RU2105350C1 - System for personal registration of wounded casualties - Google Patents

Abstract

FIELD: information processing, in particular, devices for generation, storing, writing and reading medical registration information and for processing displaying and registration of data which include individual information carriers about injured (wounded and sick) persons. SUBSTANCE: device has central unit and individual information carriers. EFFECT: increased functional capabilities due to increased number of solved problems of sorting, diagnostics, survival prognosis, advising for time and location of emergency care of injured and keeping statistics about hospital losses. 2 dwg

Description

 The invention relates to the field of information, in particular to devices for the formation, storage, recording and reading of medical accounting information, as well as the processing, display and registration of accounting data, which includes individual information carriers (INI) about the injured (wounded and sick).

 Close analogs of IDNs are magnetic cards, IP cards, “smart” cards, which have become widespread both in financial and credit operations and in military applications, for example, as a means of identifying a soldier’s identity. In the memory of the INI it is supposed to place all official, medical, financial data, various marks, for example, on the receipt of personal weapons.

 First, cards with a magnetic bar code were used. They are simpler and cheaper than other types of media, but easier to fake. IP cards include products that have a built-in downloadable integrated memory, regardless of the presence or absence of a microprocessor in them. Reasonable cards have certain intellectual capabilities due to the presence of a microprocessor or specialized logic circuits. The most famous are the "smart" cards of foreign companies Philips, Flonik, etc. Two types of cards had microprocessors, and the third type had EPROMs controlled by a logical matrix. The Philips company card uses an 8021 microprocessor and a 16 K. EPROM. CII-HoneyWell Bull has a single-chip card based on a Motorola laptop computer with a 4 K or 8 K EPROM. Flonik offered a card that included composed of an electrically erasable reprogrammable read-only memory EEPROM with a capacity of 4 K or 6 K and a special logic matrix that allows you to perform the necessary calculations.

 "Reasonable" cards - individual carriers of accounting information for military use, together with equipment for programming and reading, were supplied by Philips (France). The card contained two ICs: an 8-bit microprocessor and an EPROM with a capacity of 16 K. The main disadvantage of a “reasonable” card was its high cost, approximately equal to 7-10 dollars at a magnetic card cost of 50 cents (at 1988 prices).

 A device for introducing electronic personal signs of military personnel in the US Army [1]. The technical means of this device are distributed at headquarters at various levels: at the level of a rifle battalion, these means include personal ID badges in an amount corresponding to the full personnel, reading units, computing facilities. Cards of the company "Datakeu" under the name "Data Key" and "Data Tag" were used as personal signs. Data Key cards, issued since 1981, are a 5 cm long hard plastic tag that contains 2 Kb of ROM. The price of the Data Key card is 4-7 dollars. Data Tag cards have similar technical specifications, but they match the standard personal badge used in the army. Cards have the same serrated edges with gold contacts in the recesses. They contain an 8-bit 8048 microprocessor from National Semiconductor Corp., which provides data flow control. Personal signs have a sampling time of 100 - 500 ms. The reading unit provides contact with the serrated edges of the plate of a personal sign. It uses contact brushes made of a gold-containing alloy, which "pass" through the contacts during write and read operations. The reader unit is coupled to a data flow control system via a serial I / O interface. As computing tools at the headquarters of the battalion used laptop computers company "Litton Data Systems". At the level of the division headquarters, the computing facilities include four microsystems similar in technical characteristics to the equipment of the battalion headquarters. These microsystems are manufactured by Micro Source. Each microsystem is based on the M600 P / H microcomputer based on the Z80 microprocessor. It includes a printer, small-sized drives on flexible and hard magnetic disks, a modem and a unit for reading data from an electronic personal sign. In size, such a microsystem corresponds to an ordinary suitcase and has a mass of 21 kg [1].

 The disadvantages of these known devices are as follows.

 US personal electronic signs are only a means of identifying a soldier’s identity and are not used because of the small amount of memory as an “electronic consultant”, who has in his memory the most important medical data about the soldier himself (information about illnesses, injuries, blood pressure, etc.) .p.), and as an "electronic history" of diseases (injuries), and also they do not provide protection against unauthorized access to recorded medical accounting information; in addition, the plastic case of personal signs does not ensure their safety from fire, and personal signs themselves cannot be used for cashless payments and settlements ("electronic money").

 The main disadvantage of the known devices is that conventional EEPROMs, pressed into plastic “smart” cards, are subject to wear due to mechanical contact between the card and the reader or programmer. However, this contact is fundamentally necessary both for data transfer and for supplying power to the EEPROM, and in cards with an internal power source from a miniature battery or a photoelectric cell, such a contact is needed for reading and writing operations.

 The main difficulties that prevented the solution of the problem as a whole were: the relatively small information capacity of single EEPROM microcircuits; the need for reliable multi-pin (in the field) connectors for connecting the EEPROM INI to PC adapters, which causes great difficulties in practice; the need to use practically all functional units of the stages of medical evacuation of personal computers (PCs), which requires high material costs and centralized power supply; the need for preliminary qualified preparation of information for recording it in the INI, and, therefore, additional staff; the need for qualified technical personnel to service the PC.

 Attempts to eliminate some of these difficulties by combining several EPROMs and creating a non-contact transition of the INI-adapter of the PC using optical and electromagnetic couplings lead to the creation of prototypes of the INI of unacceptable size, weight, cost and complexity.

 Known optical cards for recording and storing medical information / journal "Foreign military medicine", 1989, N 6, p. fifteen/. Optical holographic storage devices (OGZU) have a maximum recording density and do not require electrical contacts when recording / reading.

 Now the most widespread in the EEC countries are magnetic cards, which are equipped with microprocessors that provide a memory capacity of up to 8 KB.

 It is known that the company "Drexler technology" (USA) is developing an automated medical information system based on the optical recording of information on individual media, including the registration of x-ray images, tomograms, electrocardiograms, etc. In healthcare institutions in Western Europe and the United States, automated medical data recording systems are used that are integrated with other information systems into single, state-wide (for the EEC countries-interstate) information local and regional networks.

 The optical recording of information is based on the registration of holograms. With modern technology, one A4 page with text or graphic material is recorded on a hologram (GG) with a diameter of 2-3 mm. Taking into account the protective interval of 1 - 2 mm, a width of 15 mm can accommodate no more than 3 GG, and with a length of 50 mm - no more than 10 GG. Therefore, with such an area of INI, no more than 30 A4 pages can be recorded on one film of an optical holographic storage device (OGZU). Since the full capacity of the OGZU should be 150 pages, it is necessary to include at least 5 films in the INI. With a film thickness of 0.1 - 0.2 mm and taking into account the thickness of the walls of the INI case, the total thickness of the INI can be limited to 3 - 5 mm.

 The main disadvantages of the OGZU are the following.

 1). GG registration imposes relatively strict requirements on the recording materials in terms of resolution, sensitivity, light scattering of the material and the transfer characteristic of the material, which have a strong influence on the frequency-contrast characteristic (the dependence of the band contrast on the spatial frequency).

 2). There are restrictions on access to information, while the reproduction method is illumination with coherent light through the lens and image formation on the screen, and the recording method is the interaction of the reference beam with the object and the lens passing through it. Information recovery requires good temporal and spatial coherence.

 3). Not every image can be recorded on a Fourier hologram, since the size of the spatial spectrum of the image must coincide with the size of the hologram, and the process of recording the GG must be preceded by the process of microfilming the pages of the source information and making banners. The image on the banner relative to the original should be negative (from the point of view of the simplicity of the technology when shooting banners on film and the convenience of visual perception of information when reading). Thus, an indispensable element for recording a GG is a microfilming unit or a camera with appropriate optics and a tripod (with a frame size of 24x36 mm).

 4). It is a very difficult task to choose a storage medium, because under the given recording conditions, the operation of the INI should be carried out on the linear portion of the transition characteristic of the material, which affects the frequency-contrast characteristic that most fully describes the resolution of the recording material. Therefore, for INI, it is necessary to select a medium with a contrast as close as possible to 1 in order to obtain a sufficiently contrasting image for playback under recording conditions: the size of the GG is 2–3 mm, the size of the object (transparency) is at least 24x36 mm, and the limited linear dimensions of the ultrasound scan.

 5). The sensitivity of OGZU carriers is greater, the lower the resolution. Therefore, apparently, it is necessary to use not very sensitive materials, compensating for this by increasing the radiation intensity when recording a hologram.

 6). When applying the Fourier scheme, the most important is the choice of the type of laser, which determines the mass, dimensions and power consumption of the device for recording the GG (UGG), the time of recording the GG, the information capacity of one recording. When choosing a GG reader (USG), the choice of a laser and a display scheme are also important. From the point of view of the minimum mass, dimensions and energy consumption, it is preferable to use an infrared semiconductor laser. However, the reconstructed image is not susceptible to examination with the naked eye. When using a small-sized gas laser, a clearly visible image can be obtained, but at the same time, the mass, dimensions and energy consumption of the GH recovery device increase significantly.

7). UZG is the most complex, expensive and energy-consuming unit of the complex. The minimum thickness of the lines of letters on the photo banner with a frame size of 24x36 mm when re-shooting a page of text printed on a typewriter is approximately 30 microns. At the same time, a frequency equal to 3.3 • 10 ^-8 1 / M must be recorded on the Fourier hologram, and in order to record a GG with a diameter of 2 mm at such a spatial frequency, it is necessary to have a Fourier lens with a focal length equal to 0, 1 m. This limits the bottom dimensions of the ultrasound. Moreover, the minimum dimensions of ultrasonic scanning are limited by the required beam paths, as well as by service equipment: a mechanism for pulling a tape with banners, to move the carrier when exposing a number of GGs, and to prepare the thermoplastic carrier for exposure.

The most suitable for ultrasonic scanning is a helium-neon laser, having an output power of 1 mW at a wavelength of 0.63 μm, dimensions of 280x35x35 mm, weight 0.5 - 0.6 kg, power consumption of 10 watts. However, this laser is afraid of shock and must be provided with a suitable suspension in its design. Therefore, obviously, it will not be possible to place the main part of the ultrasonic ultrasound device in dimensions of 500x350x100 mm and weighing about 8 kg; you will need to have a separate power supply unit from the 220 V, 50 Hz or 27 V network from the onboard network, as well as with stand-alone autonomous power supply. With a power consumption of about 50-60 W, the power supply can be placed in dimensions of 200x100x100 mm with a weight of 3 kg. Thus, the ultrasonic scan includes three nodes: a camera with thermal film, a GG recording unit with a banner and a power supply, in total with a minimum weight of about 10 -12 kg and a volume of about 23 - 25 dm ³ .

eight). Fourier holograms can be restored only by light with good temporal and spatial coherence, otherwise there can be big complications. This predetermines the use of a laser light source in USG for the restoration of GG. Here again the problem arises of choosing the type of laser. If you restore the image on an open screen, then to obtain a clear image on a clear sunny day, you will need the radiation power of a stationary laser of the order of hundreds of milliwatts. In a dark room, a well-readable image can be obtained with a portable laser power of 1-10 mW, having a mass of about 0.6 kg, a volume of 0.3 dm ³ and an energy consumption of about 10 W, which virtually eliminates autonomous power supply. The use of a closed optical system that eliminates external illumination makes it possible to use the energy of a 5 g semiconductor injection laser with spherical microlenses. However, radiation with a wavelength of 0.8 - 0.9 μm is not distinguished by the human eye. Semiconductor lasers (developed by the Polyus Research Institute, Moscow), operating at a wavelength of 0.755 microns, allow you to observe the image with the naked eye in dark red colors. In the case of applying a spectrum conversion system in a USG using electron-optical converters that convert radiation at a wavelength of 0.8 - 0.9 μm, USG can be placed in a volume of 2 - 3 dm ³ with a mass of 2 - 2.5 kg and energy consumption 3-5 W with a duration of continuous operation from an autonomous power source of 4-6 hours.

 The closest in technical essence to the claimed system is the information system (IC) of the SAT 35C904 memory selected as a prototype, which has software and control means for protecting the data of the SATC704-35 memory IC, an EEPROM with a capacity of 4 kbps, with service decoders, read amplifiers, and recording buffers, blocks of access code and control, command decoder, synchronization and serial communication unit. The main difference of CAT 35C904 is the additionally introduced high-frequency input circuit, which transmits and receives data through an external inductor and converts the received energy into power, which ensures the operation of the IC. Programming, reading, and writing operations are performed in response to decryptable input data and commands. As in the previous CAT 35C704, CAT 35C904 has a programmable memory matrix, organized in 256 16-bit or 512 8-bit words. It uses the same organization commands of the same data protection scheme and the same read, write and erase commands. The IC is supplied in an unprotected version, in which any part of the memory matrix can be read and written without the help of an access code. Data and electrical power for the operation of the IC are extracted from a sinusoidal signal transmitted by the main system in the frequency range from 100 to 500 kHz. This signal enters through an inductor pressed into the card housing (INI) along with the EEPROM. The coil is connected to a high-frequency input IC circuit, through which the signal passes to internal control circuits. The output signal of a half-wave rectifier is stabilized by a parallel-type circuit generating an EEPROM programming voltage. This voltage is then supplied to a parallel stabilizer that generates a 5 V supply voltage for the IC chip logic. Data in the system is transmitted by frequency-shift keying. The gap between the inductor in the main system and the coil connected to the EEPROM is about 1 mm, depending on the transmitted power. When a signal is received, the control circuit demodulates the input data using an internal oscillator and a time base circuit. The byte-data protocol accepts a signal with a frequency of 500 kHz as a logical "1", and a signal with a frequency of 100 kHz as a logical "0". This communication protocol includes one start bit, 8 data bits, one parity bit and one stop bit. Resynchronization starts when each start bit is detected, and the chip is tuned to the frequency of the input signal during the initial power-up procedure. When the crystal begins to receive an input signal and its internal rectifier and voltage stabilizers are set to working condition, this 500-kHz signal synchronizes the internal IC oscillator with the time base of the main system. If the frequency counter overflows, an increment signal is sent to the internal frequency divider and the measurement is repeated. When the counter operates without overflow, the frequency of the internal oscillator at a data transfer rate of 9600 baud is set to the frequency of the main system with an error of less than 3%. The IC uses this tuned frequency to set the desired synchronization of the communication channel with a transmission speed of 9600 baud. After establishing synchronization, the IS transmits to the main system a signal of readiness for receiving data. The maximum allowable input signal must have a voltage of 3 V ± 10% at a current of 150 μA to 50 mA. Amplitude-modulated data is transmitted by the IC to the main system. Modulation is performed by turning on and off a MOS transistor connected in parallel with the coil, while the main system perceives the induced energy as logical "1" or logical "0". The energy stored in two external filter capacitors with a capacity of 0.1 μF is used to power the crystal during data transfer. In a write operation, the IC 35C904 first determines whether the amplitude of the programmable voltage corresponds to the required level. After checking, this voltage is supplied to the memory matrix and a programming cycle with automatic synchronization starts. At the end of programming, the IC transfers the contents of its status register to the main system, thereby indicating the end of the cycle. Thus, the rectifier and stabilizers in the 4-kbit input stages of the CAT 35C904 EEPROM convert the frequency-manipulated signals from the main system to the supply voltage of the IC, and the energy stored in the filter capacitors allows the IC to transmit amplitude-modulated signals to the main system. A connected inductor is connected to the input contacts AC + and AC- (system ground), while the latter is also externally connected to the data output contact (DO).

 The disadvantages of the known prototype device are the inability to adjust the recorded information about the change in medical credentials, in particular, about changing the diagnosis of the injured or wounded and other medical information about providing emergency medical care, the inability to display these data on the indicator, etc. The main disadvantage of the prototype is a limited scope of its application and a narrow range of tasks, which consists in the fact that it does not allow the full accounting of sanitary x losses, medical property, devices and medicines, carrying out operational and statistical analysis of the functional state of the injured and wounded, and also does not make it possible to obtain operational (in real time) and statistical information in the form of summaries and certificates of the state of medical support for emergency situations during liquidation medical consequences of natural disasters, accidents and disasters.

 The aim of the invention is to expand the functionality of the system by increasing the class of simultaneously solved problems of medical sorting, diagnostics, prediction of survival, issuing decisions on the time and place of emergency assistance to victims and compiling statistical records of sanitary losses.

 This goal is achieved by the fact that new blocks and connections are additionally introduced into the system, namely, the main subsystem additionally contains a second register, the information input of which is connected to the output of an analog-to-digital converter connected to physiological sensors, and the control input of the second register is connected to the first output of the block control unit of the reference memory, the read input of which is connected to the first output of the control unit, the first comparison unit, the first information input of which is connected to the first the formation input of the display unit — the liquid crystal display and the output of the second register, and the second information input — to the first output of the reference memory unit, an element NOT, whose input is connected to the output of the first comparison unit, a subtraction unit, the first and second information inputs of which are connected to the output of the second register and the first output of the reference memory block, respectively, and the control input is to the output of the element NOT, the second comparison block, the first and second information inputs of which are connected to the output of the subtraction block the second output of the reference memory block, respectively, the first memory block, the read input of which is connected to the counting input of the second counter and to the second output of the control unit, a group of OR elements whose outputs are connected to the address input of the first memory block, and the inputs are connected to the discharge outputs of the first and second counters, the first register, the control input of which is connected to the counting input of the first counter and the first output of the control unit, the first clock input of which is connected to the overflow output of the second counter, the second block memory, the information input of which is connected to the discharge outputs of the first counter, the recording input - with the third output of the control unit, the read input - with the fourth output of the control unit, and the output - with the installation input of the first counter, a group of memory units - individual information carriers (IDN) of each the victim, the information outputs of which through the first and second inductors of the reading unit and the reading unit (by its output) are connected to the information input of the first register, the third register, the first, second and third whose information inputs are connected to the output of the second register, the output of the first register and the output of the second comparison unit, respectively, the control input is with the fifth output of the control unit, and the output is with the information input of the first memory unit, the fourth register, the information input of which is connected to the first output of the unit data input (key terminal), the third comparison unit, the first and second information inputs are connected to the output of the fourth register and the output of the first memory block, respectively, and the output to the counted input the house of the third counter, a group of AND elements, the first inputs of which are connected to the output of the third block of comparison, and the second inputs to the output of the first memory block, the third memory block, the information input of which is connected to the outputs of the elements of the And group, the address input is to the output of the third counter, and the output is to the second information input of the liquid crystal display, and it is also the information output of the main subsystem, the fifth register, the information input of which is connected to the second output of the data input unit, and the output to the fourth information the ion input of the display-display unit, the block of AND elements, the inputs of which are connected to the outputs of the AND elements of the group, the output of the first comparison unit and the output of the third register, and the output to the fifth information input of the third register, and the second group of OR elements, the inputs of which are connected to the output block of elements And, and outputs to the inputs of the registrar.

 In FIG. 1 shows a structural-functional diagram of an individual accounting system (the restrictive part of the claims is a prototype). In FIG. 2 shows the structural and functional block diagram of an individual accounting system (a distinctive part of the claims).

 The system of individual registration and sorting of the wounded, in particular the identification and identification of victims of emergency situations, contains the main subsystem 1, which consists of interconnected information reading unit 2, high-frequency source 3, a liquid crystal display 4 - display unit, and two paired inductance coils 5, located from each other at a relatively small distance (not more than 1 mm), and the first inductor 5-1 is pressed in and connected to the input of an integrated circuit individually dual information carrier 6, and the second coil 5-2 is placed in the information reading unit 2 of the main subsystem 1, while the individual information carrier 6 (INI) includes program control data protection units 7, a matrix 8 of an electrically erasable reprogrammable read-only memory device EEPROM connected to serving decoders of rows 9 and columns 10, amplifiers 11 for reading, buffers 12 for writing, code block 13 for access and control, connected in parallel using a common bus 14 to register 15 status read amplifiers 11, the first input of address register 16, the input of the memory pointer 17, the register 18 and the synchronization-communication unit 19, while the command register 18 is aligned with the decoder unit 20 of the commands, and the output of the memory pointer 17 is connected to the second input of the address register 16 the output of which is connected to the recording buffers 12, and the synchronization-communication unit 19 is connected to the input high-frequency circuit 21, to which the first inductance coil 5-1 is connected, the internal rectifier 22 and the programming voltage circuit 23 connected to the stabilizer 24 on voltage, while the input high-frequency circuit 21 contains an internal oscillator 25, a temporary base circuit 26 for demodulating the input data, a frequency counter 27 coupled to a frequency divider 28, and a MOS transistor 29 connected in parallel to the first inductor 5-1 connected to two capacitors (0.1 μF capacitance) 30 of the filter, and the input high-frequency circuit 21 has two input contacts 31 to which the first inductance coil 5-1 is connected, two data output contacts 32, one of which is connected to the input minus 31-1 , d VA contact 33 of a constant voltage supply, in parallel with which the first filter capacitor 30-1 is connected, one terminal 34 of the output of the internal oscillator 25, one terminal 35 of the reference voltage source and one terminal 36 of the output of the programming voltage circuit, between which and a minus of the constant voltage of the power supply 30-2 filters.

 The main subsystem 1 additionally contains a second register 37, the information input of which is connected to the output of an analog-to-digital converter 38 connected to physiological sensors 39, and the control input of the second register 37 is connected to the first output of the control unit 40 (block 40 is not indicated in Fig. 2) , a reference memory unit 41, the read input of which is connected to the first output of the control unit 40, a first comparison unit 42, the first information input of which is connected to the first information input of the liquid crystal display unit 4 and the output of the second register 37, and the second information input is to the first output of the reference memory unit 41, the element is NOT 43, the input of which is connected to the output of the first comparison unit 42, the subtraction unit 44, the first and second information inputs of which are connected to the output of the second register 37 and the first the output of the reference memory unit 41, respectively, and the control input is connected to the output of the element NOT 43, the second comparison unit 45, the first and second information inputs of which are connected to the output of the subtraction unit 44 and the second output of the reference memory unit, respectively, the first memory block 46, the read input of which is connected to the counting input of the second counter 47 of the address and to the second output of the control unit 40-2, a group of OR elements 48, the outputs of which are connected to the address input of the first memory block 46, and the outputs are connected to the discharge outputs of the first 49 and second 47 address counters, the first register 50, the control input of the second is connected to the counting input of the first counter 49 and the first output of the control unit 40-1, the first clock input of which is connected to the overflow output of the second counter 47, the second memory unit 51, information the first input of which is connected to the discharge outputs of the first counter 49, the recording input is with the third output of the control unit 40-3, the read input is with the fourth output of the control unit 40-4, and the output is with the installation input of the first counter 49, the group of memory units 6 is individual information carriers (INI) of each victim, the information outputs of which through the first 5-1 and second 5-2 of the inductor, the write / read unit 2 are connected to the information input of the first register 50, the third register 52, the first, second and third information inputs of which connected to the output of the second register 37, the output of the first register 50 and the output of the second comparison unit 45, respectively, the control input is with the fifth output 40-5 of the control unit, and the output is with the information input of the first memory unit 46, the fourth register 53, the information input of which is connected to the first output of the input block (key terminal) 54, the third comparison block 55, the first and second information inputs of which are connected to the output of the fourth register 53 and the output of the first memory block 46, respectively, and the output with the counting input of the third counter 56, a group of AND elements of block 57, the first inputs of which are connected to the output of the third comparison unit 55, and the second inputs to the output of the first memory block 46, the third memory block 58, the information input of which is connected to the outputs of the AND elements of group 57, the address input is to the output of the third counter 56, and the output to the second information input of the display 4, and it is also the information output of the main subsystem, the fifth register 59, the information input of which is connected to the second output of the input unit 54, and the output to the fourth information input 52-4 tre register 52 and the third information input 4-3 of the display-display unit 4, the block of elements AND 60, the inputs of which are connected to the outputs of the elements AND of group 57, the output of the first comparison unit 42 and the output of the third register 52, and the output to the fifth information input of the third register 52, the second group of elements OR 61, the inputs of which are connected to the output of the block of elements And 60, and the outputs to the inputs of the recorder 62. The output of the first element And 63 is connected to a single input of the first trigger 64, the output of which is connected to the first pulse generator 65, the output koto The horn, which is the first output 40-1 of the control unit 40, is connected through the first delay element 66 to the zero input of the first trigger 64 and directly to the control inputs of the reference memory unit 41, the first 50, and the second 37 registers.

 The first output of the mode switch 67 is connected to the first input of the OR-NOT element 68 and the second input of the second element And 69, the first input of which is the input "Input", and the output is connected to a single input of the second trigger 70, the output of which is connected to the input of the second pulse generator 71 the output of which is the second output 40-2 of the control unit 40 and is connected to the input of the first memory unit 46. The second output of the mode switch 67, which is the third output 40-3 of the control unit 40, is connected to the second input of the OR-NOT 68 element, the input of the first element AND 63 and the input of the third element And 72. The output of the OR-NOT element 68, which is the fourth output 40-4 of the control unit 40, is connected to the input of the second memory unit 51. The output of the third element And 72 is connected to a single input of the third trigger 73, the output of which is connected to the third generator 74 single pulses, the output of which, which is the fifth output 40-5 of the control unit 40, is connected to the control input of the third register 52 and through the third delay element 75 is connected to the zero input of the third trigger 73 and the input of the first memory unit 46.

 The system of individual registration and sorting of the wounded is as follows.

 The recording mode of accounting medical information is set by the mode switch 67. The doctor-operator inserts INI 6 about the injured (wounded) into the information recording / reading unit 2, turns on the Start button on it (the button in Fig. 2 is not shown) and then an electrical signal appears which, from the output of the write / read unit 2 through the first AND element 63, opened by the recording mode signal from the mode switch 67, charges the first trigger 64 to a single state. After that, the first single pulse generator 65 is started, according to the signal of which information read from the IDN 6 is transmitted through the write / read unit 2 to the first register 50 and display 4 of the main subsystem 1. The first counter 49 of the second block address 49 is the same signal from the first pulse generator 65 51 memory is set to one, preparing the address of the first cell.

 The same signal is gated by an analog-to-digital converter ADC 38, the input of which receives analogue physiological information about the functional state of the first injured (wounded) from sensors 39 worn on it. This information, converted by ADC 38 into binary code, is written to the second register 37. С of its output, it arrives at the first block of comparison 42, the second information input of which from the block 41 of the reference memory, sequentially according to the command, the values of the "norm" of each (four of them) physiological parameters (often you have heart rate, respiratory rate, maximum blood pressure and the body temperature of the victim). If at least one of the parameters goes beyond the "norm", then the signal from the element NOT 43 determines the absolute value of the deviation of the parameter. This is done by the subtraction unit 44 by determining the difference between the current value of the parameter and the value of its “norm”. The absolute deviation arrives at the second comparison unit 45, where the gradation of the deviation, i.e., the degree of deviation, is carried out. The calibration values of the gradations of physiological parameters are stored in the block 41 of the reference memory and are constantly present on the second information input of the second block of comparison 45 (control physiological physiological channels - their switching and control block 41 of the reference memory in Fig. 2 are not shown). The doctor-operator on the display unit - display 4 can observe the actual values of the accounting and physiological parameters of the injured (wounded). After examining each victim and analyzing his indicators, the doctor makes a diagnosis and prescribes measures for the provision of emergency medical care. Then, according to the relevant code tables, he enters the required medical credentials in the INI 6 of the injured (wounded) from the terminal 54 keypad into the fifth register 59 (for example, 011001010 - this is the defeat of the victim with OB poisonous substances, 011001111 - the defeat with bacteriological weapons, 011010100 - the complication of thermal injuries , 011010011 - mental disorders of the victim, 011011011 - head injury, 011010010 - disease of the blood and blood-forming organs of the victim, etc.).

 After completing the set of required codes, the doctor presses the "Enter" key and the signal goes to the third element And 72, prepared by the recording signal from the switch 67 modes. This signal includes a third flip-flop 73, which starts the third single pulse generator 74, according to the control signal of which a third generalizing register 52 is prepared, and through the second delay element 75, the first memory block 46. The degree of deviation of physiological parameters from their "norm", the actual values of these parameters, individual account information about the injured (wounded) and the data entered by the doctor from input unit 54 are collected on the third generalizing register 52 and, according to the signal of the third generator, 74 single pulses are recorded in the first memory block 46 at the address of the first counter 49. The same information from the output of the third register 52 goes to the input of the analyzing block of elements AND 60 and the second block of the groups of elements OR 61, where a decision is made about the point (place), for example injured victim (wounded) at the stages of medical evacuation. This decision and all necessary information about the injured (wounded) can be recorded by the registrar 62. When the credentials of all injured (wounded) are processed in this way, the recording mode is turned off.

 When the recording mode is turned off, an output appears at the output of the OR-NOT 68 element, according to which the readings of the first counter 49 of the address are stored in the second memory unit 51. If the recording mode is turned on again, the value of the first register 50 is written to the first counter 49 and the recording in the memory of the first memory block 46 will continue from the address at which it was previously completed.

 The individual injured sorting system allows receiving reports, certificates of injured (wounded), for example, such as: a report on sanitary losses, a report on the movement of the wounded and sick, a certificate of admission in connection with the location and nature of the mechanical damage, a certificate of distribution and movement the wounded (sick) by type of medical institution, a certificate of the results of treatment affected by different types of weapons, etc.

 To do this, the switch 67 modes is set to "Read". The doctor types the search terms on the keyboard of the input unit 54 and presses the Enter key. The signal "Input" through the second element And 69 starts the second trigger 70, which, in turn, starts the second pulse generator 71. At the signal of the generator 71, a second address counter 47 is started and these signals of the generator 71 are fed to the read input of the first memory unit 46. A sequential reading of information from the first memory block 46 takes place. This information comes from the output of the memory unit 46 to the first information input of the third comparison unit 55, to the second information input of which search signs from the fourth register 53 are received. When the signs coincide with the desired data, the third comparison unit 55 gives a signal according to which information of this cell of the first block memory 46 through the block of the group of elements And 57 enters the block of the group of elements And 60, and also enters the information input of the third block of memory 58. Writing to the third block 58 of the memory is carried out at the address from the third a counter 56, which is triggered by a signal from a third comparison unit 55; so, inquiries, tables and summaries of the injured (wounded) are grouped and fed to the display unit — display 4, to the third memory unit 58 and to the system output. Thus, the system for sorting the wounded and individual records allows you to record, store, read, process and display medical accounting information about sanitary losses, medical property, devices and medicines; to measure and process the physiological parameters of the injured (wounded), analyze their functional state, carry out diagnostics and medical sorting of the injured (wounded and sick).

 The system of individual registration and sorting of the wounded, in particular the identification and identification of victims in emergency situations during the liquidation of the medical consequences of natural disasters, accidents and disasters, makes it possible to improve the quality of emergency medical care by obtaining operational (real-time) and statistical information in the form of all medical certificates and reports about the injured (wounded). Moreover, high-frequency inductive radio communication provides power to the EEPROM and the INI 6 circuits with medical data protection and its accounting information exchange channel with the main subsystem I without using mechanical contacts between the INI 6 and the write / read unit 2 by means of power supply, serial transmission and reception of data from the source high frequency 3. At the same time, the system allows you to automate the information and reference work of the medical service.

Sources of information
1. Marilyn A. Harris. "Tests of electronic personal signs of military personnel during military maneuvers." - Electronics, N 10. M .: Mir, 1983, p. 5 - 8.

 2. Milt Leonard. EEPROM with non-contact high frequency power and data exchange for smart credit cards. - Electronics, N 6 (811). M .: Mir, 1989, p. 81 - 83 (prototype).

Claims (1)

 An individual account and sorting system for the wounded, containing an individual information carrier, a main subsystem consisting of an information recording / reading unit, a high-frequency source, a liquid crystal display and two conjugate inductors located no more than 1 mm from each other, the first inductor it is pressed and connected to the input of the integrated circuit of an individual information carrier, and the second coil is included in the information recording / reading unit of the main subsystem, I distinguish The main subsystem contains physiological sensors connected to the input of an analog-to-digital converter, the output of which is connected to the information input of the second register, the control input of which is connected to the first output of the control unit, a reference memory unit, the read input of which is connected to the first output of the control unit , the first comparison unit, the first information input of which is connected to the first information input of the liquid crystal display unit and the output of the second register, and the second information in One to the first output of the reference memory unit, an element NOT whose input is connected to the output of the first comparison unit, a subtraction unit, the first and second information inputs of which are connected to the output of the second register and the first output of the reference memory unit, respectively, and the control input to the output of the element NOT, the second comparison unit, the first and second information inputs of which are connected to the output of the subtraction unit and the second output of the reference memory unit, respectively, the first memory unit, the read input of which is connected to the counting input the second counter, and the second output of the control unit, the first group of OR elements, the outputs of which are connected to the address input of the first memory block, and the inputs are connected to the bit outputs of the first and second counters, the first register, the control input of which is connected to the counting input of the first counter and the first output of the block control, the first clock input of which is connected to the overflow output of the second counter, the second memory block, the information input of which is connected to the discharge outputs of the first counter, the recording input with the third output ka control, read input with the fourth output of the control unit, output with the installation input of the first counter, N 1 individual storage media, the information outputs of which are connected via the write / read unit to the information inputs of the first register and the first input of the first element AND, third register, first, the second and third information inputs of which are connected to the output of the second register, the output of the first register and the output of the second comparison unit, respectively, the control input with the fifth output of the control unit, and the output the information input of the first memory block, the fourth register, the information input of which is connected to the first output of the input block, the third comparison block, the first and second information inputs of which are connected to the output of the fourth register and the output of the first memory block, respectively, and the output with the counting input of the third counter, group AND elements, the first inputs of which are connected to the output of the third comparison unit, and the second inputs to the outputs of the first memory unit, the third memory unit, the information inputs of which are connected to the electronic outputs elements AND groups of elements AND, the address input to the output of the third counter, and the output to the second information input of the liquid crystal display, it is also the information output of the main subsystem, the fifth register, the information input of which is connected to the second output of the input unit, and the output with the fourth information input of the third register and the third information input of the liquid crystal display, the block of elements And, the inputs of which are connected to the outputs of the elements AND of the group of elements And, the output of the first block of comparison and the output of the third about the register, respectively, and the output to the fifth information input of the third register, the second group of OR elements, the inputs of which are connected to the output of the block of AND elements, and the outputs to the inputs of the recorder, the output of the first AND element is connected to a single input of the first trigger, the output of which is connected to the first generator pulses, the output of which, which is the first output of the control unit, is connected through the first delay element to the zero input of the first trigger and directly to the control inputs of the reference memory unit, the first and second Registers, the first output of the mode switch is connected to the first input of the OR element AND NOT and the second input of the second AND element, the first input of which is the "Input" input of the main subsystem, and the output is connected to a single input of the second trigger, the output of which is connected to the input of the second pulse generator, the output of which is the second output of the control unit and is connected to the input of the first memory unit, the second output of the mode switch, which is the third output of the control unit, is connected to the second input of the element OR NOT, the second input of the first AND element and the first input of the third AND element, the output of the OR element, which is the fourth output of the control unit, is connected to the input of the second memory unit, the output of the third AND element is connected to the unit input of the third trigger, the output of which is connected to the third pulse generator, the output of which, which is the fifth output of the control unit, connected to the control input of the third register and through the second delay element is connected to the zero input of the third trigger and the input of the first memory unit, the second input of the third element And connected to the first output of the input block.

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