Portable multifunctional monitor device
Technical Field
The utility model relates to a monitor device field especially relates to a portable multi-functional monitor device.
Background
Fatigue is a signal that reminds you that your body has exceeded normal load, should be adjusted and rested. Chronic fatigue syndrome is a newly discovered dangerous modern disease, and is a clinical syndrome characterized by chronic persistent or recurrent brain and physical fatigue, poor sleep quality, hypomnesis, alopecia and canities, cognitive decline, some somatic symptoms and the like. If the patient is in a fatigue state for a long time, various diseases and even sudden death can be caused.
The current monitors in the market mainly comprise large electrocardiograph monitors and portable monitors. But the monitor in the market has single function and mainly monitors the electrocardio, the blood pressure, the pulse rate and the like of a person; at present, people have great pressure in various aspects such as life, work and the like, fatigue questionnaires are investigated, people with fatigue account for 56.5 percent of the total number of people, and sudden death occurs, so that the research and development of a monitor capable of testing the fatigue degree of a human body has important significance for early prevention and treatment to reduce the occurrence of overuse death.
SUMMERY OF THE UTILITY MODEL
In order to solve the problem that exists among the prior art, the utility model provides a portable multi-functional monitor device to can predict the tiredness of human body, prevent and treat in order to reduce the dead emergence of overstrain early.
In order to realize the above purpose, the utility model provides a portable multi-functional monitor device, including the electrocardio sensor who is used for gathering human electrocardiosignal, be used for gathering human heart sound's heart sound sensor, be used for gathering human blood oxygen signal's blood oxygen sensor, be used for gathering human blood pressure signal's blood pressure sensor and be used for gathering human temperature signal's body temperature sensor, electrocardio sensor is connected with electrocardio filtering and amplifier circuit, heart sound sensor, heart sound transducer and heart sound filtering and amplifier circuit are connected gradually, blood oxygen sensor is connected with blood oxygen filtering and amplifier circuit, blood pressure sensor is connected with blood pressure filtering and amplifier circuit, body temperature sensor is connected with body temperature filtering and amplifier circuit, electrocardio filtering and amplifier circuit, heart sound filtering and amplifier circuit, blood oxygen filtering and amplifier circuit, The blood pressure filtering and amplifying circuit and the body temperature filtering and amplifying circuit are connected with an analog-digital conversion circuit, the analog-digital conversion circuit is further connected with a central processing unit, and the central processing unit is further connected with an indicator lamp, a display unit and a loudspeaker unit respectively.
Preferably, the central processing unit includes a master microprocessor and a memory.
The beneficial effects of this scheme of the utility model reside in that above-mentioned portable multi-functional monitor device can not only pass through each physiological parameter of relevant sensor monitoring human body, can calculate human tiredness numerical value through current algorithm according to the heart sound parameter moreover to show on the screen.
Drawings
Fig. 1 shows a schematic view of a monitor device according to the present invention.
Fig. 2 shows an electrocardiographic filtering and amplifying circuit diagram according to the present invention.
Fig. 3 shows a circuit diagram of the heart sound filtering and amplifying circuit according to the present invention.
Fig. 4 shows a blood oxygen filtering and amplifying circuit diagram according to the present invention.
Fig. 5 shows a blood pressure filtering and amplifying circuit diagram according to the present invention.
Fig. 6 shows a body temperature filtering and amplifying circuit diagram according to the present invention.
Fig. 7 shows an analog-to-digital conversion circuit diagram according to the present invention.
Fig. 8 shows a circuit diagram of a master microprocessor according to the present invention.
Fig. 9 shows a circuit diagram of an indicator light according to the present invention.
Fig. 10 shows a circuit diagram of a display unit according to the present invention.
Fig. 11 shows a circuit diagram of a speaker unit according to the present invention.
Reference numerals: the system comprises a 1-electrocardio sensor, a 2-electrocardio filtering and amplifying circuit, a 3-heart sound sensor, a 4-heart sound transducer, a 5-heart sound filtering and amplifying circuit, a 6-blood oxygen sensor, a 7-blood oxygen filtering and amplifying circuit, an 8-blood pressure sensor, a 9-blood pressure filtering and amplifying circuit, a 10-body temperature sensor, a 11-body temperature filtering and amplifying circuit, a 12-analog-to-digital conversion circuit, a 13-central processing unit, a 14-main control microprocessor, a 15-memory, a 16-indicator light, a 17-display unit and a 18-loudspeaker unit.
Detailed Description
The following description will further describe embodiments of the present invention with reference to the accompanying drawings.
As shown in figure 1, the utility model relates to a portable multifunctional monitor device is including the electrocardio sensor 1 that is used for gathering human electrocardiosignal, the heart sound sensor 3 that is used for gathering human heart sound, the blood oxygen sensor 6 that is used for gathering human blood oxygen signal, the blood pressure sensor 8 that is used for gathering human blood pressure signal and the temperature sensor 10 that is used for gathering human temperature signal, electrocardio sensor 1 is connected with electrocardio filtering and amplifier circuit 2, heart sound sensor 3, heart sound transducer 4 and heart sound filtering and amplifier circuit 5 are connected gradually, blood oxygen sensor 6 is connected with blood oxygen filtering and amplifier circuit 7, blood pressure sensor 8 is connected with blood pressure filtering and amplifier circuit 9, temperature sensor 10 is connected with body temperature filtering and amplifier circuit 11, electrocardio filtering and amplifier circuit 2, heart sound filtering and amplifier circuit 5, The blood oxygen filtering and amplifying circuit 7, the blood pressure filtering and amplifying circuit 9 and the body temperature filtering and amplifying circuit 11 are all connected with an analog-digital conversion circuit 12, the analog-digital conversion circuit 12 is further connected with a central processing unit 13, the central processing unit 13 comprises a main control microprocessor 14 and a memory 15, and the central processing unit 13 is further connected with an indicator light 16, a display unit 17 and a loudspeaker unit 18 respectively.
The electrocardiograph filtering and amplifying circuit 2 is configured to filter and amplify signals acquired by the electrocardiograph sensor 1, in this embodiment, the electrocardiograph sensor 1 may be an electrocardiograph sensor with a model V0014A, and the electrocardiograph filtering and amplifying circuit 2 may be an electrocardiograph filtering and amplifying circuit as shown in fig. 2.
The heart sound transducer 4 converts the signal collected by the heart sound sensor 3 into an analog signal, and the heart sound filtering and amplifying circuit 5 filters and amplifies the signal output by the heart sound transducer 4, in this embodiment, the heart sound sensor 3 may adopt a heart sound sensor with a model of HKY-06B +, and the heart sound filtering and amplifying circuit 5 may adopt a heart sound filtering and amplifying circuit as shown in fig. 3.
The blood oxygen filtering and amplifying circuit 7 is configured to filter and amplify the signal collected by the blood oxygen sensor 6, in this embodiment, the blood oxygen sensor 6 may be a pulse blood oxygen saturation sensor with a model number of S0010B-S, and the blood oxygen filtering and amplifying circuit 7 may be a blood oxygen filtering and amplifying circuit as shown in fig. 4.
The blood pressure filtering and amplifying circuit 9 is configured to filter and amplify a signal collected by the blood pressure sensor 8, in this embodiment, the blood pressure sensor 8 may adopt a pressure sensor with a model of PX260, and the blood pressure filtering and amplifying circuit 9 may adopt a blood pressure filtering and amplifying circuit as shown in fig. 5.
The body temperature filtering and amplifying circuit 11 is configured to filter and amplify a signal acquired by the body temperature sensor 10, in this embodiment, the body temperature sensor 10 may be a temperature sensor of type W0001A, and the body temperature filtering and amplifying circuit 11 may be a body temperature filtering and amplifying circuit as shown in fig. 6.
The analog-to-digital conversion circuit 12 is configured to perform analog-to-digital conversion on signals output by the electrocardiograph filtering and amplifying circuit 2, the heart sound filtering and amplifying circuit 5, the blood oxygen filtering and amplifying circuit 7, the blood pressure filtering and amplifying circuit 9, and the body temperature filtering and amplifying circuit 11, and then send the signals to the main control microprocessor 14 in the central processing unit 13, in this embodiment, the analog-to-digital conversion circuit 12 may be an analog-to-digital conversion circuit as shown in fig. 7.
The central processing unit 13 includes a main control microprocessor 14 and a memory 15, the memory 15 is used for storing relevant data, the main control microprocessor 14 is used for processing the received data, and displaying the processed result on a display unit 17, for example, displaying relevant physiological parameters and fatigue values of the human body, when the relevant physiological parameters and fatigue values of the human body are in a normal range, a green indicator light flashes, when the relevant physiological parameters or fatigue values of the human body are abnormal, a red indicator light flashes, and an alarm sound is emitted through a speaker unit 18, and the display unit 17 performs screen indication alarm. In this embodiment, the main control microprocessor 14 may be the main control microprocessor shown in fig. 8, the indicator light 16 may be the indicator light 16 shown in fig. 9, the display unit 17 may be the display unit shown in fig. 10, and the speaker unit 18 may be the speaker unit 18 shown in fig. 11.
The calculation of the fatigue value by the specific main microprocessor 14 can be implemented by using algorithms known in the prior art, for example, the main microprocessor 14 receives the heart rate collected by the heart sound sensor 3, the first heart sound S1 and the second heart sound S2 of the left upper sternum, the first heart sound S1 'and the second heart sound S2' of the right upper sternum, the diastolic time limit D and the systolic time limit S, and calculates the amplitude ratio D1 ═ S1/S2, D1 ═ S1 '/S2' and the diastolic time limit ratio D/S; then, whether the heart sound has a third heart sound is judged S3, and if the heart sound has the third heart sound S3, the fatigue degree is defined according to the frequency of the third heart sound S3; when the third heart sound is absent S3, fitting a fatigue value through a fatigue degree algorithm according to the values of the heart rate, D1, D1' and D/S; and then judging whether the fatigue value is in the range of the fatigue value, if not, representing no fatigue, if yes, blinking a red indicator light, giving out alarm sound through a loudspeaker unit 18, and displaying on a screen by a display unit 17 to give an alarm, so that a doctor can propose a related treatment scheme according to the fatigue value.
The utility model relates to a portable multi-functional monitor device can not only pass through each physiological parameter of relevant sensor monitoring human body, can calculate human fatigue degree numerical value through current algorithm according to the heart sound parameter moreover to show on the screen.