RU2248292C1 - Electronic mark - Google Patents

Abstract

FIELD: systems for identifying transported cargoes in stations for automatic data reading in order to provide tracking of their dislocation and keeping them at transportation.

SUBSTANCE: pulse type code converter includes programming device whose outlet is connected with information inlets of memory device; multiplexing units; unit for introducing data related to object condition. Said unit is connected with one inlet of apparatus for registering object condition. Other inlet of said unit is connected with outlet of cell address decoder of apparatus for registering object condition. Signal shaper is in the form of unit for shaping signal of object condition and for receiving reference sum. First inlet of signal shaper is connected with outlet of decoder of reference sum cell addresses. Second inlet of signal shaper is connected with outlet of memory, its first outlet is connected with first inlets of multiplexing units, its second outlet is connected with first inlet of binary adder whose outlet is connected with third inlet of signal shaper. Inlets of decoder of reference sum cell addresses and decoder of cell address of apparatus for registering object condition are connected with second outlet of address counter. The last is connected with inlets of multiplexing units. Memory unit is programmable one and it is in the form of memory matrix. Multiplexing units are designed for matching transmitted code train with preset or desired standard of signal transmission. Outlet of multiplexing unit forms outlet of pulse type code converter.

EFFECT: enhanced operational reliability.

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Description

The invention relates to means for identifying transported goods during their passage through an automatic information reading point for operational tracking of dislocation and ensuring security control during transportation carried out in wagons, containers, vans, etc.

The electronic tag (EM) is designed for installation on an electronic locking and sealing device (EZPU), which can be used and placed on vehicles, on critical parts of the rolling stock of railways. EZPU is used for remote reading of information about the state of the EZPU when a mobile unit passes through an automatic information retrieval point.

Two main types of EM are known: active (RU 2170684), containing an encoder connected through a modulator to a transceiver antenna, and an autonomous power source, while the encoder contains a master oscillator and a programming node connected to a memory matrix, i.e. containing the transmitter and the power source, and passive (RU 2170684, US 3633158, US 4068232) - not having their own power source. The reading range of the first EM does not depend on the energy of the reader, and the second is determined by the energy coming from the reader.

The advantage of active EMs over passive ones is a significantly longer, not less than 2–3 times reading range and high permissible EM speed relative to the reader. However, a significant drawback is the large size and relatively high cost of EM.

The advantage of passive EMs is an almost unlimited life, and the disadvantage is the need for more powerful readers.

Patent RU 2203820 describes an EM used as an identifier for a locking and sealing device or a critical part of a rolling stock. This well-known electronic tag contains an encoder connected through a modulator to a transceiver antenna, and an autonomous power supply, the encoder consists of a clock generator and a programming unit connected to a memory matrix, the encoder contains a binary counter whose input is connected to the output of the clock generator, and the outputs connected to the inputs of the insert decoder, column decoder and row decoder, a switch whose first input is connected to the output of the insert decoder, the second input is connected to the output of the memory matrix connected to the output by a column decoder and a row decoder, a code converter, the input of which is connected to the output of the switch, and the output is connected to the input of the adder, the outputs of which are connected to the inputs of the modulator, the third input of the switch connected to the output of the side of the status of the electronic locking and sealing device (ESPA), This autonomous power source is connected only with a memory matrix and a clock generator. In one particular embodiment, the modulator is amplitude and contains microwave diodes configured to operate in a linear mode when the level of the pulse signal of the cutoff voltage of the microwave diodes is exceeded. In another particular case of execution, the modulator is phase and contains microwave diodes, the voltage on which is limited to a level less than the opening threshold, for example, 0.4 V. The EZPU status block is configured to generate the same digital sequences at its output, but in an inverse code when applied to its input signal "0", characterizing the open state of the EZPU, or signal "1, characterizing the closed state of the EZPU. This known EM provides the optimal ratio of reading range, service life and required power irradiation by a reading device, but does not allow recording additional information under production conditions.

The invention is aimed at expanding the functionality and increasing the reliability of monitoring the safety of goods and objects by providing operational control over their condition when interrogated by a reading device, transmitting, among other information, information about identifiable signs of goods and objects, for example, type of object, place and year of manufacture , current state of the object, etc.

This is due to the fact that the electronic tag is configured to generate and transmit encoded filling information for reading by portable and / or stationary reading devices and contains a microwave unit connected to the output of a pulse code converter with an autonomous power supply, including a clock connected to to the address counter with a decoder, the first outputs of which are connected to the address inputs of the storage device, a signal conditioner. In this case, the pulse code converter is equipped with a programming device, the output of which is connected to the information inputs of the storage device, multiplexers, an object state information input device connected via an anti-chatter device to one of the inputs of the object state fixing device, and the other input connected to the decoder output cell addresses of the device for fixing the state of an object. The signal conditioner is made in the form of a device for generating an object state signal and a checksum, which includes cells for fixing the checksum, the first input of the signal generator being connected to the output of the address decoder of the checksum cells, the second input to the output of the storage device, the first output to the first inputs of the multiplexers, and the second output to the first input of the binary adder, the output of which is connected to the third input of the signal conditioner. The inputs of the address decoder of the cells of the checksum and the address decoder of the cells of the device for fixing the state of the object are connected to the second output of the address counter, the address counter is connected to the second inputs of the first, second and third multiplexers, respectively. The storage device is programmable and is a memory matrix, the cells of which are divided into two groups, programmable separately and independently from each other. One of these groups is designed to store service information intended for reading only, and the other is for user information and can be reprogrammed by it. Three data banks are organized in each of these groups, and the storage device contains a bank combination device designed to combine code sequences from the selected data banks into a single sequence, and keys corresponding to each bank are provided for selecting a specific data bank and connecting it to the bank combination device. At the same time, the multiplexers are designed to bring the transmitted code sequence in accordance with a given or required signal transmission standard, and the output of the pulse code converter is formed by their output. The clock generator is configured to use either a quartz resonator or an internal RC generator to set the frequency of choice, and the pulse code converter is equipped with a device for selecting the type of generator whose output is connected to the input of the clock generator.

The invention is illustrated using graphic materials, where figure 1 schematically shows an electronic tag; figure 2 shows a functional diagram of a programmable pulse code converter; figure 3 shows a functional diagram of a memory matrix.

The graphic materials depict an electronic tag configured to generate and transmit encoded filling information for reading by portable and / or stationary reading devices (not shown in Fig.), Containing a microwave unit 1 connected to the output of a pulse code converter 2 with an autonomous power supply 3 . Pulse code converter 2 performs the generation and issuance of output "Q _out" cyclically repeating code sequence digit - 128 bits in each digit of which is formed in the Manchester code in accordance with ISO 10374 standard, it is composed of eight bits of information. Pulse code converter 2 includes a clock 4 connected to an address counter 5 with a decoder, the first outputs of which are connected to the address inputs of a memory device 6, and a signal conditioner 7. The memory programmable device 6 is a matrix of memory (binary bits (12 × 8 × 6 ×)) and is intended for input during programming and storage of full information about the object: object type, identification number, month, year of manufacture, etc. The pulse code converter 2 is equipped with a programming device 8, the output of which is connected to the information inputs of the storage device 6, multiplexers 9, a device for inputting information about the state of an object 10, connected through a protection device from “bounce” 11 to one of the inputs of a device for fixing the state of an object 12, another the input of the address of the cells of the device for fixing the state of the object 13 connected to the output of the decoder. The signal conditioner 7 is made in the form of a device for generating an object state signal and the role sum, which includes cells for fixing the checksum, the first input of the signal shaper 7 connected to the output of the address decoder of the cells of the checksum 14, the second input to the output of the storage device 6, the first output to the first inputs of the multiplexers 9, and the second output - to the first input of the binary adder 15, the second input connected to the second output of the signal conditioner 7, and the output - to the third input of the signal conditioner 7. The inputs of the address decoder of the cells of the checksum 14 and the address decoder of the cells of the mouth The device for fixing the state of the object 13 is connected to the second output of the address counter 5, the third, fourth, and fifth inputs of which are connected to the second inputs of the first, second, and third multiplexers 9 respectively. The memory device 6 is programmable and is a memory matrix (binary bits (12 × 8 × 6 ×)), the cells of which are divided into two groups, programmable separately and independently from one another, one of these groups 16 is designed to store service information intended for reading only, and d the other 17 is for user information and can be reprogrammed by him, in each of the indicated groups 16 and 17 three data banks are organized, and the storage device 6 contains a device for combining banks 18, designed to combine code sequences from the selected data banks into a single sequence, and for The keys 19 corresponding to each bank are provided for selecting a particular data bank and connecting it to the bank combination device. Multiplexers 9 are designed to bring the transmitted code sequences in accordance with a given or required signal transmission standard, and their output is the output of a pulse code converter 2. The clock generator 4 is configured to use either a quartz resonator or an internal RC generator to set the frequency of choice, while the pulse code converter is equipped with a device selecting the type of generator 20, the output of which is connected to the input of the clock generator 4.

Figure 3, which shows a functional diagram of the memory matrix of the storage device 6, shows that the full data bank (12 × 8 × 6) is divided into separate banks, 64 bits in each (8 × 8) cells.

To increase the reliability of the memory matrix of the storage device 6, it provides redundant coding according to the Hamming code, so each bank consists of (12 × 8) memory cells, thereby forming six information storage banks. The resulting memory banks are conditionally divided into two groups: three service banks 16 (SB) and three user banks 17 (BP). Banks 16 SB size (3 × 64) binary bits are designed to store information such as: type of object, affiliation, etc. Banks 17 PSUs, in sizes (3 × 64) of binary bits are intended for storing user information: the place of installation of the product on the object, installation date, installer data, etc. This division of the main memory into two types is intended to provide the possibility of separate and independent programming both in the manufacture of a pulse code converter 2 and immediately before installing an electronic tag on a protected object. In this case, the user can only view the service information in the bank 16 SB, but can not change it. To ensure this, devices have been introduced into the composition of the pulse code converter 2, which, at the end of programming of the 16 SB bank, block the possibility of changing the information in it. The code sequence from each bank is supplied to the bank combining device 18 through sequentially connected keys 19 K1-K6, respectively, from the service banks 16 SB through keys with odd numbers (K1, K3, K5), and from the banks of the user 17 BP through the keys with even numbers (K2, K4, K6). In the initial state, the bank selection control device 18 includes keys K1 and K2. The code sequence, through the above-mentioned keys and the remaining keys turned off, goes to the bank combination device 18. Upon completion of the programming of the first service bank SB1, if it is successful, the state of the key K1 is recorded. At the same time, the states of the keys K3 and K5 are recorded. Further access to other official banks is not. If the programming of the first service bank 16 SB1 failed, then the key K1 is turned off, and the key K3 is turned on. Programming of the service bank 16 SB3, etc. Upon completion of programming of the service bank 16 and fixing the state of the keys 19 with odd numbers, a code sequence from the selected service bank is received to the bank combination device 18. Information from the selected official bank can be read, but cannot be changed. Similarly, work is carried out with user banks. The main task of the device combining banks 18 is the combination of code sequences from banks for various purposes in a single code sequence. In this case, one bank with a size of 128 binary digits appears (without taking into account the redundancy due to the use of the Hamming code).

The work of the memory matrix MP of the memory device 6 is carried out under the control of the address counter 5 and decoders 13 and 14. The clock input of the address counter 5 receives the clock frequency from the output of the clock generator 4.

The clock 4 can be assembled based on an RC oscillator with internal RC elements. It is possible to use a quartz resonator connected between the terminals G ₁ and G _t . When using the internal RC generator, it is possible to work with the internal capacitor “C” and a set of built-in resistors “R _P ”, connected programmatically, or with an external resistor “R _H ”.

The formation of the code sequence is carried out using multiplexers 9: unit, zero and marker. From the output of the multiplexers 9, the generated code sequence is fed to the output of the pulse code converter 2 (“Q _out ” output, as shown in FIG. 2).

To implement the input into the output code sequence information about the state of the object in the circuit of the pulse code converter 2, the following are entered: a decoder of the cell address of the device for fixing the state of the object 13, a decoder of the address of the cells of the checksum 14, a device for inputting information about the state of the object 10, a device for fixing information about the state of the object 12 , a device for protection from “bounce” 11, a device for generating an object status signal and a checksum 7, a binary adder 15.

Bits of information about the state of the object are reserved in the output code sequence, but information about the state of the locked object is not programmed when a pulse code converter 2 is installed on the object. Thus, it is necessary to “cut out” the information about the state of the locked object from the indicated sequence and paste the current information into this place.

The address decoder of the cells of the device for fixing the state of the object 13 determines the place in the output code sequence, and the input device 10 and fixing information about the state of the object 12, having received the current information about the state of the object, enter it into the output code sequence. When sealing and locking an object, for example, using a locking and sealing device with a cable segment (not shown in Fig.), When a cable segment of a locking and sealing device passes through the housing and moves relative to the sliding contact, a transition process is possible during which information about the state of the object can arbitrarily change (“bounce”). To eliminate the influence of the transient in the pulse code converter 2, a “chatter” protection device has been introduced, which is a timer with a holding time, for example, 20 ... 60 seconds, after which information about the state of the object is recorded by input devices 10 and recording state information object 12. When biting a piece of cable, i.e. when the state of the object changes, when the transient process is absent, the information is recorded without delay on the “bounce”.

The checksum, which is the sum of all the binary bits of the code, is transmitted in the output code sequence. When changing the information in the output code sequence caused by entering additional bits of the object state, it is necessary to change the checksum. To do this, the pulse code converter 2 contains: a device for generating an object status signal and a checksum 7 and a binary adder 15. Information about the checksum is “cut out” from the output code sequence, information about the current state of the object is added to it using a binary adder 15, and the received new checksum “crashes” into the place of the previous checksum.

Figure 2 shows the conclusions of the “V _CC ” and “V _PP ” of the power device 3 and are intended for summing the supply voltage and programming, respectively. To improve the stability of the clock frequency, a voltage stabilizer (not shown) can be introduced, which converts the input voltage “V _CC ” to the operating voltage.

Thus, the invention in the presented set of features provides enhanced functionality and increased reliability of safety control, for example, of transported goods, due to the fact that it allows you to record information in the “service banks” of memory in the production environment, and record additional information in operating conditions. After recording service and additional information, re-entering information into the service bank and the user’s bank is excluded; to protect the input information, checksums are generated at the same time as input, which allows checking the correctness of the read information. When used with cable locking and sealing devices, it allows you to quickly monitor the state of the object during operation, for example, the integrity of the cable: 01 - working, not closed, 10 - working, closed, 11 - violation of the integrity of the cable segment.

Claims (2)

1. An electronic tag configured to generate and transmit encoded filling information for reading by portable and / or stationary reading devices, comprising a microwave unit connected to the output of a pulse code converter with an autonomous power source, including a clock generator connected to an address counter with a decoder, the first outputs of which are connected to the address inputs of the storage device, and a signal conditioner, characterized in that the pulse code the converter is equipped with a programming device, the output of which is connected to the information inputs of the storage device, multiplexers, an object state information input device connected through an anti-chatter device to one of the inputs of the object state fixation device, and another input of the fixation device cell address connected to the decoder output state of the object, the signal shaper is made in the form of a device for generating a signal of the state of the object and the checksum, which includes cells for fixing the checksum, and the first input of the signal generator is connected to the output of the decoder of the address of the cells of the checksum, the second input to the output of the storage device, the first output to the first inputs of the multiplexers, and the second output to the first input of the binary adder, the output of which is connected with the third input of the signal conditioner, the inputs of the address decoder of the cells of the checksum and the address decoder of the cells of the device for fixing the state of the object are connected to the second output of the address counter, address account The IR is connected to the second inputs of the first, second and third multiplexers, the storage device is programmable and is a memory matrix, the cells of which are divided into two groups, programmable separately and independently from one another, one of these groups is designed to store service information intended only for readings, and the other for user information and can be reprogrammed once by him, in each of these groups three data banks are organized, and the storage device it contains a bank combining device for combining code sequences from selected data banks into a single sequence, and for selecting a particular data bank and connecting it to the bank combining device, keys corresponding to each bank are provided, while multiplexers are designed to bring the transmitted code sequence in accordance with a predetermined or required signal transmission standard, and their output is the output of a pulse code converter. 2. The electronic tag according to claim 1, characterized in that the clock generator is configured to use either a quartz resonator or an internal RC generator to set the frequency of choice, while the pulse code converter is equipped with a device for selecting the type of generator, the output of which is connected to the input clock generator.

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