RU2072788C1 - Apparatus for controlling and restoring technical means intended for medical uses - Google Patents

Abstract

FIELD: instrument engineering. SUBSTANCE: inventively novel feature of apparatus is that staff of each enterprise comprises automated working station of metrologist responsible for checking measurement instruments, detecting and counting faulty measurement instruments 2, providing scope of work for generator of signals indicative of restoration requirements. This generator is connected to first matching unit. Metrologist's working station also comprises set-point device for testing reference input signal for analog and microprocessor means, first elements and comparator connected, all of them, to memory unit for reference data allowances. Working station further comprises adder and counter of faulty instruments 2 connected, both of them to second matching unit. Station also comprises receivers-transmitters of each enterprise, central control desk for controlling apparatus, and mobile laboratories for measuring instruments, these laboratories serving to interconnect first, second and third matching units, respectively, to central control desk. To carry out express-diagnostics, apparatus comprises units effecting rests in processors, on- line memory, fixed memory made on self-testable control LSI basis. This approach makes it possible to combine structurally test units with objects to be controlled and to made checks on principle "valid-invalid" at real frequencies, at which measuring instruments operate, thereby permitting to reliably detect not only randomly occurring failures and short-circuits, but also parametric failures. Besides, incorporation of test units 52, 96 into each standard replacement element makes it possible to quickly detect and replace faulty standard replaceable element, thus ruling out need to use sophisticated and expensive test rigs for external control of analog and digital measuring means for medical uses. EFFECT: faulty measurement means can be timely detected in each enterprise of city (region, administrative area) being serviced and process of restoring them can be controlled. 1 cl, 3 dwg

Description

 The invention relates to medical measuring equipment, in particular, to automated complexes for monitoring and restoring medical devices (TS) for medical purposes, in particular medical measuring devices (SIMS).

 Known automated control system and monitoring the health of measuring instruments (SI) (1), selected as a prototype of the claimed device. It contains monitored SI, including serially connected sensors, amplifiers, analog-to-digital and digital-to-analog converters connected to the display unit - indicator, and devices designed for checking and evaluating the operability of the SI itself.

 The main disadvantages of the known prototype system are the low metrological reliability of SI as a property of these tools to continuously maintain their normalized metrological characteristics in time within specified limits under certain operating conditions. The low metrological reliability of SI is determined by frequent failure due to untimely verification, failures and malfunctions, as well as the lack of mobile mobile laboratories of measuring equipment and automated control of the process of monitoring and recovery of SI. As a result, diagnostic and treatment-and-prophylactic complexes of medical facilities have a large number of malfunctioning and non-tested medical devices, which significantly reduces the productivity and throughput of the complex of facilities themselves, and worsens the reliability of patients undergoing medical examination. Moreover, the lack of systematic rapid control and diagnostics does not allow to identify the most in need of monitoring and restoration of CIMS objects.

 The aim of the invention is to increase the metrological reliability of medical equipment by reducing the time of their control and recovery due to automation of management and metrological support of the operation of SIMS, especially at the same time as integration, express control, tested diagnostics, periodic verification of operability, timely detection of faulty SIMNs, rational management the whole process of monitoring and restoring mobility and increasing productivity and mobile medical measurement laboratories.

 In FIG. 1 shows a block diagram of a device for monitoring and restoring medical equipment TS MN; figure 2 is a block diagram of a test structure block by the processor and ROM, made on the basis of the LSI self-test express control; figure 3 is a functional block diagram of a block of the test structure of RAM, made on the basis of the LSI self-test diagnostics SIMN.

 The device for monitoring and restoring the TS MN contains analog microprocessor-based SIMNs 2 distributed for various treatment and prophylactic objects 1, for example, multichannel electrocardiographs with microprogram control, connected by their inputs through switching unit 3 to test drivers 4 of the reference input signal, and the outputs of measuring instruments 2 are connected to the analyzer 5 reactions to tests through the first elements of 6 comparisons, the first inputs of which are connected to the direct outputs of SIMN 2, and their second inputs are connected to Exit block elements I7, a signal input coupled to the output of the reference output signal 8, the control input of which is connected to the control input I7 block elements. The central unit of the test reaction analyzer 5 is a comparison unit 9, the information inputs of which are connected to the outputs of the first comparison elements 6, the control inputs of the comparison unit 9 are connected to the memory block 10 of tolerance thresholds.

 Each object 1 additionally contains an automated workstation (AWS) 11 of the metrologist, consisting of an input / output unit 12 of information connected to the switching unit 3 and the first output of the synchronizer 13 connected to the control inputs of the block of elements I7 and the shaper 8 of the reference signals, the first input of the synchronizer 13 is connected to the keyboard 14, and its second input is connected to the input-output block 12 connected to the display 15, the recorder 16, the arithmetic-logic device 17 connected to the RAM 18 and the ROM 19 and the signal conditioner is restored 20 faulty SIMN 2, the output of which is connected to the input of the first matching unit 21. The AWP 11 also includes an adder 22, the outputs of which are connected to the outputs of the comparison unit 9 of the analyzer 5 of the reactions to the tests, the output of the adder 22 is connected to the input-output unit 12 through ROM 19 and ALU 17, to ROM 19, the fault counter 23 SIMN and the second matching unit 24. The first 21 and second 24 matching units, as well as the fault counter 23 are interconnected with the transceiver 25 AWP 11 connected via the communication line 26 to the receiver transmitter 26 CPU 28 city a (district, region, region) containing a microprocessor 29 connected via an input and indication unit 30 to a signal generator of recovery possibility 31, the inputs of which are connected to the outputs of the transceiver 27, and the outputs of the driver 31 are connected to the first inputs of the second comparison elements 32, the second inputs of which are connected via transceivers 25, 27 and the communication line 26 (the equipment of the communication line 26 is not indicated in Fig. 1) with the outputs of the first matching unit 21 AWP 1, the outputs of the second comparison elements 32 are connected to the inputs of the analyzing unit 33 and the first input of the comparator unit 34, respectively, and the output of the analyzing unit 33 is connected to the second inputs of the comparator unit 34, the outputs of which are connected to the inputs of the decoder 35, the output of which is connected through the transceiver 27 of the CPU 28 and the communication line 26 with the transceiver 36 of each mobile laboratory 37 of medical measuring equipment PLT MN, interconnected through a third matching unit 38 with a microprocessor 39, to which a display unit 40 is connected. Each asynchronous transceiver 25, 27, 36 consists of a unit a system line 41 providing parallel channel communications, a synchronization unit 42 for operating the microcircuit along a system line, a comparator 43 of addresses and control signals, a block of operating modes 44 that supports the operation of the microscom on a serial channel in various data formats, with and without parity, receiver blocks 45 and transmitter 46, including state registers 47, buffer and shift 49 of the speed selector block 50, which provides operation at different speeds of information exchange via serial channel y, as well as the production of the signal "interrupt timer" frequency of 50 Hz (timer 1 is not shown), interrupt unit 51 (the source chip comprises two interrupt vector address receiver 45 and transmitter 46 and four registers 47, 48).

 To implement built-in express control and tested diagnostics on the “fit for use” principle, typical elements for replacing microprocessors, ROM of measuring instruments 2, ROM 19 of AWP 11, microprocessors 29 of CPU 28 and microprocessors of 39 PLIT 37 include blocks of the test structure of 52 processors and ROM made on the basis of BIS 53 for self-testing express diagnostics of processors of various types, ROMs / ROMs and arbitrary logic circuits, which can be implemented, for example, on the BIS KR1828 VZh1 series. Each LSI 53 contains a control 54 of the operation of all its nodes, the operational element 55 includes an adder 56 with batteries 57 and performs all the conversion of the received data from control points 58 through a switch 59 connected to the input of the input transfer circuit 60, LSI 53 of the counter 61 of the control points 58, including LSI 53, and ROM standards 62, connected to a signature analyzer also performed on LSI 53, each of which also includes a comparator 63, comparing the results with reference values, xp arising in the ROM of standards 62, a state indication circuit 64 used to generate the test results "Yes" and "No" ("good not good") and sectional build-up LSI 53. Block 52 of the test structure MP and ROM contains the first trigger 65, connected via the first gate 66 with the output of the state indicator circuit 64 of the LSI of the signature analyzer 53. The synchronization output 67 is connected to the inputs of the LSI 53, the first 68 and the second 69 test generators, forming a 24 bit test vector (processor micro-command) together with the ROM 70. The output of the first trigger 65 connected to the information inputs of the BIS 53 of the counter 61 control points 58 and the signature analyzer 53, the first 68, the second 69 generators of text actions and ROM 70, and the control outputs of the first 68 and second 69 generators are connected through a valve 71 to the BIS 53 of the counter 61 control points, the output which is connected to the LSI 53. The information outputs of the first 68, second 69 generators and ROM 70 are connected to the test bus 72. The ROM module 73 consists of a drive 74 connected to a control unit 75 connected to the control bus 76 and the address bus 77, connected connected to the ROM drive 74 and the output of the test structure made from the address counter 78, which contains two LSI 53, and the adder 79, which also includes two LSI 53, connected to the output of the second trigger 80, connected to the third valve 81, the output of which is connected to the outputs the adder 79 "Yes" and "No", while the outputs of the address counter 78 through the data bus 82 are connected to the address bus 77, and the data bus 82 is connected to the younger and oldest LSI 53 of the adder 79. Test bus 72 of the test structure block 52 is connected to Memory of microcommands 83 and microprogram control unit 84 m of microprocessors 29, 39 and measuring instruments 2, including an arithmetic logic unit 85, an interrupt unit 86, an input / output unit 87, a timer 88, and a communication valve 89 with a trunk 90 of a microcomputer.

 The drive 91 RAM measuring instruments 2, RAM 18 AWP 11, RAM CPU 28 and PLIT 37 is connected to the highway 90 micro-computers through the SHU 92, control unit 93, SHA 94, SHD 95. Using the control bus 92, address 94, data 95 a block of the test structure of RAM 96 is connected to the drive 91 of RAM 18 of the AWP 11, which consists of three or more LSIs 97 of the built-in express diagnostics of RAM, controlled by the third trigger 98, connected to the outputs "Yes" and "No" through the fourth valve 99 .

 As LSI 97 express diagnostics of RAM 18 AWP 11, a microcircuit, for example, type КР 1828 ВЖ LSI can be used. The older LSI 97 contains a control 100 connected through the control bus 92 to the address generation element 101 connected to the address buffer 102 connected to the address bus 94, to which the middle BTS 97 and the lower LSI 97 are connected, the inputs of which are connected to the output of the third trigger 98. A data generation and analysis unit 103 is connected to the data bus 95 and connected to a data buffer 104, to which a parity control element 105 is connected, and the outputs of the address generation element 101 and the data generation and analysis unit 103 are connected to the element and indications of states 106, which form the signals of the yes and no states at their output. The blocks of the test structure 96 RAM, which carry out the built-in self-test express diagnostics, are included in the typical elements for replacing the RAM of measuring instruments 2, RAM 18 AWP 11, RAM CPU 28 and RAM PLIT 37 of the device.

 A device for monitoring and restoring medical equipment works as follows (figure 1, 2, 3).

 Verification and express diagnostics mode.

 Switching unit 3 provides a direct connection of SIMN 2 with the settings 4 of the test of analog and digital reference input signals, periodically when checking the information of the workstation 11 of the metrologist connected to the measuring means 2 using the input-output unit 12 according to the commands of the synchronizer 13. Test unit 4 generates predetermined metrological characteristics, mainly analog reference input signals, which are sent through the switching unit 3 at certain points in time to the input of the verified SIMN 2 and act on them in the form of test signals of a given amplitude and frequency, in order to obtain signals at their outputs that are subject to control by the reaction analyzer 5 to the tests. At the same time, according to the signal of the synchronizer 13, the outputs of the shaper of the reference output signals 8 are connected to the second inputs of the first comparison elements 6 through the block of elements I7. In block 9 of the comparison, the signals received from the outputs of the first comparison elements 6 are compared with the specified reference signals stored and supplied to the control input of the comparison unit 9 from the output of the memory block 10 tolerances of the analog reference thresholds.

где ΔM_j количество СМН2 j-го объекта, нуждающихся в восстановлении; kj, bj постоянные величины (bj число СИМН 2, требующих периодической поверки).The error signals SIMN 2 from the output of the comparison unit 9 are fed to the adder 22, which at its output generates a generalized signal of a malfunction of the measuring instruments, proportional to the sum of the number of elements of the comparison 6, the output signals of which exceed the specified threshold values. This fault signal SIMN 2 at the command of the synchronizer 13 is stored in the memory of the counter 23 of faulty SIMN 2. Thus, the device identifies and determines the number of failed SIMN 2 by supplying an analog reference input signal from the output of test settings 4 to the inputs of the corresponding measuring instruments 2, comparing the output the response signal of the reaction to the test of each verified SIMN 2 with a given reference output signal supplied from the output of the memory unit 10, the formation of an error signal at the output of the comparison unit 9, and when the error signal exceeds a predetermined threshold level, the adder 22 generates, and the counter 23 remembers the generalized malfunction signal of the verified measuring instruments 2. Now, with the aim of promptly recovering the faulty SIMN 2, the device generates for each j-th medical institution 1 (hereinafter referred to as object 1), where j 1, 2, 3, n, the signal (Lj) of the consumer in the restoration of faulty measuring instruments 2 in accordance with the ratio

where ΔM _{j is the} number of SMN2 of the j-th object in need of restoration; kj, bj are constant values (bj is the number of CIMS 2 requiring periodic verification).

где ΔN_i количество СИМН 2, которое может восстановить i-я ПЛИТ 37, a_i, d_i постоянные величины, задаваемые и вводимые в блок памяти 10 заранее (а_i коэффициент, пропорциональный фактической величине наличия ЗИП у i-ой ПЛИТ 37, d_i расстояние до заправочной колонки).To accomplish this task, the output signal of the counter 23 is converted by the driver 20 of the restoration signal into an equivalent signal j of the need for the recovery of faulty SIMN2 in accordance with formula (1). Next, the generated signal from the output of the driver 20 through the first matching unit 21 is fed through the transceiver 25, 27 via a communication line 26 to the input of the signal driver of the possibility of restoration 4 31 SIMN 2 of the central control panel 28 of the device. Then it is necessary to generate alarms and calls for maintenance-free PLIT MN 37 for each object, to determine for each i-th (i 1, 2, n) service-free PLIT 37 "n" signals U _ij (j 1, 2, n) proportional to the distance from this PLT 37 to each object 1 and generate for each i-th service-free PLT 37 "n" signals q _ij (j 1, 2, n) the possibilities of recovering faulty SIMN 2 in accordance with the following ratio:

where ΔN _{i is the} number of SIMN 2 that can be restored by the i-th PLIT 37, a _i , d _{i are the} constant values set and entered into the memory block 10 in advance (and _{i is a} coefficient proportional to the actual value of the availability of spare parts for the i-th PLIT 37, d _i distance to the gas station).

To solve this problem, the operator of the i-th PLIT 37 is connected in turn to each j-th counter 23 of the faulty SIMN 2, namely, it enters, using the counter 23, the value ΔN _{i of the} number of SIMN 2, which this PLIT 37 can restore, according to the formula ( 2). This happens as follows: the signal of the counter 23 of the number of SIMN 2 through the second matching unit 24 through the communication line 26 is transmitted to the CPU 28, where it is fed to the first input of the signal generator 31 of the possibility of recovering the faulty SIMN 2, on the terminals of which the signals q _{ij of the} possibility of restoring the SIMN 2, in accordance with formula (2). Moreover, the values of the distances between the objects 1 (S _ij ) and the constant values a _i and d _{i are} known in advance before the start of each cycle of the device and therefore, without much difficulty, they are entered into the shaper 31 and adjusted by the CPU manager 28 using the input unit and Indications 30 data. The magnitude of the signals (q _ij ) of the possibility of restoring the SIMN 2 and the signals (L _i ) of the need for restoring the SIMN 2 are compared using the second comparison elements 32, which form, for each service-free i-SLIT 37 "n" auxiliary control signals U _ij (where j 1,2, n) in the following ratio:
U _ij L _j q _ij , (3)
where L _j signals the need for recovery SIMN 2,
q _ij signals the possibility of recovery SIMN 2,
j 1,2, n.

Для решения этих задач, определяемых формулами (3) и (4), с выхода вторых элементов сравнения 32 соответствующие вспомогательные управляющие сигналы (U_ij) поступают на входы анализирующего элемента 33 и блока компараторов 34. Максимальный сигнал r_max поступает с выхода анализирующего элемента 33 на управляющий вход блока компараторов 34. При этом срабатывает компаратор 34 для номера "r" (формула 4), у которого maxU_ij. В результате этого на выходах блока компараторов 34 формируется соответствующий код (000. 1.0) основного сигнала управления (r_max) для i-ой ПЛИТ 37 для ее направления в r-ое учреждение 1. Этот код (единица указывает номер r-го объекта 1) преобразуется с помощью дешифратора 35 и по линии связи 26 через приемо-передатчик 36 и третий блок 38 согласования подается через микропроцессор 39 на блок отображения 40 ПЛИТ 37, представляющий собой дисплей с цифровым табло. Таким образом, на блоке отображения 40 ПЛИТ 37 высвечивается номер того объекта, куда должна прибыть освободившаяся от обслуживания ПЛИТ 37.Now it is necessary to generate the main control signal for the i-th service-free PLT 37, requiring the direction of this PLT to the r-th facility object 1 for monitoring and restoring CIMS 2 in accordance with the following ratio:

To solve these problems, defined by formulas (3) and (4), from the output of the second comparison elements 32, the corresponding auxiliary control signals (U _ij ) are fed to the inputs of the analyzing element 33 and the block of comparators 34. The maximum signal r _max comes from the output of the analyzing element 33 to the control input of the block of comparators 34. In this case, the comparator 34 for the number "r" (formula 4), which has maxU _ij . As a result of this, the corresponding code (000. 1.0) of the main control signal (r _max ) for the i-th PLIT 37 is formed at the outputs of the comparator unit 34 for its direction to the r-th institution 1. This code (unit indicates the number of the r-th object 1 ) is converted by means of a decoder 35 and through a communication line 26 through a transceiver 36 and a third matching unit 38 is fed through a microprocessor 39 to a display unit 40 of a PLIT 37, which is a display with a digital display. Thus, on the display unit 40 of the PLIT 37, the number of the object where the PLIT 37, which has been freed from service, should arrive, is displayed.

 The main program for controlling the SIMN 2 control and recovery processor is composed of subprograms by placing them at the addresses of memory block 10 and ROM 19 of the AWP 11 in the required sequence and organizing the relationship between the individual subprograms by assigning common RAM cells 18 for the input and output signals of the device blocks. The main program implements the algorithm represented by formulas (1-4).

 In the automated workstation 11 of the metrologist of each object 1, the following is carried out: storage of control and analysis algorithms of signals, storage of constants (constant values necessary for calculating the required indicators) characterizing the signs of the generated signals; the formation of synchronizing signals to control the operation of the test units 4, the analyzer of reactions 5 to tests and blocks of the workstation 11 itself; the conversion and formation of the information induced on the display 15; the formation of time delays of signals; mathematical processing of information by calculating the required data by formulas (1-4).

 Display 15 is used to control and monitor the workstation 11 of the metrologist of object 1 during its operation in the mode of automated self-control and the tested express diagnostics of the device nodes. As an information converter, an input-output unit 12 is used, which perceives the required information and converts it into digital form.

 The comparison unit 9 of the reaction analyzer 5 together with the AWP 11 performs the following operations: comparing the measured signal of the destination indicator of each SIMN 2, for example, the sensitivity of the electroencephalograph, with acceptable values; generating appropriate signals from the comparison results; generation of control signals for the CIMN 2 monitoring program based on the results of previous measurements; formation of information on the results of monitoring and diagnostics.

 ROM 19 and memory block 10 tolerances provide storage of control subroutines, all the necessary reference threshold signals and constants in binary (ROM 19) and analog (memory block 10) form, and the execution of the algorithms of the device in the control modes SIMN 2. Synchronizer 13, which controls the operation AWP 11, provides the reflection of all the information necessary for the metrologist about the results of monitoring and diagnostics, controls the operation of all units of the device of each object 1. The display 15 using the same synchronizer 13 displays all the information necessary for the metrologist about the results of monitoring and the implementation of the ability to manage the recovery process of faulty SIMN 2. The accumulation of the necessary information and documentation of the SIMN 2 monitoring results of each object 1 for their more detailed subsequent analysis using AWP 11 is made in the recorder 6. Removed from control points (tens of thousands of control points 58 may be provided) SIMN 2 analog signals with voltage up to 50 W (double amplitude value) and frequency (0-400) G fed to comparing unit 9 and the storage unit 10 for data collection. The analog signals are normalized to a voltage of 5 V, a double amplitude value, and from the output of the comparison unit 9 in transit through the adder 22 enter the ROM 19, then to the arithmetic-logic device 17, where they are compared with the permissible limits stored in the ROM 19. Structure and functional circuits block of elements I7, shaper of output reference signals 8, main blocks of AWP 11 and decoder 35 of CPU 28 are given on pages 328-330 in monograph (1).

 In the mode of exchange of information via the serial communication channel 26, asynchronous transceivers 25, 26, 36, made on the basis of the controller of external devices, provide interface requirements for radial connection of devices for serial transmission of information. They can also be used to communicate processors with remote control terminals. Each transceiver 25, 27, 36 contains four registers and two sources of addresses of the interrupt vector. The addresses of the registers of the receiver 45 and the transmitter 46 and their two vectors are interchangeable in four groups by a digital decimal code, for example, the address of the transmitter interrupt vector 46: 1st group 064, 2nd group 364, 3rd group 374, 4th group XX4. In the state register 47 of the receiver 45 of the discharge class 0-5, 8-11, 13, 14, are not used and are read as a Log. 0; bit 6 permission of the receiver 45 to interrupt; if this bit is set to Log. 1, then interruption is enabled, if to Log. 0 then forbidden. State register 47 of the transmitter 46: bit (0) line break, bit (2) operation check, bit (6) enable the transmitter to interrupt, bit (7) state flag of the transmitter 46. State register 47 of the receiver 45: bits (6), (7) for the same purpose as the transmitter 46.

 When the receiver 45 is operating, the information in the serial code is transmitted from the input of the receiver 45 to the shift register 49 and at the end of the shift it is written to the buffer register 48. In the discharge (7) of the status register 47 of the receiver 45, the receiver 45 ready flag is set. If in the discharge (6) of the register state 47, the operating condition of the channel of the receiver 45 of the microcircuit for interruption is recorded, then the output signal for the vector interruption generates an interrupt request signal. An interrupt request from the receiver 45 occurs if the bits (6) and (7) of the status register 47 of the receiver 45 are set to “1”. The request should be processed on the system line 41 by the processor 49 of the PLIT 37, as a result of which the package should be read at the address of the buffer register 48. When processing the interrupt request, the address of the receiver interrupt vector 46 is read. At the end of the reading of the package, the receiver 45 ready flag in bit (7) is reset and the receiver 45 can receive a new package. In the absence of an interrupt enable condition (bit (6) of the status register 47 of the receiver 45 contains “Log. 0”), an interrupt requirement does not arise at the output of the interrupt block 51 of the receiver 45. The microprocessor 39 PLIT 37 should work with the transceiver chip 36 in the scanning mode (periodic reading at the address) of the status register 47 of the receiver 45 and after reading the readiness flag of the receiver 45, read the package from the buffer register 48 of the receiver 45.

 The operation of the transmitter 46 is as follows. In the initial state, to the input "Power supply failure" of the operating mode block 44, the transceivers 25, 27, 36 set the status flag 47 of the transmitter 46 in the status register 47, indicating that the buffer register 48 of the transmitter 46 is empty. In the discharge (6) of the status register 47, the condition for the operation of the transmitter 46 to interrupt may or may not be recorded. The algorithm of operation of the transmitter 46 for interruption and without it is similar to the description of the operation of the receiver 45: a request for interruption from the transmitter 46 occurs if the bits (6) and (7) of the status register 47 of the transmitter are set to "1"; when processing the interrupt request, the address of the interrupt vector of the transmitter 46 is read. Information from the system trunk unit 41 is written to the address of the buffer register 48 of the transmitter 46. When the recording is completed, it is written in parallel code to the shift register 49. If there is no busy signal for the serial channel at the input of the shift register 49 of the transmitter 46 at the output of the shift register 49 through T = 1/16 of the bit duration, the signal of the transmitter 46 appears, the package is automatically pulled out of the shift register 49. With the beginning of the shift Yoke sending in the status register 47 of the transmitter 46 is set the ready flag high-level pulse signal, indicating that the buffer register 48 of the transmitter 46 even if it is possible to write new information into it.

 If the recording of new information was made during the issuance of the parcel on the communication line 26, then the new parcel will be released immediately after the end of the current parcel, i.e. after the STOP bit, the output signal-bit START of the new package appears at the output of the shift register 49 of the transmitter 46. The channel busy signal at the output of the shift register 49 affects the output of the transmitter 46 and the synchronization unit 42 of the channel of the transmitter 46. If the input of the shift register 49 is low, the channel of the transmitter 46 operates as described above.

 If a high level is applied to the input of the shift register 49, then a low STOP level is set at the output of the transmitter 46, regardless of whether the parcel is coming out or not, and the parcel is slowed down. If during the operation of a high level at the input of the shift register 49 of the transmitter 46, data is written to the buffer register 48 of the transmitter 46, then this data is not written to the shift register 49 of the transmitter 46. After the high level is removed from the input of the shift register 49, the package written to the buffer register 48 it is written into the shift register 49 and at the output of the latter through T 1/16 of the bit duration, the START bit of the given parcel appears and a new transmitter readiness flag 46 appears.

 Each transceiver 25, 27, 36 (Fig. 1) is made of LSI, for example, of type K1801 VP1-035 using p-channel MOS technology, and contains about 5000 transistors placed in a 42-output planar metal-ceramic case. The information exchange rates during the operation of transceivers 25, 27, 36 over a serial channel with a clock frequency of 4608 kHz are 50, 75, 100, 150, 200, 300, 600, 1200, 4 2400, 4800, 9600, 19200 bol. Receiving and issuing parcels are carried out in the formats of 5, 7 and 8 information bits, this ensures the formation of two-stop and one-and-a-half bits (in the format of sending 5 bits), as well as the formation and control of a parity bit (parity or oddness) and operation without a parity bit.

 The system trunk unit 41 provides communication between the parallel channel and the registers of the transceiver circuit 25, 27, 36 for writing information (addresses and data) to the registers, as well as reading information from the registers or reading interrupt vectors. The synchronization unit 42 is used to write and read information from the registers and synchronize the operation of the microcircuit along the system line. The comparator 43 addresses and control signals is designed to select the address of the registers of the chip and generate write or read signals. The block of operation modes 44 supports the operation of the microcircuit over a serial channel in various data formats, as well as with and without parity. The speed selector unit 50 provides operation of the microcircuit at different information exchange rates over the serial channel, as well as the generation of an interrupt signal by a timer with a frequency of 50 Hz.

 Self-monitoring of the internal state of the LSI and self-testing express diagnostics of the main components of the microprocessor SIMN 2 are integrated by the device through the use of D-triggers with an additional installation input, built-in self-testing blocks 52, 96 of the test structure in typical replacement elements, detected single contact faults and short circuits using tests containing several thousand input sets. The algorithm of operation of block 52 of the test structure of processors and ROM consists of an initial installation, generating a test vector and compressing the signal at control point 58. An analysis of reactions to the test influences of the first 68 and second 69 pseudorandom number generators is carried out when registering the signal values in the “M” pre-selected control points 58 on all test exposures. The T-bit sequence obtained at control points 58 is transformed during the experiment into an 8-bit signature, which is compared with the values of the reference signature. In case of coincidence with the standard, a "Yes" signal is generated; otherwise, a "No" signal is generated. The generators 68, 69 of the test actions form a 24-bit test vector micro processor instruction. Fields of microcommands with forbidden codes are formed using ROM 70 which can be addressed by a pseudo-random number generator 63, 69; the maximum number of text vectors (T) generated by generators 68, 69 of pseudo-random numbers for test actions, when using two LSI 53, is 65770. A prerequisite for testing the installation of microprocessor 29, 39 in a previously known state is an installation experiment. The reaction analysis circuit of block 52 consists of a 32-bit switch 59 control points 58, a counter 61 control points 58, a ROM 62 of reference signatures executed on a KR556 PT5 chip and an 8-bit signature analyzer made on LSI 53. The control circuit of block 52 test the structure of the MP and ROM consists of two gates 66, 71 and the block of the first trigger 65. Thus, block 52 of the test structure of the MP and ROM generates a test sequence 32 times and compares the standard 8-bit reactions with those obtained in each of the 32 control points 58.

 The block of the test structure 96 RAM 18 ARM 11, based on the BIS KR 541 RUZ, is made of several BIS 97 of the type KR1828 VZh 2. The capacity of the RAM is 64Kx18-bit layers (16 information and two control bits). For the hardware implementation of BIS 97 in the form of KR1828 VZh2 tests are selected; appeal to direct and additional addresses, proportional division, running along the digits "1" and "0". The first two tests are designed to test the drive and decryption schemes of RAM 18, the latter for the diagnosis of the information path in the form of detection of short circuits of discharge circuits.

Thus, the claimed device for monitoring and restoring medical equipment has the following advantages compared to the prototype:
allows you to inspect, certify, restore and verify during operation of measuring instruments, especially those treatment and prophylactic facilities that are most in need; provides rational control of the movement and supply of components and spare parts for mobile laboratories for medical measuring equipment;
provides accounting for the distances between mobile laboratories and serviced objects, as well as the capabilities of the PLM MN for the restoration of medical measuring instruments;
allows transmitting information to the required distances in the duplex using transceivers to significantly improve the control process of the control and recovery of medical information systems and measuring instruments, thereby reducing the recovery time by 2–3 times and thereby increasing the metrological reliability of these SIMNs;
allows detecting not only terminal malfunctions of microprocessor boards, but also a wide class of parametric failures, since the diagnosis is carried out at the operating frequency;
significantly simplifies the troubleshooting of CIMS (up to a circuit malfunction), partly such information can be obtained from the number of the control point, according to which there was a mismatch with the standard;
automates the management, technical and metrological support of the operation and repair of medical equipment, thereby reducing the staff of metrologists and repairmen of these funds by 3.5-4 times, while simultaneously increasing the productivity and throughput of medical institutions in the country.

Claims (2)

1. A device for monitoring and restoring medical equipment for medical purposes, containing measuring instruments distributed over the objects, connected by their inputs through the switching unit to the test settings of the reference input signal, and the outputs of the measuring devices connected to the analyzer of reactions to tests through the first comparison elements, the first inputs of which connected to the outputs of the measuring instruments, their second inputs are connected to the corresponding outputs of the block of elements And, the signal input of which is connected to the output of the shaper reference output signals, the control input of which is connected to the control input of the AND block, the comparison unit with thresholds, the information inputs of which are connected to the outputs of the first comparison elements, and the control inputs of the comparison unit are connected to the tolerance memory block, characterized in that automated workplaces of metrologists, consisting of a display, an input / output unit, a synchronizer, a keyboard, a recorder and an arithmetic-logical device, interconnected, soy the random-access memory and permanent memory device, which are shared with its inputs and outputs, connected to the shaper of recovery signals of faulty measuring instruments with its outputs, two other inputs connected to the recorder input and one of the synchronizer outputs, and outputs through the first matching unit with the first input and output the transceiver of the workstation, the second input and output of which through the fault counter is connected to the inputs of the adder, one group of outputs of which It is connected to a read-only memory, and the other to a second matching unit, one group of inputs and outputs of which is connected to an additional group of inputs and outputs of a tolerance memory unit, and the other to a third group of inputs and outputs of a transceiver of an automated workstation, and an input and output information unit connected to the switching unit, a synchronizer with the control inputs of the block of elements And and the driver of the reference signals, and the driver of the recovery signals of faulty measuring instruments made with the possibility of generating commands of the actual need for the restoration of measuring instruments in accordance with the ratio

where j 1,2. n;
ΔM _{j the} number of measuring instruments of the _j -th object;
K _j , b _j constants,
in addition, a central control panel for the restoration of measuring instruments of objects together with a transceiver and a communication line connected to a transceiver of an automated workstation containing a signal generator of a recovery possibility, a microprocessor with a built-in test structure according to the "fit and fail" principle, connected through the input and indication unit to the signal generator of the possibility of restoration, a mobile laboratory of measuring equipment, and the generator of possibility in sstanovleniya configured to generate n signals q _ij recoverability measuring means in accordance with the relation

where j 1,2.n;
i number of mobile laboratories for measuring equipment;
ΔN _{i is the} number of measuring instruments that can be restored i mobile laboratory measuring technology;
a _i , d _i constants,
the second comparison elements are configured to generate n control signals U _ij for each i-th mobile laboratory of measuring equipment in accordance with the ratio
U _ij L _j q _ij ,
where j 1,2, n,
L _j signals the need for the restoration of measuring instruments,
q _ij signals the possibility of recovery of measuring instruments,
wherein the analyzing unit and the comparator unit are configured to generate the main control signal of the direction of the i-th service-free mobile laboratory of the measuring equipment in the r-th object in accordance with the ratio

at the same time, the inputs of the signal generator of the possibility of restoration are connected to the outputs of the transceiver, and the outputs are connected to the first inputs of the second comparison elements, the second inputs of the second comparison elements are connected via transceivers and a communication line with the outputs of the first matching unit of the workstation, the outputs of the second comparison elements are connected to the inputs of the analyzing block and the first inputs of the comparator unit, respectively, the analyzing unit is connected to the second inputs of the comparator unit, the outputs of which They are connected to the inputs of the decoder, the output of which is connected through the transceiver of the central control panel and the communication line with the transceiver of each mobile laboratory of medical measuring equipment, interconnected through the third matching unit with the microprocessor, to which the display unit is connected.  2. The device according to claim 1, characterized in that the test settings, random access memory, read-only memory, microprocessors of measuring instruments, automated workplaces of metrologists of objects, microprocessors of the central control panel and mobile laboratories of medical measuring equipment additionally contain test blocks processor structures, read-only memory, blocks of test structures of random access memory, made on the basis of integrally th circuit, self-testing express diagnostics of processors and read-only memory, integrated circuits of self-testing express-diagnostics of random access memory, respectively, while each block of the test structure of processors and read-only memory contain the first trigger connected through the first valve to the output of the integrated state indication circuit Signature analyzer circuits based on self-test express diagnostics circuits for various types of processors If memory devices or programmable read-only memory devices and arbitrary logic circuits, the synchronization output is connected to the inputs of the first and second test generator and read-only memory, the output of the first trigger is connected to the information inputs of the counter and the integrated circuit of the signature analyzer, the first and second test generators actions and read-only memory, and the control outputs of the first and second test exposure generators are connected through the valve to the counter of control points, the output of which is connected to an integrated circuit for self-testing express diagnostics, the information outputs of the first and second generators of test influences and a read-only memory connected to the test bus, the read-only memory module consists of a drive connected to the control unit connected to the control bus and the address bus connected to the storage medium of the read-only memory device and the output of the test structure block, from an address counter containing two integrated circuits, and an adder also including two integrated circuits connected to the output of the second trigger connected to the third valve, the output of which is connected to the outputs of the adder "Yes" and "No", while the outputs of the address counter through the data bus is connected to the address bus, and the data bus is connected to the junior and senior integrated circuit of the adder, the test bus of the process test structure unit and read-only memory device is connected to the micro-command storage device and to the microprocessor microprogram control unit, including an arithmetic-logic device, an interrupt unit, an input-output unit, a timer and a communication valve with a trunk, a microcomputer, and a memory storage device for measuring instruments of an automated workstation of a mobile laboratory for measuring medical equipment is also connected to a microcomputer highway through a control bus, a control unit, an address bus, a data bus through which to the means of random access memory devices The unit of the test structure of random access memory, which consists of three or more integrated circuits of built-in express diagnostics of random access memory, is connected to the control circuits connected to the third trigger connected to the Yes and No output through the fourth valve.

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