CN110623653A - Computer-controlled emergency system - Google Patents
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- CN110623653A CN110623653A CN201911002674.4A CN201911002674A CN110623653A CN 110623653 A CN110623653 A CN 110623653A CN 201911002674 A CN201911002674 A CN 201911002674A CN 110623653 A CN110623653 A CN 110623653A
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
- A61B5/024—Detecting, measuring or recording pulse rate or heart rate
- A61B5/0245—Detecting, measuring or recording pulse rate or heart rate by using sensing means generating electric signals, i.e. ECG signals
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- G—PHYSICS
- G08—SIGNALLING
- G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
- G08B21/00—Alarms responsive to a single specified undesired or abnormal condition and not otherwise provided for
- G08B21/18—Status alarms
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- G—PHYSICS
- G16—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
- G16H—HEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
- G16H40/00—ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices
- G16H40/20—ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices for the management or administration of healthcare resources or facilities, e.g. managing hospital staff or surgery rooms
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/50—Network services
- H04L67/52—Network services specially adapted for the location of the user terminal
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Abstract
The invention discloses a computer-controlled emergency system, which comprises a doctor real-time positioning signal transmitter, a patient position receiver, a heartbeat measurer, a patient signal transmitter, a map information storage, a matching computer and an electric power control system, wherein the doctor real-time positioning signal transmitter is connected with the patient position receiver; the matching computer is used for sending path information to the patient position receiver through operation after receiving the patient real-time positioning information transmitted by the patient signal transmitter; the invention solves the technical problem that doctors cannot help timely when patients suddenly stop the heart in the prior art.
Description
Technical Field
The invention relates to a computer control system, in particular to a computer-controlled emergency system.
Background
Sudden cardiac arrest is a very dangerous condition that can cause shock and even death in patients. Sudden cardiac arrest can occur anywhere and anytime, with a gold rescue time of 4 minutes after sudden cardiac arrest, and if not rescued for more than 10 minutes, the patient's brain may suffer irreversible damage. Cardiac arrest differs from other diseases that may cause sudden death primarily in that the rescue process is relatively simple and requires no assistance from other drugs, and that once the rescue is complete, life risks are essentially eliminated. General personnel can complete the rescue of the cardiac arrest through common training or self-learning. However, the rescue of other diseases such as stroke, asthma, acute myocarditis and the like generally requires professional training or assistance of other medicines and instruments, and the danger can be completely removed by subsequent rescue after primary rescue. Therefore, rapid rescue is the key to rescue from sudden cardiac arrest. Sudden cardiac arrest is more likely to occur in patients with a history of cardiac disease. At present, if cardiac arrest occurs suddenly in the life of a heart disease patient, a professional doctor is probably not available around the patient, and a good passer-by sometimes wants to help the patient, but how to help the patient is not known due to the lack of medical knowledge. Even after the patient was sent to the hospital after the patient was found to have cardiac arrest, many patients have damaged or died because the cardiac arrest time exceeded 10 minutes. It is also possible that a doctor or non-medical personnel knowledgeable of cardiac resuscitation may be present near the patient's onset of disease, but the doctor or non-medical personnel knowledgeable of cardiac resuscitation is not aware of the patient's cardiac arrest and does not arrive at the point of rescue. A cardiac arrest victim is likely to be effectively rescued if a nearby physician or non-medical personnel knowledgeable about cardiac resuscitation can exchange information with the cardiac arrest victim in need of such rescue within a short period of time. There is no such system in the prior art.
Therefore, there is a need for improvement of the prior art to solve the above technical problems.
Disclosure of Invention
In view of the above, the present invention provides a computer-controlled emergency treatment system, which solves the technical problem in the prior art that doctors and medical institutions are not rescued in time when sudden cardiac arrest occurs. The method is realized by the following technical scheme:
the designed computer-controlled emergency system comprises a doctor real-time positioning signal transmitter, a patient position receiver, a heartbeat measurer, a patient signal transmitter, a map information storage, a matching computer and a power control system, wherein doctors can carry the doctor real-time positioning signal transmitter and the patient position receiver in practice, patients carry the heartbeat measurer and the patient signal transmitter, the map information storage and the matching computer are arranged in a central control room capable of receiving wireless signals, and the power control system can comprise a battery, an electric wire and other equipment and provides electric energy for the whole device; the heartbeat measurer can adopt a device for measuring heartbeat in the prior art; the doctor real-time positioning signal transmitter can wirelessly transmit real-time positioning information, namely the real-time position of the doctor, to the matching computer; the heartbeat measurer carried by a patient can measure the heartbeat of a patient with heart disease or other heart diseases, the patient signal transmitter is used for transmitting real-time patient positioning information to the matching computer when the heartbeat measurer does not detect heartbeat activity for 10 seconds, namely when the patient breaks a heart disease and the heart stops beating for more than 10 seconds, the patient signal transmitter transmits the real-time patient positioning information to the matching computer so as to determine the position of the patient, the phenomenon that the heart of some people is premature is comprehensively considered, the rescue time of sudden cardiac arrest is usually within 10 minutes, so that the patient can be basically determined that the heart 10s does not beat when the heartbeat measurer does not detect the heartbeat activity for more than 10 s; the matching computer is used for calculating according to the following steps after receiving the real-time positioning information of the patient transmitted by the patient signal transmitter:
(1) acquiring real-time doctor positioning information transmitted by a real-time doctor positioning signal transmitter, and determining the position of a doctor;
(2) obtaining map information stored in a map information storage, wherein the map information can be provided by third-party software, and information such as real-time road conditions and the like can also be added into the map information;
(3) generating all paths on the map from the doctor's real-time location to the real-time location of the patient signal transmitter that transmits the patient's real-time positioning information;
(4) numbering the paths generated in the step (3) in an increasing mode according to the length of the distance, wherein the number of the path with the shortest distance is 1;
(5) the patient position receiver, which transmits the route information numbered 1 to the patient position receiver, i.e., the shortest route to the patient position to the doctor, may be provided with a display screen to visually display the map information and the route information numbered 1.
Further, the computer-controlled emergency system also comprises confirmation signal transmitters connected with the patient position receiver, wherein the doctor real-time positioning signal transmitters, the patient position receiver and the confirmation signal transmitters are all arranged in equal number and are arranged in a plurality, each confirmation signal transmitter is provided with a serial number, and the serial numbers of different confirmation signal transmitters are different; the matching computer is also used for receiving the confirmation information transmitted by the confirmation signal transmitter after completing the operation of the step (5), sending the number of the confirmation signal transmitter transmitting the confirmation information to the patient position receiver, the doctor who is closer to the position of the patient with the cardiac arrest can arrive before the position of the patient, the confirmation information is sent to the matching computer by the confirmation signal transmitter, after the matching computer sends the number of the confirmation signal transmitter which transmits the confirmation information to the patient position receiver, after a doctor who is far away from the patient and does not send confirmation information sees that another doctor has already driven to the rescue patient, the confirmation signal emitter is arranged to effectively prevent the problem that too many doctors come to rescue the sudden cardiac arrest of a patient without going to the position of the patient with the sudden cardiac arrest, and the labor amount of the doctors is reduced.
Furthermore, a computer-controlled emergency system, still include the power off switch of setting on patient's signal transmitter, power off switch is used for when power off switch disconnection, patient's signal transmitter can not launch the real-time locating information of patient, considers that the heartbeat caliber of hand-carrying provides the electric quantity through the battery usually, when changing the battery, the heartbeat caliber also can not detect the heartbeat, for patient's signal transmitter sends the signal to the matching computer when preventing to change the battery and causes the patient not suffer from the sudden cardiac arrest and inform doctor's phenomenon to take place, can be before finishing with the power off switch disconnection before changing the battery, will cut off the power off switch-on again after changing.
Further, the computer-controlled emergency system further comprises an arrival signal transmitter connected with the heartbeat measurer, when a doctor arrives at the position where the patient is located to rescue the patient, arrival information can be sent to the matching computer through the arrival signal transmitter, the matching computer is further used for sending the arrival information to the patient position receiver when the arrival information sent by the arrival signal transmitter is received after the operation of the step (5) is completed, and other doctors know that the doctor arrives at the position where the patient is located after seeing the arrival information and do not need to arrive at the position where the patient is located, so that the doctor is prevented from carrying out useless wave rushing.
Further, the matching calculation is also used for performing the calculation of the step (1), the step (2), the step (3), the step (4) and the step (5) again when the arrival information sent by the arrival signal transmitter is not received within 3 minutes after the calculation of the step (5) is completed, and when no doctor arrives at the position of the patient for rescuing the patient after the patient is in cardiac arrest for 3 minutes, the system can ask for help from nearby doctors again.
Further, a computer controlled emergency system, further comprising a patient signal receiver connected to the patient signal transmitter, wherein the matching computer is further configured to perform the following steps after the operation of step (5) is completed:
(6) the method comprises the steps of obtaining position information of all hospitals on a map information storage, wherein the information can be obtained through map software of a third party;
(7) generating all paths on the map from the location of the patient signal transmitter to the hospital location;
(8) numbering the paths generated in the step (7) in a descending manner according to the length of the distance, wherein the number of the path with the shortest distance is-1;
(9) and sending the path information with the number of-1 to a patient signal receiver, and when the patient does not have the doctor to help the patient or the doctor primarily helps the patient after the patient has suffered from the heart arrest, passers or doctors near the patient can send the patient to the hospital as soon as possible by checking the path information with the number of-1 in the patient signal receiver.
Further, the patient signal emitter is also used for automatically emitting a sound alarm when the heartbeat measurer does not measure that the heartbeat activity exceeds 10s, and can remind surrounding people to pay attention after the cardiac arrest of the patient so as to help the patient as soon as possible.
Furthermore, the computer-controlled emergency system also comprises a prompting device connected with the real-time positioning signal transmitter of the doctor, a disclaimer protocol display connected with the signal receiver of the patient and an electronic signature device connected with the disclaimer protocol display; the prompting device is used for displaying a CPR method, determining content that rescue behaviors are not legal obligations and the rescuer is not responsible for legal responsibility due to major negligence, and controlling a doctor to position the signal emitter in real time to emit signals after all the content on the prompting device is displayed; the exemption protocol device is used for displaying the contents that the clear rescue behavior is not legal obligatory and the rescuers do not bear legal responsibility due to major negligence, and the electronic signature device and the exemption protocol device are used for transmitting signals only after the contents on the exemption protocol display are all displayed, the signatures are signed on the electronic signature device and the consent of the contents displayed on the exemption protocol device is confirmed; the system can be used for CPR rescue, and non-medical personnel who hold a doctor to position a signal transmitter and a patient position receiver in real time and know CPR can also rescue the patient with sudden cardiac arrest through the system, but if an accident occurs in the rescue process, legal disputes can be caused, the prompter, the exemption protocol display and the electronic signature device are arranged to enable the sudden cardiac arrest patient and the person using the system to rescue to clearly see the non-legal obligation of the rescue behavior in advance, and the rescue person can not bear the legal liability due to serious negligence, and can confirm the patient with sudden cardiac arrest in advance, so that the possibility of legal disputes is reduced, the good-minded person can participate in rescue with confidence, rescue resources of the non-medical personnel are mobilized, and more patients with sudden cardiac arrest can be rescued.
The positive and beneficial technical effects of the invention comprise:
(1) the patient with cardiac arrest can be quickly informed to nearby doctors through the system, and the doctors can be informed no matter in hospitals or at home, so that the success rate of rescuing the patient with cardiac arrest is increased;
(2) non-medical personnel who understand CPR can also help the cardiac arrest patient through the system, and the system simultaneously mobilizes medical personnel and non-medical personnel resources to participate in the help of the cardiac arrest patient, thereby improving the probability of timely help of the cardiac arrest patient and reducing the pressure of medical institutions;
(3) the confirmation signal emitter and the arrival signal emitter are arranged, so that a doctor is prevented from carrying out useless running waves, and the waste of medical resources is reduced;
(4) the whole system has high automation degree and convenient use;
other advantageous effects of the present invention will be further described with reference to the following specific examples.
Drawings
The invention is further described below with reference to the following figures and examples:
FIG. 1 is a diagram of the apparatus and signal diagram of the present invention;
in the figure, 1, matching computer; 2. a map information storage; 3. a doctor positions a signal emitter in real time; 4. a patient position receiver; 5. a heartbeat measurer; 6. a patient signal transmitter; 7. an acknowledgement signal transmitter; 8. a patient signal receiver; 9. an arrival signal transmitter; 10. and (6) powering off the switch.
Detailed Description
Example (b): a computer controlled emergency system, as shown in figure 1, including doctor's real-time positioning signal emitter 3, patient's position receiver 4, the measurer of heartbeat 5, patient's signal emitter 6, map information storage 2, match computer 1 and electric control system, practice Chinese doctor can carry doctor's real-time positioning signal emitter 3, patient's position receiver 4 with oneself, and the patient carries the measurer of heartbeat 5, patient's signal emitter 6 with oneself, map information storage 2 and match computer 1 are set up in the central control room that can receive the wireless signal, the electric control system can include apparatuses such as the battery, electric wire, etc., provide the electric energy for the whole apparatus; the heartbeat measurer 5 can adopt a device for measuring heartbeat in the prior art; the doctor real-time positioning signal emitter 3 can wirelessly transmit real-time positioning information, namely the real-time position of the doctor, to the matching computer 1; the heartbeat measurer 5 carried by a patient can measure the heartbeat of a patient with heart disease or other heart diseases, the patient signal transmitter 6 is used for transmitting real-time patient positioning information to the matching computer 1 when the heartbeat measurer 5 does not detect heartbeat activity for 10 seconds, namely when the patient breaks heart disease and the heart stops beating for more than 10 seconds, the patient signal transmitter 6 transmits the real-time patient positioning information to the matching computer 1 so as to determine the position of the patient, the phenomenon that some people have premature heart beat is comprehensively considered, the rescue time of cardiac arrest is usually within 10 minutes, so that when the heartbeat measurer 5 does not detect heartbeat activity for more than 10 seconds, the patient can basically determine sudden cardiac arrest if the heart 10s does not beat; the matching computer 1 is used for calculating according to the following steps after receiving the real-time positioning information of the patient transmitted by the patient signal transmitter 6:
(1) acquiring real-time doctor positioning information transmitted by a doctor real-time positioning signal transmitter 3, and determining the position of a doctor;
(2) obtaining map information stored in the map information storage 2, wherein the map information can be provided by third-party software, and information such as real-time road conditions and the like can also be added into the map information;
(3) generating all paths on the map from the doctor's real-time location to the real-time location of the patient signal transmitter 6 which transmits the patient's real-time positioning information;
(4) numbering the paths generated in the step (3) in an increasing mode according to the length of the distance, wherein the number of the path with the shortest distance is 1;
(5) the patient position receiver 4 is configured to transmit the route information numbered 1 to the patient position receiver 4, that is, to transmit the shortest route to the patient position to the doctor, and the patient position receiver 4 may be configured to have a display screen for visually displaying the map information and the route information numbered 1.
In this embodiment, the computer-controlled emergency system further includes a plurality of confirmation signal transmitters 7 connected to the patient position receiver 4, the doctor real-time positioning signal transmitters 3, the patient position receiver 4, and the confirmation signal transmitters 7 are all set to be equal in number and are set to be plural, each confirmation signal transmitter 7 is provided with a serial number, and the serial numbers of different confirmation signal transmitters 7 are different; the matching computer 1 is further configured to send the number of the confirmation signal transmitter 7 for transmitting the confirmation information to the patient position receiver 4 when receiving the confirmation information transmitted by the confirmation signal transmitter 7 after the operation of the step (5) is completed, so that a doctor closer to the patient with sudden cardiac arrest can send the confirmation information to the matching computer 1 through the confirmation signal transmitter 7 before arriving at the position of the patient, and after the matching computer 1 sends the number of the confirmation signal transmitter 7 for transmitting the confirmation information to the patient position receiver 4, a doctor farther from the patient and without sending the confirmation information sees that another doctor has arrived at the rescue patient, and does not need to arrive at the position of the patient with sudden cardiac arrest, and the confirmation signal transmitter 7 is configured to effectively prevent the problem that one patient stops the heart and too many doctors arrive at the rescue, reducing the labor capacity of doctors.
In this embodiment, a computer-controlled emergency system further includes a power-off switch 10 disposed on the patient signal transmitter 6, the power-off switch 10 is configured to, when the power-off switch 10 is turned off, the patient signal transmitter 6 cannot transmit real-time positioning information of a patient, and considering that the portable heartbeat measurer 5 generally provides power through a battery, when the battery is replaced, the heartbeat measurer 5 cannot detect heartbeat, in order to prevent the patient signal transmitter 6 from sending a signal to the matching computer 1 when the battery is replaced to cause sudden cardiac arrest of the patient and notify a doctor, the power-off switch 10 may be turned off before the battery is replaced, and the power-off switch 10 may be turned on after the battery is replaced.
In this embodiment, a computer-controlled emergency system further includes an arrival signal transmitter 9 connected to the heartbeat measurer 5, and when a doctor arrives at a position where a patient is located to rescue the patient, the arrival information may be sent to the matching computer 1 through the arrival signal transmitter 9, and the matching computer 1 is further configured to send the arrival information to the patient position receiver 4 when receiving the arrival information sent by the arrival signal transmitter 9 after completing the operation in step (5), and after seeing the arrival information, other doctors know that the doctor has arrived at the position where the patient is located, and do not need to arrive at the location of the patient, so as to prevent the doctor from performing useless rush waves.
In this embodiment, the matching calculation is further configured to perform the operations of step (1), step (2), step (3), step (4) and step (5) again when the arrival information sent by the arrival signal transmitter 9 is not received within 3 minutes after the operation of step (5) is completed, and when the patient is still in cardiac arrest for 3 minutes and no doctor arrives at the patient position to help the patient, the system may ask for help from a doctor nearby again.
In this embodiment, the computer-controlled emergency system further includes a patient signal receiver 8 connected to the patient signal transmitter 6, and the matching computer 1 is further configured to perform the following operations after the operation of step (5) is completed:
(6) the position information of all hospitals on the map information storage 2 is obtained, and the information can be obtained through map software of a third party;
(7) generating all paths on the map from the location of the patient signal transmitter 6 to the hospital location;
(8) numbering the paths generated in the step (7) in a descending manner according to the length of the distance, wherein the number of the path with the shortest distance is-1;
(9) and the path information with the number of-1 is sent to the patient signal receiver 8, and when the patient does not have the doctor to help the patient or the doctor primarily helps the patient after the patient has suffered from the heart sudden arrest, passers by the patient or the doctor can send the patient to the hospital as soon as possible by checking the path information with the number of-1 in the patient signal receiver 8.
In this embodiment, the patient signal emitter 6 is further configured to automatically emit an audible alarm when the heartbeat measurer 5 does not measure that the heartbeat activity exceeds 10 seconds, so as to remind surrounding people of paying attention after the cardiac arrest of the patient, and help the patient as soon as possible.
In this embodiment, the computer-controlled emergency system further includes a prompting device connected to the doctor real-time positioning signal transmitter, a disclaimer protocol display connected to the patient signal receiver, and an electronic signature device connected to the disclaimer protocol display; the prompting device is used for displaying a CPR method, determining content that rescue behaviors are not legal obligations and the rescuer is not responsible for legal responsibility due to major negligence, and controlling a doctor to position the signal emitter in real time to emit signals after all the content on the prompting device is displayed; the exemption protocol device is used for displaying the contents that the clear rescue behavior is not legal obligatory and the rescuers do not bear legal responsibility due to major negligence, and the electronic signature device and the exemption protocol device are used for transmitting signals only after the contents on the exemption protocol display are all displayed, the signatures are signed on the electronic signature device and the consent of the contents displayed on the exemption protocol device is confirmed; the system can be used for CPR rescue, a doctor is not necessary, non-medical personnel holding the real-time positioning signal emitter of the doctor and the patient position receiver and knowing CPR can also rescue the patient with sudden cardiac arrest through the system, but if an accident occurs in the rescue process, legal disputes can be caused, the prompter, the disclaimer protocol display and the electronic signature device are arranged, so that the patient with sudden cardiac arrest and the person using the system to rescue can clearly determine the non-legal obligation of the rescue behavior in advance, the rescue person can not bear the legal liability due to serious negligence, and the patient with sudden cardiac arrest can confirm in advance, the possibility of the legal disputes is reduced, if the legal disputes occur, the nature of the rescue behavior can also be clearly determined, the good-minded person can participate in rescue with confidence, the rescue resources of the non-medical personnel are mobilized, and more patients with sudden cardiac arrest can be resc.
The implementation process comprises the following steps: a doctor or non-medical personnel who understand the heart resuscitation carries with him a real-time positioning signal transmitter 3, a patient position receiver 4 and a confirmation signal transmitter 7, the patient carries with him a heartbeat measurer 5, a patient signal transmitter 6, a patient signal receiver 8 and an arrival signal transmitter 9, the heartbeat measurer 5 can measure the heartbeat of the patient in real time, and the matching computer 1 and the map information memory 2 are arranged in a control room which can receive and send wireless signals; when the patient is in cardiac arrest, the heartbeat measurer 5 controls the patient signal transmitter 6 to transmit patient real-time positioning information to the matching computer if the patient heartbeat is not measured for more than 10 seconds, the matching computer performs calculation according to the steps (1), (2), (3), (4) and (5) and transmits path information with the number of 1 to the patient position receiver 4, nearby doctors or non-medical personnel who know cardiac resuscitation can arrive at the position of the patient as soon as possible to carry out first aid after receiving the information no matter in a hospital or at home, and the doctors or the non-medical personnel who know cardiac resuscitation can inform other doctors or the non-medical personnel who know cardiac resuscitation to not arrive any more through the confirmation signal transmitter 7 and the arrival signal transmitter 9; if no doctor or non-medical personnel who know the cardiac resuscitation arrive at the rescue patient in more than 3 minutes, the matching computer 1 repeats the operation steps and asks for help again; the matching computer 1, while sending out a help call, also obtains the information of the hospital position on the map information storage 2 and sends the path information with the number-1 to the receiver favored by the patient, and guides the good at the patient to send the patient to the hospital nearby.
Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.
Claims (8)
1. A computer controlled emergency system, characterized by: the system comprises a doctor real-time positioning signal transmitter, a patient position receiver, a heartbeat measurer, a patient signal transmitter, a map information storage, a matching computer and an electric power control system; the patient signal emitter is used for emitting real-time patient positioning information to the matching computer when the heartbeat measurer does not detect heartbeat activity for 10 seconds, and the matching computer is used for calculating according to the following steps after receiving the real-time patient positioning information emitted by the patient signal emitter:
(1) acquiring real-time doctor positioning information transmitted by a real-time doctor positioning signal transmitter;
(2) obtaining map information stored in a map information storage;
(3) generating all paths on the map from the doctor's real-time location to the real-time location of the patient signal transmitter that transmits the patient's real-time positioning information;
(4) numbering the paths generated in the step (3) in an increasing mode according to the length of the distance, wherein the number of the path with the shortest distance is 1;
(5) it sends path information numbered 1 to the patient position receiver.
2. A computer controlled emergency system according to claim 1, wherein: the doctor real-time positioning signal transmitter, the patient position receiver and the confirmation signal transmitter are all arranged in a plurality of numbers, each confirmation signal transmitter is provided with a number, and the numbers of different confirmation signal transmitters are different; and the matching computer is also used for sending the number of the confirmation signal transmitter for transmitting the confirmation information to the patient position receiver when the confirmation information transmitted by the confirmation signal transmitter is received after the operation of the step (5) is completed.
3. A computer controlled emergency system according to claim 2, wherein: the patient positioning system further comprises a power-off switch arranged on the patient signal transmitter, wherein the power-off switch is used for preventing the patient signal transmitter from transmitting the real-time positioning information of the patient when the power-off switch is switched off.
4. A computer controlled emergency system according to claim 3, wherein: and the matching computer is also used for sending the arrival information to the patient position receiver when the arrival information sent by the arrival signal transmitter is received after the operation of the step (5) is completed.
5. A computer controlled emergency system according to claim 4, wherein: and the matching calculation is also used for carrying out the calculation of the step (1), the step (2), the step (3), the step (4) and the step (5) again when the arrival information sent by the arrival signal transmitter is not received within 3 minutes after the calculation of the step (5) is finished.
6. A computer controlled emergency system according to claim 5, wherein: the matching computer is also used for carrying out the following steps after the operation of the step (5) is completed:
(6) acquiring position information of all hospitals on a map information storage;
(7) generating all paths on the map from the location of the patient signal transmitter to the hospital location;
(8) numbering the paths generated in the step (7) in a descending manner according to the length of the distance, wherein the number of the path with the shortest distance is-1;
(9) the path information is sent to the patient signal receiver with the number-1.
7. A computer controlled emergency system according to claim 6, wherein: the patient signal emitter is also used for automatically giving out an acoustic alarm when the heartbeat measurer does not measure the heartbeat activity for more than 10 s.
8. A computer controlled emergency system according to claim 7, wherein: the system also comprises a prompting device connected with the real-time positioning signal transmitter of the doctor, a disclaimer protocol display connected with the signal receiver of the patient and an electronic signature device connected with the disclaimer protocol display; the prompting device is used for displaying a CPR method, determining content that rescue behaviors are not legal obligations and the rescuer is not responsible for legal responsibility due to major negligence, and controlling a doctor to position the signal emitter in real time to emit signals after all the content on the prompting device is displayed; the exemption protocol device is used for displaying the contents that clear rescue behaviors are not legal obligations and the rescuers do not bear legal responsibility due to major negligence, and the electronic signature device and the exemption protocol device are used for transmitting signals only after the contents on the exemption protocol display are displayed, the signatures are signed on the electronic signature device and the consent of the contents displayed on the exemption protocol device is confirmed.
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