WO2012002103A1 - Function-supplementing integrated circuit and integrated circuit system, and medical instruments using same - Google Patents

Abstract

Provided are a function-supplementing integrated circuit and an integrated circuit system, for which cost reduction is possible, and medical instruments using same. The disclosed integrated circuit (110) is used in at least one of a plurality of medical instruments (10) and supplements some of the functions of a common processor (100) that is used by each of the plurality of medical instruments (10). Said integrated circuit comprises processor monitors (111, 112, 114) that, when a problem observation signal indicating a processor problem is received from the processor, stop said supplemented functions and moves the medical instruments into a safety state and a problem-detection signal transmitter (118) that transmits a problem-detection signal to the processor to cause the processor to detect problems in the integrated circuit.

Description

Function-complementary integrated circuit, integrated circuit system, and medical device using these

The present invention relates to a function-complementary integrated circuit, an integrated circuit system, and a medical device using these.

Conventionally, an internal circuit of a medical device has been configured by hybrid mounting electronic components such as a microcomputer and an operational amplifier on a wiring board.

A technique described in the following document (Patent Document 1) is a technique for realizing a reduction in the cost of a component by integrating a plurality of components on a single integrated circuit (one-chip).

Japanese Patent Laid-Open No. 2001-212098

However, since the integrated circuit made into one chip by the above-mentioned conventional technology is customized as a dedicated component for one device, it is a common component to be mounted on other devices having different functions required for the integrated circuit to be used. Cannot be used. For this reason, there exists a problem that the further cost reduction by sharing components in a some apparatus cannot be implement | achieved.

The present invention has been made to solve such a problem, and an object thereof is to realize further cost reduction of medical device parts and medical devices using the same.

In order to solve the above-described problems, a function-complementary integrated circuit according to the present invention is used in at least one of a plurality of medical devices, and complements some functions of a common processor used for each of the plurality of medical devices. An abnormality detection signal transmission unit that transmits an abnormality detection signal for detecting an abnormality of the integrated circuit to the processor, and the abnormality detection signal that indicates the abnormality of the processor is received from the processor. A processor monitoring unit that stops some functions and controls the medical device to the safe side.

In addition, an integrated circuit system according to the present invention is used in at least one of a plurality of medical devices, and a function-complementary integrated circuit that supplements some functions of a common processor used for each of the plurality of medical devices; And a processor having the function supplemented by the function complementing integrated circuit, wherein the function complementing integrated circuit complements the processor when receiving an abnormality monitoring signal indicating an abnormality of the processor from the processor. Monitoring unit for controlling the medical device to the safe side, an abnormality detection signal transmission unit for transmitting an abnormality detection signal for detecting an abnormality of the function-complementary integrated circuit to the processor, and an abnormality detection signal An abnormality detection signal receiving unit for receiving an abnormality detection signal transmitted by the processor when the processor detects an abnormality in the function-complementary integrated circuit, and an abnormality A shutoff control signal output unit that outputs a shutoff control signal used to shut off a control signal supplied to the medical device in order to supplement the partial function when the intelligent signal receiving unit receives the abnormality detection signal; The processor includes an abnormality monitoring signal transmission unit that transmits an abnormality monitoring signal indicating an abnormality of the processor, and a safety control unit that controls the medical device to the safe side when an abnormality of the function-complementary integrated circuit is detected, Have

Also, the medical device according to the present invention uses the above-described function-complementary integrated circuit or the above-described integrated circuit system.

According to the function-complementary integrated circuit or integrated circuit system according to the present invention, a processor used for a plurality of medical devices is customized and shared, and a highly functional device is customized to supplement a part of the functions of the processor. Function-complementary integrated circuits are used in combination with processors. Further, the processor and the function-complementary integrated circuit are monitored for abnormalities, and when an abnormality occurs, the medical device is controlled to the safe side. As a result, it is possible to reduce the total cost of medical equipment because it is possible to share parts of multiple medical equipment, reduce the number and size of parts, reduce development man-hours, and reduce redesign risk. it can. In addition, the reliability and safety of the medical device can be improved.

It is a figure which shows the functional block diagram of a syringe pump and an infusion pump among the medical devices which concern on embodiment of this invention. It is a figure which shows the functional block diagram of a blood glucose meter and a blood pressure meter among the medical devices which concern on embodiment of this invention. It is a block diagram which shows the connection relationship of a processor, a gate array, and a peripheral device among the components of the medical device which concerns on embodiment of this invention, and the timing chart of the control signal of these peripheral devices. It is a block diagram which shows the connection relationship of a processor, a gate array, and a peripheral device among the components of the medical device which concerns on this embodiment when a processor is abnormal, and the timing chart of the control signal of a peripheral device. It is a block diagram which shows the connection chart of a processor, a gate array, and a peripheral device among the components of the medical device which concerns on this embodiment when a gate array is abnormal, and the timing chart of the control signal of a peripheral device. It is a block diagram which shows the connection relation of the processor of the component of the conventional medical device, a discrete element group, and.

Hereinafter, with reference to the drawings, a function-complementary integrated circuit, an integrated circuit system, and a medical device using these will be described in detail.

FIG. 1 is a functional block diagram of a syringe pump and an infusion pump in the medical device according to the present embodiment.

FIG. 2 is a functional block diagram of a blood glucose meter and a blood pressure meter among the medical devices according to the present embodiment.

In FIGS. 1 and 2, some functional blocks of the medical device are omitted.

Syringe pumps are medical devices whose main purpose is to perform nutritional supplementation and blood transfusion for patients, chemotherapeutic agents and anesthetics for a long period of time with high accuracy in intensive care units (ICU). The chemical flow control is superior to other types of pumps.

An infusion pump is a medical device that continuously administers a drug at a set amount of infusion per hour, and is used when, for example, it is desired to accurately infuse a patient after surgery.

The blood pressure monitor is a medical device that measures human blood pressure, and the blood glucose meter is a medical device that measures human blood glucose level.

As shown in FIGS. 1 and 2, the same processor 100 is commonly used for the medical devices 10 and 11 according to the present embodiment.

1 and 2, when a signal (hereinafter referred to as “detection signal”) detected by a sensor 120 provided in each of the medical devices 10 and 11 is input to the processor 100, the detection signal is received by the processor 100. The signal is amplified by the amplification unit 101 having the same. Here, the processor 100 may include the amplification unit 101 and other elements. However, the processor 100 may be configured by only a CPU (Central Processing Unit) 102, and the amplification unit 101 and other elements may be configured by separate chips.

The sensor 120 includes an occlusion pressure sensor when the medical device 10 is a syringe pump and an infusion pump, a pressure sensor and a microphone when the medical device 11 is a blood pressure monitor, and a blood glucose sensor when the medical device 11 is a blood glucose meter. Is applicable.

The CPU 102 included in the processor 100 performs an operation based on the amplified detection signal, calculates a detection result, and controls the medical devices 10 and 11.

The detection result by the sensor 120 is recorded in the flash memory 150 provided in the medical devices 10 and 11 and can be displayed on an LCD (Liquid Crystal Display) 140. Further, when it is determined that the measurement is completed or when an abnormality is detected, the buzzer 130 provided in the medical devices 10 and 11 is sounded, and the LED (Light Emitting Diode) 170 is controlled to be turned on or blinking.

When the medical device 10 is a syringe pump or an infusion pump, a motor 160 that drives a pump (not shown) is controlled based on the detection result of the sensor 120.

As shown in FIG. 1, the syringe pump and the infusion pump that are the medical devices 10 according to the present embodiment use a gate array (function-complementary integrated circuit) 110 together with a processor 100.

Generally, the processor 100 used for the syringe pump and the infusion pump is required to have a relatively high arithmetic processing capability and a high function. On the other hand, the processor 100 used for the sphygmomanometer and the blood glucose meter does not need to be as sophisticated as the processor 100 used for the syringe pump and the infusion pump. For this reason, if it is going to achieve the function of all the four medical devices 10 and 11 mentioned above by the same processor 100, the function of the processor 100 must be matched with a syringe pump and an infusion pump, and is used for a blood pressure meter and a blood glucose meter. In that case, the processor 100 is over spec. That is, the chip size of the processor 100 is increased, and it becomes difficult to reduce the component cost.

Therefore, in the present embodiment, the processor 100 used in common for the medical devices 10 and 11 is assumed to have a relatively low function sufficient to achieve the functions of the blood pressure monitor and the blood glucose meter. And when the processor 100 is used for a syringe pump and an infusion pump, the processor 100 and the gate array 110 are connected. That is, for example, the gate array 110 is supplemented with the function of the processor 100 by causing the gate array 110 to control peripheral devices that require relatively high arithmetic processing capability for the control, such as the motor 160 and the LCD 140.

The processor 100 and the gate array 110 are connected to each other to constitute an integrated circuit system that realizes a high function or a plurality of functions.

On the other hand, as shown in FIG. 2, the gate array 110 is not used for the blood glucose meter and the blood pressure monitor that are the medical device 11 according to the present embodiment.

As described above, the medical devices 10 and 11 according to the present embodiment use the gate array 110 in accordance with their functions. The gate array 110 is configured to complement some functions of the processor 100.

The gate array 110 may be, for example, a gate array that is customized by changing a wiring (for example, an aluminum master slice method), or a gate array that is programmable and customized by writing or rewriting a logic circuit (for example, An FPGA (Field Programmable Gate Array) may be used.

As described above, according to the medical devices 10 and 11 according to the present embodiment, the processor 100 used for the plurality of medical devices 10 and 11 is customized and shared, and a part of the processor 100 is used for a highly functional device. A customized gate array 110 that complements these functions is used in conjunction with the processor 100. As a result, it is possible to share the parts of the plurality of medical devices 10 and 11, reduce the number of parts and the size of the parts, reduce the development man-hours, and reduce the redesign risk due to the suspension of production of general-purpose products. , 11 can reduce the total cost.

Further, according to the medical devices 10 and 11 according to the present embodiment, even if the functions of some of the components of the platform integrated circuit 100 are configured to have relatively low functions, higher functions than the functions are required. The scope of application can be expanded to the measuring device to be used. For this reason, parts costs can be further reduced by the mass production effect.

In order to improve the chip size reduction effect, the processor 100 and the gate array 110 may be configured by a full custom ASIC (Application Specific Integrated Circuit), or may be configured by a semi-custom standard cell.

FIG. 3 is a block diagram showing a connection relationship between a processor, a gate array, and peripheral devices among components of the medical device according to the embodiment of the present invention, and a timing chart of control signals of these peripheral devices.

The components of the medical device 10 according to this embodiment shown in FIG. 3 are elements relating to the fail-safe function of the syringe pump and the infusion pump. The fail-safe function is a function that always controls the medical device 10 to the safe side when an abnormality occurs in the medical device 10.

The processor 100 includes a WDT (Watch Dog Timer, abnormality monitoring signal transmission unit) 103, a fail safe control unit (safety control unit, second alarm control signal output unit) 104, and a serial communication unit 105.

The WDT 103 is a timer for monitoring the normal execution state of the program in the processor 100. The WDT 103 outputs a count-up signal (pulse signal) when the processor 100 is normal, and outputs a constant DC signal without outputting the count-up signal when the processor 100 is abnormal. The output signal of the WDT 103 is referred to as an abnormality monitoring signal.

The fail safe control unit 104 is a signal for stopping the motor 160, a signal for sounding the buzzer 130, and a signal for lighting or blinking the LED 170 (hereinafter referred to as "fail safe control signal") when the gate array 110 is abnormal. Output). The fail safe control unit 104 controls the medical device 10 to the safe side by stopping the motor 160 when the gate array 110 is abnormal.

The serial communication unit 105 transmits / receives verification test data for detecting an abnormality of the gate array 110 to / from the serial communication unit 118 of the gate array 110. The verification test data is transmitted / received by serial data, but may be performed by parallel data. The serial communication unit 105 detects an abnormality of the gate array 110 by a verify test, and transmits data notifying the abnormality of the gate array 110 to the fail safe control unit 104. The verification test will be described later.

The gate array 110 includes a WDT monitoring unit (processor monitoring unit) 111, a fail safe control unit (processor monitoring unit, an alarm control signal output unit, a first alarm control signal output unit) 112, a self-diagnosis unit (an abnormality detection signal transmission unit). ) 113, switch 114, motor control unit 115, buzzer control unit 116, LED control unit 117, serial communication unit (abnormality detection signal transmission unit, abnormality detection signal reception unit) 118, and cutoff control signal output unit 119.

The WDT monitoring unit 111 receives the abnormality monitoring signal from the WDT 103, and thereby monitors the processor 100. Further, the abnormality of the processor 100 is detected based on the abnormality monitoring signal. The fail safe control unit 112 outputs a fail safe control signal. When the processor 100 is abnormal, the switch 114 is switched so that the fail safe control signal generated by the fail safe control unit 112 is output from the gate array 110. Note that the fail-safe control signal generated by the fail-safe control unit 112 of the gate array 110 may be the same as the fail-safe control signal generated by the fail-safe control unit 104 of the processor 100.

The self-diagnosis unit 113 determines the abnormality of the gate array 110 by itself, and when abnormal, transmits a signal (an abnormality detection signal) for causing the processor 100 to detect the abnormality of the gate array 110. For example, the self-diagnosis unit 113 determines an abnormality in which the internal power supply voltage drops below a threshold value, or an abnormality in which a control pulse of the motor 160 is detected even though the stop key of the medical device 10 is input. May be.

When the processor 100 is normal, the switch 114 is configured so that a normal control signal (hereinafter referred to as “normal control signal”) for peripheral devices generated by the motor control unit 115, the buzzer control unit 116, and the LED control unit 117 is the gate array 110. The input signal is switched based on the control signal from the WDT monitoring unit 111. The switching state of the switch 114 shown in FIG. 3 indicates the normal state of the processor 100.

Further, the switch 114 outputs an input signal based on a control signal from the WDT monitoring unit 111 so that a fail safe control signal generated by the fail safe control unit 112 is output from the gate array 110 when the processor 100 is abnormal. Switch.

The motor control unit 115 outputs a control signal for normally controlling the motor 160. The buzzer control unit 116 outputs a control signal for preventing the buzzer 130 from ringing, and the LED control unit 117 outputs a control signal for preventing the LED 170 from lighting. The timing chart of the control signals of the motor 160, the buzzer 130, and the LED 170 shown in FIG. 3 shows the control signals of the peripheral devices supplied to the peripheral devices when both the processor 100 and the gate array 110 are normal.

The serial communication unit 118 is an interface for the gate array 110 to perform serial communication with the processor 100, and has a storage device that temporarily stores received data.

The processor 100 (specifically, the serial communication unit 105 of the processor 100) detects an abnormality of the gate array 110 by performing a verification test on the serial communication unit 118. That is, the processor 100 writes data to an arbitrary address of the storage device of the serial communication unit 118, then reads the data written from the same address (transmits it from the gate array 110 to the processor 100), and reads the written data. The data (abnormality detection signal) is collated, and the abnormality of the gate array 110 is detected when they do not match. Here, as a result of the verification test, the processor 100 can detect not only the verification error but also the failure of communication with the gate array 110 as an abnormality of the gate array 110.

Furthermore, the processor 100 can detect the abnormality of the gate array 110 by receiving the abnormality of the gate array 110 from the self-diagnosis unit 113 of the gate array 110.

When the processor 100 detects an abnormality in the gate array 110, the processor 100 transmits a control signal for shutting down the gate array 110 to the serial communication unit 118. The gate array 110 that has received the control signal from the processor 100 stops the function of the activated gate array 110. Then, a control signal (hereinafter referred to as “blocking control signal”) for blocking the normal control signal supplied from the gate array 110 to the motor 160, the buzzer 130, and the LED 170 is output from the blocking control signal output unit 119.

The cutoff control signal may be an open potential signal. By using the pull-down resistor 310, a Lo level (eg, ground potential) signal can be supplied to the switch 300. However, the cutoff control signal is not limited to this, and may be a Lo level voltage signal.

The switch 300 is based on the cutoff control signal (Lo level) from the cutoff control signal output unit 119 so that when the gate array 110 is normal, the normal control signal output from the gate array 100 is supplied to peripheral devices. The input signal is switched. The switching state of the switch 300 shown in FIG. 3 indicates a normal state of the gate array 100.

Further, the switch 300 controls the control signal from the shutoff control signal output unit 119 so that the fail safe control signal generated by the fail safe control unit 104 of the processor 104 is supplied to the peripheral device when the gate array 110 is abnormal. The input signal is switched based on (Hi level).

The control signals for the motor 160, the buzzer 130, and the LED 170 will be described.

As shown in the timing chart of FIG. 3, when both the processor 100 and the gate array 110 are normal, a pulse-shaped normal control signal output from the gate array 110 is input to the motor 160. Further, since the buzzer 130 is not sounded and the LED 170 is not lit at normal time, a control signal that does not sound and light these peripheral devices is input to the buzzer 130 and the LED 170 from the gate array 110. For example, a ground potential control signal is input.

FIG. 4 shows a connection relationship between the processor 100, the gate array 110, and peripheral devices among the components of the medical device 10 according to the present embodiment when the processor 100 is abnormal, and a timing chart of control signals of the peripheral devices. FIG.

As shown in FIG. 4, when the processor 100 is abnormal and the gate array 110 is normal, the motor 160 receives a signal from the gate array 110 to control the medical device 10 to the safe side by stopping the motor 160. Entered. For example, a ground potential control signal is input. When an abnormality occurs, the buzzer 130 is sounded to notify the abnormality, and the LED 170 is turned on. Therefore, the buzzer 130 and the LED 170 are input from the gate array 110 with control signals for sounding and lighting these peripheral devices. For example, a control signal by a voltage pulse is input.

FIG. 5 shows a connection relationship among the processor 100, the gate array 110, and peripheral devices among the components of the medical device 10 according to the present embodiment when the gate array 110 is abnormal, and a timing chart of control signals for the peripheral devices. FIG.

As shown in FIG. 5, when the gate array 110 is abnormal and the processor 100 is normal, the motor 160 receives a signal for controlling the medical device 10 to the safe side by stopping the motor 160 (details). Is input from the fail-safe control unit 104) of the processor 100. For example, a ground potential control signal is input. When an abnormality occurs, the buzzer 130 is sounded to notify the abnormality, and the LED 170 is turned on. Therefore, the buzzer 130 and the LED 170 are input from the processor 100 with control signals for sounding and lighting these peripheral devices. For example, a control signal by a voltage pulse is input.

FIG. 6 is a block diagram showing a connection relationship among the processor 600, the discrete element group 610, the motor 660, the buzzer 630, and the LED 670 among the components of the conventional medical device 60.

Since the conventional medical device 60 uses a general-purpose processor 600, and the general-purpose processor 600 directly controls the motor 660, the buzzer 630, and the LED 670, the processor 600 becomes redundant in terms of function and element area. Further, since the circuit for monitoring the abnormality of the processor 600 by the output of the WDT 601 and controlling the peripheral device to the safe side at the time of abnormality is configured by the discrete element group 610, it is difficult to reduce the cost and the mounting area.

Furthermore, the conventional medical device 60 monitors the abnormality of the processor 600, but does not monitor the abnormality of the discrete element group 610. Therefore, the peripheral device is not controlled to the safe side when the discrete element group 610 is abnormal.

On the other hand, according to the medical device according to the embodiment of the present invention, a processor used for a plurality of medical devices is customized and shared, and a customized device that complements some of the functions of the processor for a high-performance device. Use a gate array with a processor. As a result, it is possible to reduce the total cost of medical equipment because it is possible to share parts of multiple medical equipment, reduce the number and size of parts, reduce development man-hours, and reduce redesign risk. it can.

In addition, according to the medical device according to the present embodiment, even if the functions of some of the components of the platform integrated circuit are configured to have a relatively low function, a measurement apparatus that requires a higher function than the function is required. The scope of application can be expanded to For this reason, parts costs can be further reduced by the mass production effect.

Furthermore, according to the medical device according to the present embodiment, the processor and the gate array are monitored for abnormalities, and when an abnormality occurs, the control of the peripheral device by the integrated circuit having the abnormality is cut off, and the medical device is operated by the normal integrated circuit. Control the equipment to the safe side. Thereby, the reliability and safety of the medical device can be improved.

As described above, the function-complementary integrated circuit, the integrated circuit system, and the medical device using these according to the embodiment of the present invention have been described, but the present invention is not limited to the above-described embodiment.

For example, in the above-described embodiment, the integrated circuit is described as being commonly used for four medical devices such as a syringe pump, an infusion pump, a blood glucose meter, and a blood pressure meter. However, the integrated circuit is commonly used for other medical devices. It may be used, and the number of medical devices commonly used is not limited.

This application is based on Japanese Patent Application No. 2010-150006 filed on June 30, 2010, the disclosure content of which is referenced and incorporated as a whole.

10, 11 Medical equipment,
100 processors,
101 amplifying unit,
102 CPU,
103 WDT,
104 fail-safe control unit,
105 Serial communication unit,
110 gate array,
111 WDT monitoring unit,
112 Fail-safe control unit,
113 Self-diagnosis department,
114 switches,
115 motor controller,
116 buzzer control unit,
117 LED control unit,
118 Serial communication unit,
119 shut-off control signal output unit,
120 sensors,
130 buzzer,
140 LCD,
150 flash memory,
160 motor,
170 LED
300 switches,
310 Pull-down resistor.

Claims (10)

1. An integrated circuit that is used in at least one of a plurality of medical devices and supplements a part of functions of a common processor used for each of the plurality of medical devices,
   An abnormality detection signal transmitter for transmitting an abnormality detection signal for detecting an abnormality of the integrated circuit to the processor;
   A processor monitoring unit that stops the part of the function that is complemented when an abnormality monitoring signal indicating abnormality of the processor is received from the processor and controls the medical device to the safe side;
   A function-complementary integrated circuit comprising:
2. An abnormality detection signal receiving unit that receives an abnormality detection signal transmitted by the processor when the processor detects an abnormality of the integrated circuit based on the abnormality detection signal;
   When the abnormality detection signal receiving unit receives the abnormality detection signal, a cutoff control that outputs a cutoff control signal used to cut off a control signal supplied to the medical device in order to supplement the partial function. A signal output unit;
   The function-complementary integrated circuit according to claim 1, further comprising:
3. 3. The apparatus according to claim 1, further comprising an alarm control signal output unit that outputs an alarm control signal for causing an alarm device to generate an alarm when the processor monitoring unit receives an abnormality monitoring signal indicating an abnormality of the processor. The function-complementary integrated circuit described in 1.
4. The function-complementary integrated circuit according to any one of claims 1 to 3, wherein the plurality of medical devices are a syringe pump, an infusion pump, a blood glucose meter, and a blood pressure meter.
5. The integrated circuit is used for a syringe pump or an infusion pump, and the processor monitoring unit controls the medical device to the safe side by stopping the pump of the syringe pump or the infusion pump. Function-complementary integrated circuit.
6. A function-complementary integrated circuit that is used in at least one of a plurality of medical devices and supplements a part of functions of a common processor used for each of the plurality of medical devices;
   The processor having the partial function complemented by the function-complementary integrated circuit,
   The function-complementary integrated circuit is:
   A processor monitoring unit that stops the part of the function that is complemented when an abnormality monitoring signal indicating abnormality of the processor is received from the processor and controls the medical device to the safe side;
   An abnormality detection signal transmitter for transmitting an abnormality detection signal for detecting an abnormality of the function-complementary integrated circuit to the processor;
   An abnormality detection signal receiving unit that receives an abnormality detection signal transmitted by the processor when the processor detects an abnormality in the function-complementary integrated circuit based on the abnormality detection signal;
   When the abnormality detection signal receiving unit receives the abnormality detection signal, a cutoff control that outputs a cutoff control signal used to cut off a control signal supplied to the medical device in order to supplement the partial function. A signal output unit,
   The processor is
   An abnormality monitoring signal transmitter for transmitting an abnormality monitoring signal indicating an abnormality of the processor;
   When detecting an abnormality of the function-complementary integrated circuit, a safety control unit that controls the medical device on the safe side;
   An integrated circuit system comprising:
7. The function-complementary integrated circuit further includes a first alarm control signal output unit that outputs an alarm control signal that causes an alarm device to generate an alarm when the processor monitoring unit receives an abnormality monitoring signal indicating an abnormality of the processor. ,
   The processor further includes a second alarm control signal output unit that outputs an alarm control signal that causes the alarm device to generate an alarm when the safety control unit detects an abnormality in the function-complementary integrated circuit. The integrated circuit system according to claim 6.
8. The integrated circuit system according to claim 6 or 7, wherein the plurality of medical devices are a syringe pump, an infusion pump, a blood glucose meter, and a blood pressure meter.
9. The integrated circuit is used for a syringe pump or an infusion pump, and the processor monitoring unit of the function-complementary integrated circuit and the safety control unit of the processor make the medical device safe by stopping the pump of the syringe pump or the infusion pump. 9. The integrated circuit system according to claim 8, wherein the integrated circuit system is controlled.
10. A medical device using the function-complementary integrated circuit according to any one of claims 1 to 5 or the integrated circuit system according to any one of claims 6 to 9.

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