, consumes only the response energy obtained from an externally transmitted signal prior to reading. The system of the present invention can advantageously be used to identify objects or vehicles that do not have a separate power source.

Identification systems known to date operate by generally taking the energy required to output vehicle-specific data from the vehicle's energy system (Management System Review, March 1989, p. 4) .The signal transmission may be intermittent or continuous, with optical or radio frequency transmission. The identification signal thus consumes a significant amount of energy on the one hand and the identification signal on the other hand is continuously present, which may cause interference to other systems and cause interference. There is also a known solution in which the respondent is powered by a query signal (Proc. Of EuropeanMicrowave Conf. 1989, London, pp. 10471051). .

SUMMARY OF THE INVENTION The object of the present invention is to eliminate the drawbacks of known systems and to provide a system that does not require an energy-saving, independent power source to provide the identification signal, and provides the identification signal only during the query. It has been discovered that the elimination of the disadvantages of known systems can be conveniently solved by separating external power supply and query.

We have also discovered that power supply via photoelectric sensors is particularly economical, since most of the applications are illuminated to some degree, so the power required for operation is available while the identification signal is only asked for in a completely different frequency range (preferably radio frequency), which further increases the system's immunity.

In its solution, an energy-saving, highly intelligent information system, preferably for identifying moving objects, is formed from the responder (s) and the reader (s), in which the responder (s) and the reader (s) move relative to one another. / k is mounted on a moving object (s) while a scan tool is connected to the controller computer. The transponder has an optical signal receiver, a photoelectric sensor, and a converter connected to its output signal line, which converts an output signal line to a control processor, an output power line to a processor power input, and a radio frequency transmitter and a transceiver memory signal output, while the signal output is connected to a radio antenna transmitting antenna, whereby the reader has a radio frequency receiver receiver antenna and an optical radiation source providing an optical signal. The receiver antenna is connected to the input of a radio frequency receiver, the output of which is connected to the input of a system control unit and the output of the system control unit is connected to an optical radiation source input via a controlled drive stage ve10 and the system control unit is bidirectionally connected via

The information system is configured such that the memory in the sleeper is a low-consumption read-only memory with a further power input connected to a power source and the memory being a bidirectional controller connected to the processor. To determine the direction of travel, the system may be constructed with at least two respondents on the object to be identified (e.g., a vehicle), one after the other in the direction of movement.

The system and operation of the present invention will be described in more detail by reference to the drawings, in which:

Figure 25 the principle arrangement of the system according to the invention Figure 2 illustrates a possible system implementation example, a Figure 3 the block diagram of the respondent, 30 Figure 4 the block diagram of the reader, that is Figure 5 the block diagram of the converter, Figure 6 the block diagram of the radio frequency transmitter, Figure 7 block diagram of low - power memory, Figure 8 the selective radio frequency receiver 35 a Figure 9 shows the process flow diagram of the processor.

The structure of the system according to the invention is shown in Figs. Figure 2. In the system, respondents 1 to the object to be retrieved, e.g. the vehicle 39 is permanently or interchangeably secured while the installed reader 2 is connected to the AC power supply 3 and the control computer 4 with a display pin 23. The connection between the respondents 1 and the readers 2 is provided by the optical signal 5 and the radio frequency signal 6.

Figure 3 shows the internal structure of the responder 1. wherein a photoelectric sensor 7 capable of detecting optical signals 5 is connected to a converter 9 via a signal line 8 of a DC voltage and modulation signal. Of the two outputs of the converter 9 that separates the power signal and modulation, the all output signal line is connected to the jd input of the processor 12, while the output line 10 is connected to the input of the processor 12, low power memory 13 and RF transmitter 14.

The processor A12 is bidirectional for data transmission to the low-power memory 13. The data output of the battery 13 is connected to the radio transmitter 14, and the radio output of the radio transmitter 14 is connected to a down transmit antenna. The A16 transmitting antenna is capable of 6 radio frequency signals

EN 204138 Β. Another source of battery-powered memory 13 is connected to power supply 15. The low power memory 13 is only needed in the reprogrammable version of the responder 1, otherwise it may be replaced by a constant content (e.g., wired) memory 13 containing the information to be transmitted. In the latter case, of course, the power supply 15 providing information retention is also not required, so that the processor 12 allows unidirectional data control to transmit the information content of the fixed memory 13 to the radio frequency transmitter 14.

Figure 4 shows the internal layout of the reader 2, whose interface unit 20 communicates between the control computer 4 and the system control unit 19 via a bidirectional data bus. The input of the system control unit 19 is connected to the output of the selective radio frequency 21 receiver and its output is connected to the controlled drive stage 18. The output of the controlled drive stage 18 is connected to the optical power source 17 for transmitting the optical power charging and interrogating signal, while the antenna input of the selective radio frequency receiver 21 is connected to the receiving antenna 22.

Fig. 5 shows the structure of the converter 9, in which the DC output of a filter circuit 24 which separates DC and modulation is connected to the input 25 of the supply voltage supply and the code output of which is connected to the decoder circuit 26 having a mode dependent output signal 11.

A6. FIG. 4A shows the internal structure of a radio frequency transmitter 14 having a data input on the modulator 28. A high-frequency oscillator 27 is connected to the high-frequency input of the modulator 28 and an output stage 29 is connected to its output. The output of the RF output power stage 29 is connected to the transmitting antenna 16.

Figure 7 shows the internal structure of the low-power memory 13 used in the reprogrammable version. The serial / parallel converter 30 is connected to the input of the memory circuit 31 and the parallel / serial converter 32 is connected to the output of the memory. The power supply 15 for memory retention is connected to the power supply of the memory 31.

Block diagram of selective radio frequency receiver 21 a

Figure 8. The selective preamplifier 33 has an input to the receiver antenna 22 for receiving the RF signal, and an output to the local input of the mixing circuit 34 to the local oscillator 35. The output of the mixing circuit 34 is connected to the input of the center frequency amplifier 36, the output of which is connected to the field meter 38 and to the demodulator 37, respectively. The outputs of the field strength meter 38 and the demodulator 37 collectively form the signal data output of the selective radio frequency receiver 21.

In one embodiment of the system of the invention, the interrogator 1 is polled using optical energy, preferably in the infrared range. The photoelectric sensor 7 in the responder 1 - preferably a photocell - converts the energy of the optical signal into electrical energy, which puts the circuits in the responder 1 into a standby state. Respondent 1 transmits the appropriate identification code as a radio frequency signal 6 as a result of an activation signal (e.g., an optical signal). This code can be rewritten with a constant or external broadcast signal. The power supply 15 for the memory 13 in the rewritable transponder 1 is an extremely long-life battery that is widely used in practice, even under extreme climatic conditions. The power of this power supply 15 is used only by the memory 13, and no signal is transmitted. The reader 2 comprises an optical transmitter 17 and an optical radiation source 17 emitting together a coded activation signal. The signal 15 received from the responder 1 is received by a selective radio frequency receiver 21. The signal processing and control system control unit 19 following the radio frequency receiver 21 is connected to the control computer 4 via the appropriate interface unit 20.

In the arrangement illustrated in Fig. 1, the respondents 1, which can range from 1 to N, where the upper limit for N is given by the capacity of the computer 4 that processes the data, e.g. 39 vehicles. The placement can be done one at a time, ie one respondent per object, or more than one responder per object. Objects can also move at speeds of v. The speed v is determined by the speed of data transfer and processing and the amount of information to be transmitted. The system only works when respondents 1 are within the scope of readers 2. This range is defined by the technical characteristics (power, sensitivity, noise, etc.) of the responder 1 and the readers 2. The reader 2 receives the actuating power from the AC power supply 3 and the controller computer 4 for pre-processing the data and controlling the system. In addition to the power required for the reader 2 to operate, the power supply 3 also provides the power required to charge the responder 1 and the signal initiating the response. The "OFF" output of the control computer 4 can be connected to an additional data processing system, such as a dispatcher console. For the operation of the system according to the invention, both the responder 1 and the reader 2 can be the moving object, the essential aspect being the power supply of the system. For this reason, the responder 1 is further considered to be a non-mains powered part, and is therefore assumed to be in motion. emits an infrared signal. This optical signal 5 is received by the responder 1, which, upon effect of the signal 5, outputs a radio frequency signal 6 corresponding to its internal content of information, which is transmitted to the reader 2. The signal received by the reader 2 is processed by the control computer 4.

Figure 2 shows another possible embodiment of the system according to the invention. The assortment 1 is fitted to vehicles 39 at a speed of v. They pass in front of the 2 scanners as they move. The received signal

EN 204138 Β the controller is accessed by a computer 4 which transmits the received information to the display 23.

Figure 3 shows the theoretical arrangement of the respondent. The optical signal 5 is transmitted to the photoelectric sensor 7. The output signal 8 is fed to the converter 9. The converter A9 has two, an output power line 10 and an output signal line 11. The power required for transmission is displayed on the A10 output power line, the transmit command and / or output signal appear on all output signal lines. - if any - reprogramming! command. If a reprogramming command is displayed on the output signal lines 11, the signal 12 will be rewritten by the processor 12 according to the reprogramming command. The power supply 15 provides the contents of the low power memory 13. As a memory circuit, a low-power type is preferred, and the power source 15 is, for example, a Lithium-LodineCeli type battery, which can last up to 10-15 years. The information stored in the battery-consuming memory 13 preferably consists of two parts, one of which is fixed data, for example used for identification, and the other part of the information can be reprogrammed, which may refer to a variable characteristic such as 29 If the system does not require the use of a variable portion of the information, then the memory 13 and power supply 15 are unnecessary, and the information to be radiated can be produced at a much lower cost with fixed memory 13, but a less flexible version is obtained.

Thus, in the system of the invention, the optical signal of the scanner 5 carries energy. The transmission of the fixed and variable codes of the responder 1 is performed by the radio frequency transmitter 14. Its frequency is selected so that it can provide the required amount of information with high reliability, taking into account other parameters of the speed v and transmission. This represents the lower limit of the operating frequency. In our experiments, it is not advisable to lower the frequency below 3 kHz due to the above considerations. The other two aspects that determine the operating frequency from above are the size and design of the transmitting antenna 16 emitting the signal. Here, when it comes to the microwave frequency range, the antenna can only be made flat and small by performing special techniques.

Our experiments show that the upper limit of the useful frequency is a few hundred megahertz.

The optical signal 5 is generated by the optical beam source 17 which is fed by the controlled drive stage 18. The controlled drive stage 18 provides the power required to operate the responder 1 and the initialization code for the response. The controlled drive stage 18 provides the power required for the operation of the responder I and receives the response initialization code from the system control unit 19. The variable part of the response initiating code (if any, e.g. for the purpose of tapping some of the respondents) is received by the system control unit 19 from the control computer 4 via the interface unit 20. The optical signal effect of the initialized encoded response 5 is received, demodulated, and transmitted to the system control unit 19 by the selective radio receiver 21, which is transmitted and modulated by the transponder 6 and transmits the information to the system control unit 19. The system control unit 19 synchronizes to the signal transmitted by the selective radio frequency receiver 21, performs the signal decoding, error analysis and partial error correction and then transmits it via the interface unit 10 to the control computer 4. Wed. The objective radio receiver 21, the system control unit 19 and the interface unit 20 are also powered by the power supply 3. The interface unit 28 communicates with the control computer 4 in a standard (e.g., RS232, IEEE488, etc.) or special digital signal transmission system as desired by the customer.

Fig. 5 shows a layout drawing of the converter 9. This unit generates the operating voltage from the signals transmitted on the output signal line 8, which is transmitted to the output power line 10 and the transmit command on the output signal line 11 or the command to reprogram the memory, if any. The converter 9 starts with a filter circuit 24 which separates the dc and modulated part of the input signal to drive the power supply circuit 25 with its dc output and the decoder circuit 26 with its modulated output.

Figure 6 illustrates the arrangement of the radio frequency transmitter 14. The radio frequency transmitter 14 receives power from the output power line 10 so that it only operates when the optical signals 5 initialize the transmission, i.e., when polled. The radio frequency transmitter 14 comprises a high frequency oscillator 27, a modulator 28 and a power stage 29. The output stage 29 produces a radio frequency signal 6 to the transmitting antenna 16 by modulating the signal of the high frequency oscillator 27 by the modulator 28.

A7. Fig. 4A shows an arrangement 40 of low power memory 13. At its input, the 30 serial / parallel converter receives signals from the 12processor. The content of the memory circuit 31 is maintained by the power supply 15. From the output of the low power memory 13, the signal is transmitted to the radio frequency transmitter 14 45 via the parallel / serial converter 32.

. Fig. 8 illustrates the basic construction of the selective radio frequency receiver 21. The signal received by the receiving antenna 22 is fed to the selective preamplifier 33 and, after amplification, is applied to the mixing circuit 34, which outputs a mid frequency signal amplified by the center frequency amplifier 36 using the signal of the locator 35. At its output, the demodulator unit 37 generates a decoded signal for the system controller 19. Also connected to the output of the mid frequency amplifier 36 is a field amplifier 55 which disables signal processing at low levels of the received signal.

FIG. 9 illustrates a process flow diagram of processor 12. The signal processing process is the signal level and / or signal level. starts with power recovery recovery, not 60 steps, just the right power supply

EN 204138 Β for incoming energy. When the appropriate levels are reached, the system is reset, but practically does not consume any power beyond the memory 13. This condition occurs eg. when respondent 1 is in a lighted environment. Upon reaching the environment of the illuminated reader 2 in each case, it receives the interrogation signal and determines, based on the interrogation signal, whether the interrogator 2 has sent a broadcast command. In the case of a broadcast command, according to the system-specific protocol, the information in the memory 13 is transmitted to the reader 2. If no broadcast command is received, a further scan is performed to determine if a memory reprogramming command has been received. If the command is the same as the reprogramming command, it reprograms the low-power memory 13 according to the information received after the command. If the incoming command does not match either the transmit or the reprogramming command, the system evaluates it as an electrical disturbance, and practically without power (no transmission), the system is reset and the incoming signal levels are checked and checked. it will continue to work by evaluating the commands it receives.

Thus, it can be seen that the information system of the present invention is a simple but reliable system capable of transmitting information that is inexpensive and can be operated reliably in a low-energy environment. This is particularly useful in cases where a large number of non-energy source objects (eg freight wagons) need to be identified with high reliability.

Claims (39)

An energy saving, high intelligence information system, preferably for identifying moving objects, consisting of a system of transponder (s) and reader (s) in which the transponder (s) and the reader (s) move relative to one another, preferably such that k is mounted on a moving object (s) while a reader (k) connected to the control computer is installed, characterized in that the transponder (1) has a photoelectric sensor (7) receiving an optical signal (5) on its output signal line (8). ) converter (9), which converter (9) is connected to an output signal line (11) to a control processor (12), an output power line (10) to a power input of the processor (23) and a radio frequency transmitter (14) (12) is connected to the power input of the control memory (13) and the signal input of the radio transmitter (14) is the memory (13) the signal output, while the signal output is connected to a transmitting antenna (16), which transmits a radio frequency signal (6), whereby the reader (2), an antenna (22) receiving an RF signal (6) and an optical signal (5) a radiation source (17) and a receiving antenna (22) coupled to an input of a single-frequency receiver (21) whose output is connected to an input of a system control unit (19) and an output of the system control unit (19) to an optical radiation source (17) ), and the developer control unit (19) is bidirectionally connected to the control computer (4) via an interface unit (20). An information system according to claim 1, characterized in that the memory (13) in the responder n (1) is a low-power read-write memory (13) with a further power input being connected to a power source (15) and the memory (13). 13) a bidirectional controller in communication with the van processor (12). Information system according to claim 1 or 2, characterized in that the object to be identified (on a vehicle (39)) is arranged at least two responders (1), one after the other in the direction of movement. List of reference marks 1 respondent 2 scanners 3 power supplies 4 computers 5 optical signals 6 radio frequency signals 7 photoelectric sensors 8 outgoing signal lines 9 converters 10 output power cords 11 output signal lines 12 processors 13 memory · 14 radio frequency transmitters 15 power supplies 16 transmitting antennas 17 optical sources 18 controlled drive levels 19 system control units 20 interface units 21 radio receivers 22 receiving antenna 23 viewers 24 filter circuits 25 power supply 26 decoding circuits 27 high frequency oscillators 28 modulators 29 final stages 30 series / parallel converter 31 memory circuits 32 parallel / serial converter 33 preamps 34 mixing circuits 35 local oscillators 36 mid frequency amplifiers 37 demodulators 38 field strength meters 39 vehicles