CN203773268U - Wearable device used for outdoor extreme sport personnel safety monitoring - Google Patents

Abstract

The utility model discloses a wearable device used for outdoor extreme sport personnel safety monitoring The device comprises a power supply management module, a physiological parameter acquisition module, an environmental parameter acquisition module, a GPS positioning module, a GPRS transmission module and a processor module. The size of the device is small and the weight is light. The device is portable, is high in mobility and has good comfortableness. An anti-interference capability is high. Connection with a network is stable and reliable and a data transmission and error correction capability is high. The usage is convenient. Information monitoring is stable and reliable. A usage scope is wide and is not limited by time and a region. Physiological parameters of a user, environmental parameters and positioning information are collected in real time. Through a GPRS technology, long distance transmission is performed.

Description

A kind of wearable device for outdoor extreme sport personal security monitoring

Technical field

The utility model belongs to wireless sensor network, wearable smart machine, embedded system technology field, is specifically related to a kind of wearable device that can be used for outdoor extreme sport personal security monitoring.

Background technology

Along with developing rapidly of economy, people's living standard improves constantly, and outdoor extreme sport is day by day frequent, and it brings, and security issues become increasingly urgent.Along with the rise of mobile Internet, Internet of Things, the technology such as wearable, greatly promote the development of wearable smart machine industry, by the combination of itself and outdoor extreme sport personal security watch-dog, will greatly ensure related personnel's life security.

Outdoor extreme sport is due to the singularity of self, often follow danger, it is much there is in recent years pained accident, wearable smart machine can be located in real time to outdoor extreme sport personnel, follow the tracks of related personnel position when accident is occurred, to the Real-time Collection of life, environmental information, be convenient to design efficient emergency management and rescue scheme.

Summary of the invention

The purpose of this utility model is exactly for the deficiencies in the prior art, and a kind of wearable device for outdoor extreme sport personal security monitoring is provided.

A kind of wearable device for outdoor extreme sport personal security monitoring of the present utility model, comprises power management module, physiological parameter acquisition module, environmental parameter acquisition module, GPS locating module, GPRS transport module and processor module; Wherein physiological parameter acquisition module comprises: body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit; Environmental parameter acquisition module comprises: ambient temperature and humidity collecting unit, ambient atmosphere pressure parameter acquisition unit.Described power management module comprises VCC7.4V rechargeable type lithium battery, VCC5.0V voltage conversion circuit, VCC4.0V voltage conversion circuit, VCC3.3V voltage conversion circuit; 7.4V rechargeable type lithium battery JS-7.4V-2.2AH provides power supply for VCC5V.0 voltage conversion circuit; The core of VCC5.0V voltage conversion circuit is AMS1117-5.0 low pressure difference linearity stabilized voltage supply chip, and VCC4.0V voltage conversion circuit, VCCC3.3V voltage conversion circuit, body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit, ambient atmosphere pressure parameter acquisition unit, GPS locating module are supplied with in its output; The core of 4.0V voltage conversion circuit is the sluggish switch power converter of FDS9435-MOSFET power tube, LM3485; it is output as GPRS module power supply is provided; the core of VCC3.3V voltage conversion circuit is AMS1117-3.3 low pressure difference linearity stabilized voltage supply chip, and it is output as ambient temperature and humidity collecting unit, processor module master chip STM32F103RBT6, jtag interface power supply is provided;

Power management module comprises: 7.4V lithium battery, 7.4V lithium battery interface J1, self-lock switch K1, the first diode D1, the second diode D2, the 3rd diode D3, the 4th diode D4, the first voltage transitions chip AMS1117-5.0, second voltage conversion chip AMS1117-3.3, the one MOSFET power tube FDS9435, the first sluggish switch power converter LM3485, the first electrochemical capacitor C1, the first tantalum capacitor C 2, the second tantalum capacitor C 3, the second electrochemical capacitor C4, the 3rd electrochemical capacitor C5, the 3rd tantalum capacitor C 6, the 4th tantalum capacitor C 7, the 4th electrochemical capacitor C8, the 5th tantalum capacitor C 9, the 5th electrochemical capacitor C10, the 6th electrochemical capacitor C11, the 6th tantalum capacitor C 12, the 7th tantalum capacitor C 13, the 7th electrochemical capacitor C14, the first resistance R 1, the second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the first power light DS1, the first inductance L 1,

The minus earth of described 7.4V lithium battery, the positive pole of 7.4V lithium battery connects the first pin of self-lock switch K1, and 2 pins of self-lock switch K1 are connected with the anode of the first diode D1, and the negative electrode of the first diode D1 connects VCC7.4V voltage output end;

VCC7.4V voltage output end connects the positive pole of the first electrochemical capacitor C1, one end of the first tantalum capacitor C 2, 3 pins of the first voltage transitions chip AMS1117-5.0, the negative pole of the first electrochemical capacitor C1 connects the other end of the first tantalum capacitor C 2, 1 pin of the first voltage transitions chip AMS1117-5.0, one end of the second tantalum capacitor C 3, the negative pole of the second electrochemical capacitor C4, the anode of the second diode D2, the negative pole of the 3rd electrochemical capacitor C5, one end of the 3rd tantalum capacitor C 6 is to ground, 2 pins of the first voltage transitions chip AMS1117-5.0 connect the other end of the second tantalum capacitor C 3, the positive pole of the second electrochemical capacitor C4, the negative electrode of the second diode D2, the anode of the 3rd diode D3, the negative electrode of the 3rd diode D3 connects the positive pole of the 3rd electrochemical capacitor C5, the other end of the 3rd tantalum capacitor C 6 is to the output terminal of 5V voltage conversion circuit,

The output terminal of VCC5.0V voltage conversion circuit connects 3 pins of second voltage conversion chip AMS1117-3.3, one end of the 4th tantalum capacitor C 7, the anode of the 4th electrochemical capacitor C8, the other end of the 4th tantalum capacitor C 7 connects the negative electrode of the 4th electrochemical capacitor C8, 1 pin of second voltage conversion chip AMS1117-3.3, one end of the 5th tantalum capacitor C 9, the negative electrode of the 5th electrochemical capacitor C10 is to ground, 2 pins of the first voltage transitions chip AMS1117-3.3 connect the other end of the 5th tantalum capacitor C 9, one end of the anode of the 5th electrochemical capacitor C10 and the first resistance R 1 is to the voltage output end of VCC3.3V, the other end of the first resistance R 1 connects the anode of the first power light DS1, the plus earth of the first power light DS1,

The output terminal of VCC5.0V voltage conversion circuit connects the anode of the 6th electrochemical capacitor C11, 1 pin of the one MOSFET power tube FDS9435, 2 pins, 8 pins of 3 pins and the first sluggish switch power converter LM3485, 4 pins of the one MOSFET power tube FDS9435 connect 7 pins of the first sluggish switch power converter LM3485, 5 pins of the one MOSFET power tube FDS9435, 6 pins, 7 pins, 8 pins connect the negative electrode of the 4th diode D4, 1 pin of the first sluggish switch power converter LM3485, one end of the first inductance L 1, the anodic bonding GND of the 4th diode D4, 2 pins of the first sluggish switch power converter LM3485, 6 pins connect GND, 5 pins of the first sluggish switch power converter LM3485 connect one end of the second resistance R 2, one end of the 6th tantalum capacitor C 12, the other end of the 6th tantalum capacitor C 12 connects 8 pins of the second resistance R 2 to first sluggish switch power converter LM3485, 3 pins of the first sluggish switch power converter LM3485 are built on stilts, 4 pins of the first sluggish switch power converter LM3485 connect one end of the 3rd resistance R 3, one end of the 4th resistance R 4, one end of the 7th tantalum capacitor C 13, the other end of the 3rd resistance R 3 connects GND, the other end of the 4th resistance R 4 connects the other end of the 7th tantalum capacitor C 13, the anode of the 7th electrochemical capacitor C14, the other end of the first inductance L 1 is to the voltage output end of VCC4.0V, the negative electrode of the 7th electrochemical capacitor C14 connects GND,

Described physiological parameter acquisition module comprises body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit; Body temperature parameter acquisition unit adopts 24 pins of TSIC506 digital high accuracy body temperature trans and processor module to be connected, and data read and adopt Tsic ZAC bus communication protocol, and power end is connected with 5.0V voltage conversion circuit; Universal asynchronous receiving-transmitting (the Universal Asynchronous Receiver/Transmitter of blood oxygen saturation and Pulse-Parameters collecting unit YS2000 and processor module, UART) interface UART3 is connected, and power end is connected with 5.0V voltage conversion circuit.Described blood oxygen saturation and Pulse-Parameters collecting unit comprise CY8C5566L high speed processor unit, voltage conversion circuit and filter circuit of pressure-stabilizing, and the signal of output is connected with the UART3 of processor;

Blood oxygen saturation and Pulse-Parameters collecting unit circuit comprise: splicing ear P1, splicing ear P2, the 8th tantalum capacitor C 15;

The RX pin of splicing ear P2 connects a RX pin of splicing ear P1,2 pin of splicing ear P2 connect a TX pin of splicing ear P1, the TX pin of splicing ear P2 connects GND, the supply pin of splicing ear P2 connects the voltage output end of VCC5.0V, one end of the 8th tantalum capacitor C 15, the other end of the 8th tantalum capacitor C 15 connects GND, another RX pin of splicing ear P1 connects the PB10 pin of processor STM32F103RBT6, and another TX pin of splicing ear P1 connects the PB11 pin of processor STM32F103RBT6;

Body temperature parameter acquisition unit circuit comprises: splicing ear P3, the 5th resistance R 5, the nine tantalum capacitor C 16; The power pins of the splicing ear P3 of body temperature parameter acquisition unit connects one end of the 5th resistance R 5, one end of the 9th tantalum capacitor C 16, the other end of the 5th resistance connects the voltage output end of VCC5.0V, the IO pin of splicing ear P3 connects the PC0 pin of processor STM32F103RBT6, the GND pin ground connection of splicing ear P3.

Described environmental parameter acquisition module comprises ambient temperature and humidity collecting unit, ambient atmosphere pressure collecting unit; Ambient temperature and humidity collecting unit adopts PB0, the PB1 pin of SHT11 digital high accuracy Temperature Humidity Sensor and processor to be connected, and data read and adopt class iic bus agreement, and power end is connected with VCC3.3V voltage output end.Ambient atmosphere pressure collecting unit adopts the PC pin of BMP085 digital high accuracy atmospheric pressure acquisition chip and processor to be connected, and power end is connected with VCC5.0V voltage output end.

Ambient temperature and humidity collecting unit comprises: the tenth tantalum capacitor C 17, the six resistance R 6, module splicing ear P4; The SDA pin of splicing ear P1 connects one end of the 6th resistance R 6, the PB1 pin of processor module STM32F103RBT6, the other end of the 6th resistance R 6 connects VCC3.3V Voltage-output terminal circuit, the power pins of module splicing ear P4 connects one end, the VCC3.3V Voltage-output terminal circuit of the tenth tantalum capacitor C 17, the GND pin ground connection of the other end link block splicing ear P6 of the tenth tantalum capacitor C 17, the SCL pin of splicing ear P6 connects the PB0 pin of processor module STM32F103RBT6;

Ambient atmosphere pressure collecting unit comprises: the 11 tantalum capacitor C 18, module splicing ear P6, terminals P 5, the power pins of splicing ear P6 connects one end of the 11 tantalum capacitor C 18, VCC5.0V voltage output end, the SCL pin of the SCL pin splicing ear P5 of module splicing ear P6, the SDA pin of the SDA pin splicing ear P5 of module splicing ear P6, the XCLR pin of the XCLR pin splicing ear P5 of module splicing ear P6, the NC pin of the NC pin splicing ear P5 of module splicing ear P6, the GND pin ground connection of module splicing ear P6, the SCL pin of terminals P 5 connects the PC0 pin of processor module STM32F103RBT6, the SDA pin of terminals P 5 connects the PC1 pin of processor module STM32F103RBT6, the XCLR pin of terminals P 5 connects the PC2 pin of processor module STM32F103RBT6, the NC pin of terminals P 5 connects the PC3 pin of processor module STM32F103RBT6,

GPS locating module comprises: module splicing ear P7, the 12 tantalum capacitor C 19; The power pins of module splicing ear P7 connects one end, the VCC5.0V voltage output end of the 12 tantalum capacitor C 19, the GND pin ground connection of module splicing ear P7, the TX pin of module splicing ear P7 connects the PA3 pin of processor module STM32F103RBT6, and the RX pin of module splicing ear P7 connects the PA2 pin of processor module STM32F103RBT6;

Universal asynchronous receiving-transmitting (the Universal Asynchronous Receiver/Transmitter of described GPRS transport module KS-97 and processor module, UART) interface UART1 is connected, power end is connected with VCC4.0V voltage conversion circuit output terminal, the input terminal voltage of VCC4.0V voltage conversion circuit can reach 50V, change-over circuit takes into full account electromagnetic interference (EMI), VCC4.0V output voltage stabilization is reliable, and ripple is little, for GPRS module provides power supply; GPRS transport module circuit diagram comprises: the 13 tantalum capacitor C 20, the 7th resistance R 7, the 8th resistance R 8, the 9th resistance R 9, the second light emitting diode DS2, the 3rd light emitting diode DS3, the 4th light emitting diode DS4, GPRS core cell KS97, splicing ear P8, the second button K2;

1 pin of core cell KS97 in GPRS transport module circuit, 2 pins, 11 pins, 20 pins connect GND, 3 pins of the core cell KS97 of GPRS, 4 pins are connected to VCC4.0V output voltage terminal, 5 pins of GPRS core cell KS97 are connected with 1 pin of splicing ear P8, 1 pin of splicing ear P8 connects the PA9 pin of processor STM32F103RBT6, 6 pins of GPRS core cell KS97 are connected with 3 pins of splicing ear P8, 3 pins of splicing ear P8 connect the PA10 pin of processor STM32-64, 9 pins of GPRS core cell KS97 connect 3 pins of the second button K2, 1 pin of the second button K2 connects GND, 10 pins of GPRS core cell KS97 connect the 7th resistance R 7, the 7th resistance R 7 connects the anode of the second light emitting diode, the negative electrode of the second light emitting diode connects GND, 18 pins of GPRS core cell KS97 connect one end of the 8th resistance R 8, the other end of the 8th resistance R 8 connects the anode of the 3rd light emitting diode DS3, the negative electrode of the 3rd light emitting diode DS3 connects GND, 19 pins of GPRS core cell KS97 connect one end of the 9th resistance R 9, the other end of the 9th resistance R 9 connects the anode of the 4th light emitting diode DS4, the negative electrode of the 4th light emitting diode DS4 connects GND, other pins of GPRS core cell KS97 are all maked somebody a mere figurehead,

Described processor module, taking processor STM32F103RBT6 as core, has been built respectively reset circuit, crystal oscillating circuit, jtag interface circuit, RS-232 transceiver circuit, decoupling circuit in its periphery.And each power pins of processor is carried out moving back lotus root processing.The power end of processor connects VCC3.3V voltage output end, three UART interfaces in processor module are connected with GPRS transport module, GPS locating module, blood oxygen saturation and Pulse-Parameters collecting unit respectively, wherein RS-232 transceiver circuit comprises: the 14 tantalum capacitor C the 21, the 15 tantalum capacitor C the 22, the 16 tantalum capacitor C the 23, the 17 tantalum capacitor C 24, first serial plug-in unit COM1, a RS-232 transponder chip MAX3232, main processor unit circuit comprises: master chip STM32F103RBT6, the 18 tantalum capacitor C 25, the 19 tantalum capacitor C 26, the 20 tantalum capacitor C 27, the 21 tantalum capacitor C 28, the 22 tantalum capacitor C 29, the 23 tantalum capacitor C 30, the 24 tantalum capacitor C 31, the 25 tantalum capacitor C 32, the 26 tantalum capacitor C 33, the 27 tantalum capacitor C 34, the first crystal oscillator Y1, the second crystal oscillator Y2, the 3rd button K3, the 5th light emitting diode DS5, the tenth resistance R 10, the 11 resistance R 11, jtag interface circuit comprises: JTAG connector JTAG_20, the 12 resistance R the 12, the 13 resistance R the 13, the 14 resistance R the 14, the 15 resistance R the 15, the 16 resistance R the 16, the 28 tantalum capacitor C 35,

1 pin in RS-232 main circuit chip MAX3232 connects one end of the 16 tantalum capacitor C 23, the other end of the 16 tantalum capacitor C 23 connects 3 pins of MAX3232, 4 pins in MAX3232 connect one end of the 17 tantalum capacitor C 24, the other end of the 17 tantalum capacitor C 24 connects 5 pins of MAX3232, 2 pins in MAX3232 connect one end of the 14 tantalum capacitor C 21, the other end of the 14 tantalum capacitor C 21 connects GND, 2 pins in MAX3232 connect one end of the 15 tantalum capacitor C 22, the other end of the 15 tantalum capacitor C 22 connects GND, 13 pins in MAX3232 connect 3 pins of first serial socket COM1, 14 pins in MAX3232 connect 2 pins of first serial socket COM1, 11 pins in MAX3232 connect the PA9 of host processor chip STM32F103RBT6, 12 pins in MAX3232 connect the PA10 of host processor chip STM32F103RBT6, 16 pins in MAX3232 connect VCC5.0V voltage output end, 15 pins in MAX3232 connect GND, other pins in MAX3232 are all maked somebody a mere figurehead, 5 pins of first serial plug-in unit COM1 connect GND,

7 pins of the master chip STM32F103RBT6 of processor module connect one end of the 27 tantalum capacitor C 34 in reset circuit, one end of the tenth resistance R 10,3 pins of the 3rd button K3, and the other end that 1 pin of the 3rd button K3 connects the 27 tantalum capacitor C 34 is to GND; The other end of the tenth resistance R 10 connects one end, the VCC3.3V voltage output end of the 11 resistance R 11, the other end of the 11 resistance R 11 connects the anode of the 5th light emitting diode DS5, and the negative electrode of the 5th light emitting diode DS5 connects 53 pins of processor chips STM32F103RBT6.5 pins of processor chips STM32F103RBT6 connect one end of the first crystal oscillator Y1, one end of the 23 tantalum capacitor C 30,6 pins of processor chips STM32F103RBT6 connect the other end of the first crystal oscillator Y1, one end of the 24 tantalum capacitor C 31, the equal ground connection of the other end of the other end of the 23 tantalum capacitor C 30 and the 24 tantalum capacitor C 31; 3 pins of processor chips STM32F103RBT6 connect one end of the second crystal oscillator Y2, one end of the 25 tantalum capacitor C 32,4 pins of processor chips STM32F103RBT6 connect the other end of the second crystal oscillator Y2, one end of the 26 tantalum capacitor C 33, the equal ground connection of the other end of the other end of the 23 tantalum capacitor C 32 and the 24 tantalum capacitor C 33; If crystal oscillating circuit starting of oscillation is undesirable, can be at a crystal oscillator Y1 and Y2 two ends resistance respectively in parallel; 13 pins of processor chips STM32F103RBT6 connect one end of the 18 tantalum capacitor C 25, and the other end of the 18 tantalum capacitor C 25 connects 12 pins of processor chips STM32F103RBT6 to GND; 19 pins of processor chips STM32F103RBT6 connect one end of the 19 tantalum capacitor C 26, and the other end of the 19 tantalum capacitor C 26 connects 18 pins of processor chips STM32F103RBT6 to GND; 32 pins of processor chips STM32F103RBT6 connect one end of the 20 tantalum capacitor C 27, and the other end of the 20 tantalum capacitor C 27 connects 31 pins of processor chips STM32F103RBT6 to GND; 48 pins of processor chips STM32F103RBT6 connect one end of the 21 tantalum capacitor C 28, and the other end of the 21 tantalum capacitor C 28 connects 47 pins of processor chips STM32F103RBT6 to GND; 64 pins of processor chips STM32F103RBT6 connect one end of the 22 tantalum capacitor C 29, and the other end of the 22 tantalum capacitor C 29 connects 63 pins of processor chips STM32F103RBT6 to GND;

3 pins of connector JTAG_20 in jtag interface circuit connect 56 pins of processor chips STM32F103RBT6, one end of the 12 resistance R 12, and the other end of the 12 resistance R 12 connects VCC3.3V voltage output end; 5 pins of connector JTAG_20 connect 50 pins of processor chips STM32F103RBT6, one end of the 13 resistance R 13, and the other end of the 13 resistance R 13 connects VCC3.3V voltage output end; 7 pins of connector JTAG_20 connect 46 pins of processor chips STM32F103RBT6, one end of the 14 resistance R 14, and the other end of the 14 resistance R 14 connects VCC3.3V voltage output end; 9 pins of connector JTAG_20 connect 49 pins of processor chips STM32F103RBT6, one end of the 15 resistance R 15, and the other end of the 15 resistance R 15 connects GND; 13 pins of connector JTAG_20 connect 55 pins of processor chips STM32F103RBT6, one end of the 16 resistance R 16, and the other end of the 16 resistance R 16 connects VCC3.3V voltage output end; 1 pin, 2 pins of connector JTAG_20 connect VCC3.3V voltage output end, 2 pins of connector JTAG_20 connect one end of the 28 tantalum capacitor C 35, the other end of the 28 tantalum capacitor C 35 connects 4 pins, 6 pins, 8 pins, 10 pins, 12 pins, 14 pins, 16 pins, 18 pins, 20 pins of connector JTAG_20, and other pins of connector JTAG_20 are all built on stilts.

The utility model, than prior art, mainly contains following advantage:

1, equipment volume and quality are little, and it is convenient to carry, and mobility is strong, have good comfortableness.

2, equipment antijamming capability is strong, connected to the network reliable and stable, and data transmission error correcting capability is strong.

3, equipment is easy to use, and monitoring information is reliable and stable, and equipment usable range is wide, is not subject to time regional limits.

4, Real-time Collection user's physiological parameter, environmental parameter and locating information, by GPRS technology long-distance transmissions.

5, equipment operation is low in energy consumption, and software and hardware system all adopts low power dissipation design, can work long hours, and battery flying power is strong.

Brief description of the drawings:

The 5.0V voltage conversion circuit schematic diagram that Fig. 1 (a) is power management module of the present utility model;

Fig. 1 (b) is power management module 3.3V voltage conversion circuit schematic diagram of the present utility model;

Fig. 1 (c) is power management module 4.0V voltage conversion circuit schematic diagram of the present utility model;

Fig. 2 is blood oxygen saturation of the present utility model and pulse collection element circuit schematic diagram;

Fig. 3 is body temperature collecting unit circuit theory diagrams of the present utility model;

Fig. 4 is ambient temperature and humidity collecting unit circuit theory diagrams of the present utility model;

Fig. 5 is ambient atmosphere pressure collecting unit circuit theory diagrams of the present utility model;

Fig. 6 is GPS positioning circuit schematic diagram of the present utility model;

Fig. 7 is GPRS transport module circuit theory diagrams of the present utility model;

Fig. 8 (a) is processor module RS-232 interface circuit theory diagrams of the present utility model;

Fig. 8 (b) is processor module master chip circuit theory diagrams of the present utility model;

Fig. 8 (c) is processor module jtag interface circuit theory diagrams of the present utility model.

Embodiment

The wearable device that can be used for outdoor extreme sport personal security monitoring comprises power management module, physiological parameter acquisition module, environmental parameter acquisition module, GPS locating module, GPRS transport module and processor module; Wherein physiological parameter acquisition module comprises: body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit; Environmental parameter acquisition module comprises: ambient temperature and humidity collecting unit, ambient atmosphere pressure parameter acquisition unit.

Below in conjunction with accompanying drawing, the utility model is further described:

As shown in Fig. 1 (a), power management module comprises 7.4V lithium battery, 7.4V lithium battery interface J1, self-lock switch K1, the first diode D1, the second diode D2, the 3rd diode D3, the first electrochemical capacitor C1, the first tantalum capacitor C 2, the second tantalum capacitor C 3, the second electrochemical capacitor C4, the 3rd electrochemical capacitor C5, the 3rd tantalum capacitor C 6, the first voltage transitions chip AMS1117-5.0;

As shown in Fig. 1 (a): the minus earth of 7.4V lithium battery interface J1, the positive pole of 7.4V lithium battery connects the first pin of self-lock switch K1,2 pins of self-lock switch K1 are connected with the anode of the first diode D1, and the negative electrode of the first diode D1 connects VCC7.4V voltage output end;

As shown in Fig. 1 (a): VCC7.4V voltage output end connects the positive pole of the first electrochemical capacitor C1, one end of the first tantalum capacitor C 2, 3 pins of the first voltage transitions chip AMS1117-5.0, the negative pole of the first electrochemical capacitor C1 connects the other end of the first tantalum capacitor C 2, 1 pin of the first voltage transitions chip AMS1117-5.0, one end of the second tantalum capacitor C 3, the negative pole of the second electrochemical capacitor C4, the anode of the second diode D2, the negative pole of the 3rd electrochemical capacitor C5, one end of the 3rd tantalum capacitor C 6 is to ground, 2 pins of the first voltage transitions chip AMS1117-5.0 connect the other end of the second tantalum capacitor C 3, the positive pole of the second electrochemical capacitor C4, the negative electrode of the second diode D2, the anode of the 3rd diode D3, the negative electrode of the 3rd diode D3 connects the positive pole of the 3rd electrochemical capacitor C5, the other end of the 3rd tantalum capacitor C 6 is to the output terminal of 5V voltage conversion circuit,

As shown in Fig. 1 (b): VCC3.3V voltage conversion circuit figure comprises the 4th tantalum capacitor C 7, the 4th electrochemical capacitor C8, the 5th tantalum capacitor C 9, the 5th electrochemical capacitor C10, the first resistance R 1, the first power light DS1, second voltage conversion chip AMS1117-3.3;

As shown in Fig. 1 (b): the output terminal of VCC5.0V voltage conversion circuit connects 3 pins of second voltage conversion chip AMS1117-3.3, one end of the 4th tantalum capacitor C 7, the anode of the 4th electrochemical capacitor C8, the other end of the 4th tantalum capacitor C 7 connects the negative electrode of the 4th electrochemical capacitor C8, 1 pin of second voltage conversion chip AMS1117-3.3, one end of the 5th tantalum capacitor C 9, the negative electrode of the 5th electrochemical capacitor C10 is to ground, 2 pins of second voltage conversion chip AMS1117-3.3 connect the other end of the 5th tantalum capacitor C 9, one end of the anode of the 5th electrochemical capacitor C10 and the first resistance R 1 is to the voltage output end of VCC3.3V, the other end of the first resistance R 1 connects the anode of the first power light DS1, the plus earth of the first power light DS1,

As shown in Fig. 1 (c): VCC4.0V voltage conversion circuit figure comprises the 4th diode D4, electrochemical capacitor C11, the 6th tantalum capacitor C 12, the 7th tantalum capacitor C 13, the 7th electrochemical capacitor C14, the second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the first inductance L 1, a MOSFET power tube FDS9435, the first sluggish switch power converter LM3485;

As shown in Fig. 1 (c): the output terminal of VCC5.0V voltage conversion circuit connects the anode of the 6th electrochemical capacitor C11, 1 pin of the one MOSFET power tube FDS9435, 2 pins, 8 pins of 3 pins and the first sluggish switch power converter LM3485, 4 pins of the one MOSFET power tube FDS9435 connect 7 pins of the first sluggish switch power converter LM3485, 5 pins of the one MOSFET power tube FDS9435, 6 pins, 7 pins, 8 pins connect the negative electrode of the 4th diode D4, 1 pin of the first sluggish switch power converter LM3485, one end of the first inductance L 1, the anodic bonding GND of the 4th diode D4, 2 pins of the first sluggish switch power converter LM3485, 6 pins connect GND, 5 pins of the first sluggish switch power converter LM3485 connect one end of the second resistance R 2, one end of the 6th tantalum capacitor C 12, the other end of the 6th tantalum capacitor C 12 connects 8 pins of the second resistance R 2 to first sluggish switch power converter LM3485, 3 pins of the first sluggish switch power converter LM3485 are built on stilts, 4 pins of the first sluggish switch power converter LM3485 connect one end of the 3rd resistance R 3, one end of the 4th resistance R 4, one end of the 7th tantalum capacitor C 13, the other end of the 3rd resistance R 3 connects GND, the other end of the 4th resistance R 4 connects the other end of the 7th tantalum capacitor C 13, the anode of the 7th electrochemical capacitor C14, the other end of the first inductance L 1 is to the voltage output end of VCC4.0V, the negative electrode of the 7th electrochemical capacitor C14 connects GND,

As shown in Figure 2: blood oxygen saturation and pulse collection element circuit figure comprise splicing ear P1, splicing ear P2, the 8th tantalum capacitor C 15; 1 pin of splicing ear P2 connects 3 pin of splicing ear P1,2 pin of splicing ear P2 connect 1 pin of splicing ear P1,3 pin of splicing ear P2 connect GND, 4 pin of splicing ear P2 connect the voltage output end of VCC5.0V, one end of the 8th tantalum capacitor C 15, the other end of the 8th tantalum capacitor C 15 connects GND, 4 pin of splicing ear P1 connect the PB10 pin of processor STM32F103RBT6, and 2 pin of splicing ear P1 connect the PB11 pin of processor STM32F103RBT6;

As shown in Figure 3: body temperature parameter acquisition unit circuit comprises splicing ear P3, the 5th resistance R 5, the nine tantalum capacitor C 16; 1 pin of the splicing ear P3 of body temperature parameter acquisition unit connects one end of the 5th resistance R 5, one end of the 9th tantalum capacitor C 16, the other end of the 5th resistance connects the voltage output end of VCC5.0V, 2 pins of splicing ear P3 connect the PC0 pin of processor STM32F103RBT6, and 3 pins of splicing ear connect GND;

As shown in Figure 4: ambient temperature and humidity collecting unit circuit diagram comprises the tenth tantalum capacitor C 17, the six resistance R 6, module splicing ear P4; One end of the 1 pin contact resistance R6 of module splicing ear P1 in ambient temperature and humidity collecting unit, the PB1 pin of processor module STM32F103RBT6, the other end of resistance R 6 connects VCC3.3V Voltage-output terminal circuit, 2 pins of module splicing ear P4 connect one end, the VCC3.3V Voltage-output terminal circuit of the tenth tantalum capacitor C 17,3 pins of the other end link block splicing ear P6 of the tenth tantalum capacitor C 17 are to GND, and 4 pins of splicing ear P6 connect the PB0 pin of processor module STM32F103RBT6;

As shown in Figure 5: ambient atmosphere pressure collecting unit circuit diagram comprises the 11 tantalum capacitor C 18, module splicing ear P6, terminals P 5, the power pins of module splicing ear P6 in ambient atmosphere pressure parameter acquisition unit connects one end of the 11 tantalum capacitor C 18, VCC5.0V voltage output end, 5 pins of the 2 pin splicing ear P5 of module splicing ear P6, 6 pins of the 3 pin splicing ear P5 of module splicing ear P6, 7 pins of the 4 pin splicing ear P5 of module splicing ear P6, 8 pins of the 5 pin splicing ear P5 of module splicing ear P6, 6 pins of module splicing ear P6 connect GND, 1 pin of terminals P 5 connects the PC0 pin of processor module STM32F103RBT6, 2 pins of terminals P 5 connect the PC1 pin of processor module STM32F103RBT6, 2 pins of terminals P 5 connect the PC2 pin of processor module STM32F103RBT6, 3 pins of terminals P 5 connect the PC3 pin of processor module STM32F103RBT6,

As shown in Figure 6: GPS locating module master chip model is ATK-NEO-6M-V12, adopt U-BLOX NEO-6M module, module carries high-performance passive ceramic antenna, and carry Chargeable backup battery, can support startup temperature or warm start, backup battery is after primary power source de-energizes, and the GPS that can maintain about half an hour receives data preservation.The UART2 interface of processor is connected with GPS module, and the power end of GPS module is connected with VCC5.0V voltage output end; GPS locating module comprises module splicing ear P7, the 12 tantalum capacitor C 19; The power pins of module splicing ear P7 connects one end, the VCC5.0V voltage output end of the 12 tantalum capacitor C 19, the GND pin ground connection of module splicing ear P7, the TX pin of module splicing ear P7 connects the PA3 pin of processor module STM32-64, and the RX pin of module splicing ear P7 connects the PA2 pin of processor module STM32-64;

As shown in Figure 7: GPRS transport module circuit diagram comprises the 13 tantalum capacitor C 20, the 7th resistance R 7, the 8th resistance R 8, the 9th resistance R 9, the second light emitting diode DS2, the 3rd light emitting diode DS3, the 4th light emitting diode DS4, GPRS core cell KS97, splicing ear P8, the second button K2.1 pin of the unit KS97 of the core in GPRS transport module circuit, 2 pins, 11 pins, 20 pins connect GND, 3 pins of the core cell KS97 of GPRS, 4 pins are connected to VCC4.0V output voltage terminal, 5 pins of GPRS core cell KS97 are connected with 1 pin of splicing ear P8, 1 pin of splicing ear P8 connects the PA9 pin of processor STM32-64, 6 pins of GPRS core cell KS97 are connected with 3 pins of splicing ear P8, 3 pins of splicing ear P8 connect the PA10 pin of processor STM32-64, 9 pins of GPRS core cell KS97 connect 3 pins of the second button K2, 1 pin of the second button K2 connects GND, 10 pins of GPRS core cell KS97 connect the 7th resistance R 7, the 7th resistance R 7 connects the anode of the second light emitting diode, the negative electrode of the second light emitting diode connects GND, 18 pins of GPRS core cell KS97 connect one end of the 8th resistance R 8, the other end of the 8th resistance R 8 connects the anode of the 3rd light emitting diode DS3, the negative electrode of the 3rd light emitting diode DS3 connects GND, 19 pins of GPRS core cell KS97 connect one end of the 9th resistance R 9, the other end of the 9th resistance R 9 connects the anode of the 4th light emitting diode DS4, the negative electrode of the 4th light emitting diode DS4 connects GND, other pins of GPRS core cell KS97 are all maked somebody a mere figurehead,

As shown in Fig. 8 (a): RS-232 interface circuit diagram comprises the 14 tantalum capacitor C the 21, the 15 tantalum capacitor C the 22, the 16 tantalum capacitor C the 23, the 17 tantalum capacitor C 24, first serial plug-in unit COM1, a RS-232 transponder chip MAX3232, 1 pin in master chip MAX3232 in RS-232 circuit connects one end of the 16 tantalum capacitor C 23, the other end of the 16 tantalum capacitor C 23 connects 3 pins of MAX3232, 4 pins in MAX3232 connect one end of the 17 tantalum capacitor C 24, the other end of the 17 tantalum capacitor C 24 connects 5 pins of MAX3232, 2 pins in MAX3232 connect one end of the 14 tantalum capacitor C 21, the other end of the 14 tantalum capacitor C 21 connects GND, 2 pins in MAX3232 connect one end of the 15 tantalum capacitor C 22, the other end of the 15 tantalum capacitor C 22 connects GND, 13 pins in MAX3232 connect 3 pins of first serial socket COM1, 14 pins in MAX3232 connect 2 pins of first serial socket COM1, 11 pins in MAX3232 connect the PA9 of host processor chip STM32F103RBT6, 12 pins in MAX3232 connect the PA10 of host processor chip STM32-64, 16 pins in MAX3232 connect VCC5.0V voltage output end, 15 pins in MAX3232 connect GND, other pins in MAX3232 are all maked somebody a mere figurehead, 5 pins of first serial socket COM1 connect GND,

As shown in Fig. 8 (b): processor module master chip circuit diagram comprises master chip STM32F103RBT6, the 18 tantalum capacitor C 25, the 19 tantalum capacitor C 26, the 20 tantalum capacitor C 27, the 21 tantalum capacitor C 28, the 22 tantalum capacitor C 29, the 23 tantalum capacitor C 30, the 24 tantalum capacitor C 31, the 25 tantalum capacitor C 32, the 26 tantalum capacitor C 33, the 27 tantalum capacitor C 34, the first crystal oscillator Y1, the second crystal oscillator Y2, the 3rd button K3, the 5th light emitting diode DS5, the tenth resistance R 10, the 11 resistance R 11, one end of the 27 tantalum capacitor C 34 in the connected reset circuit of 7 pins of the master chip STM32F103RBT6 of processor module, one end of the tenth resistance R 10,3 pins of the 3rd button K3, the other end that 1 pin of the 3rd button K3 connects the 27 tantalum capacitor C 34 is to GND, the other end of the tenth resistance R 10 connects one end, the VCC3.3V voltage output end of the 11 resistance R 11, the other end of the 11 resistance R 11 connects the anode of the 5th light emitting diode DS5, and the negative electrode of the 5th light emitting diode DS5 connects 53 pins of processor chips STM32F103RBT6.5 pins of processor chips STM32F103RBT6 connect one end of the first crystal oscillator Y1, one end of the 23 tantalum capacitor C 30,6 pins of processor chips STM32F103RBT6 connect the other end of the first crystal oscillator Y1, one end of the 24 tantalum capacitor C 31, the equal ground connection of the other end of the other end of the 23 tantalum capacitor C 30 and the 24 tantalum capacitor C 31; 3 pins of processor chips STM32F103RBT6 connect one end of the second crystal oscillator Y2, one end of the 25 tantalum capacitor C 32,4 pins of processor chips STM32F103RBT6 connect the other end of the second crystal oscillator Y2, one end of the 26 tantalum capacitor C 33, the equal ground connection of the other end of the other end of the 23 tantalum capacitor C 32 and the 24 tantalum capacitor C 33; If crystal oscillating circuit starting of oscillation is undesirable, can be at a crystal oscillator Y1 and Y2 two ends resistance respectively in parallel; 13 pins of processor chips STM32F103RBT6 connect one end of the 18 tantalum capacitor C 25, and the other end of the 18 tantalum capacitor C 25 connects 12 pins of processor chips STM32F103RBT6 to GND; 19 pins of processor chips STM32F103RBT6 connect one end of the 19 tantalum capacitor C 26, and the other end of the 19 tantalum capacitor C 26 connects 18 pins of processor chips STM32F103RBT6 to GND; 32 pins of processor chips STM32F103RBT6 connect one end of the 20 tantalum capacitor C 27, and the other end of the 20 tantalum capacitor C 27 connects 31 pins of processor chips STM32F103RBT6 to GND; 48 pins of processor chips STM32F103RBT6 connect one end of the 21 tantalum capacitor C 28, and the other end of the 21 tantalum capacitor C 28 connects 47 pins of processor chips STM32F103RBT6 to GND; 64 pins of processor chips STM32F103RBT6 connect one end of the 22 tantalum capacitor C 29, and the other end of the 22 tantalum capacitor C 29 connects 63 pins of processor chips STM32F103RBT6 to GND;

As shown in Fig. 8 (c): jtag interface circuit comprises JTAG_20 connector, the 12 resistance R the 12, the 13 resistance R the 13, the 14 resistance R the 14, the 15 resistance R the 15, the 16 resistance R the 16, the 28 tantalum capacitor C 35; 3 pins of connector JTAG_20 in jtag interface circuit connect 56 pins of processor chips STM32F103RBT6, one end of the 12 resistance R 12, and the other end of the 12 resistance R 12 connects VCC3.3V voltage output end; 5 pins of connector JTAG_20 connect 50 pins of processor chips STM32F103RBT6, one end of the 13 resistance R 13, and the other end of the 13 resistance R 13 connects VCC3.3V voltage output end; 7 pins of connector JTAG_20 connect 46 pins of processor chips STM32F103RBT6, one end of the 14 resistance R 14, and the other end of the 14 resistance R 14 connects VCC3.3V voltage output end; 9 pins of connector JTAG_20 connect 49 pins of processor chips STM32F103RBT6, one end of the 15 resistance R 15, and the other end of the 15 resistance R 15 connects GND; 13 pins of connector JTAG_20 connect 55 pins of processor chips STM32F103RBT6, one end of the 16 resistance R 16, and the other end of the 16 resistance R 16 connects VCC3.3V voltage output end; 1 pin, 2 pins of connector JTAG_20 connect VCC3.3V voltage output end, 2 pins of connector JTAG_20 connect one end of the 28 tantalum capacitor C 35, the other end of the 28 tantalum capacitor C 35 connects 4 pins, 6 pins, 8 pins, 10 pins, 12 pins, 14 pins, 16 pins, 18 pins, 20 pins of connector JTAG_20, and other pins of connector JTAG_20 are all built on stilts;

The wearable device equipment course of work that can be used for outdoor extreme sport personal security monitoring is as follows: after device power, processor module is each submodule of initialization system successively: physiological parameter acquisition module, environmental parameter acquisition module, GPS locating module, GPRS transport module, by the temperature in Real-time Collection environment, humidity, the information such as atmospheric pressure, gather the longitude and latitude at user place by GPS locating module, sea level elevation of living in, the information such as local time, gather user's body temperature by physiological parameter acquisition module, blood oxygen saturation, the information such as pulse, for being engaged in outdoor extreme sport, user provides reference, after being packaged into specific data stream, the treated device of information that each submodule is collected sends to appointment host computer through GPRS transport module, can supply other staff's reference, also can be used as the foundation of outdoor extreme sport personnel emergency relief time in danger simultaneously, this equipment can the personnel positions in moment occur to accident to be followed the tracks of, and is convenient to design efficient emergency management and rescue scheme.

Claims (1)

1. for a wearable device for outdoor extreme sport personal security monitoring, comprise power management module, physiological parameter acquisition module, environmental parameter acquisition module, GPS locating module, GPRS transport module and processor module;

It is characterized in that: physiological parameter acquisition module comprises body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit; Environmental parameter acquisition module comprises ambient temperature and humidity collecting unit, ambient atmosphere pressure parameter acquisition unit;

Described power management module comprises VCC7.4V rechargeable type lithium battery, VCC5.0V voltage conversion circuit, VCC4.0V voltage conversion circuit, VCC3.3V voltage conversion circuit; 7.4V rechargeable type lithium battery JS-7.4V-2.2AH provides power supply for VCC5V.0 voltage conversion circuit; The core of VCC5.0V voltage conversion circuit is AMS1117-5.0 low pressure difference linearity stabilized voltage supply chip, and VCC4.0V voltage conversion circuit, VCCC3.3V voltage conversion circuit, body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit, ambient atmosphere pressure parameter acquisition unit, GPS locating module are supplied with in its output; The core of 4.0V voltage conversion circuit is the sluggish switch power converter of FDS9435-MOSFET power tube, LM3485, it is output as GPRS module power supply is provided, the core of VCC3.3V voltage conversion circuit is AMS1117-3.3 low pressure difference linearity stabilized voltage supply chip, and it is output as ambient temperature and humidity collecting unit, processor module master chip STM32F103RBT6, jtag interface power supply is provided;

Power management module comprises: 7.4V lithium battery, 7.4V lithium battery interface J1, self-lock switch K1, the first diode D1, the second diode D2, the 3rd diode D3, the 4th diode D4, the first voltage transitions chip AMS1117-5.0, second voltage conversion chip AMS1117-3.3, the one MOSFET power tube FDS9435, the first sluggish switch power converter LM3485, the first electrochemical capacitor C1, the first tantalum capacitor C 2, the second tantalum capacitor C 3, the second electrochemical capacitor C4, the 3rd electrochemical capacitor C5, the 3rd tantalum capacitor C 6, the 4th tantalum capacitor C 7, the 4th electrochemical capacitor C8, the 5th tantalum capacitor C 9, the 5th electrochemical capacitor C10, the 6th electrochemical capacitor C11, the 6th tantalum capacitor C 12, the 7th tantalum capacitor C 13, the 7th electrochemical capacitor C14, the first resistance R 1, the second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the first power light DS1, the first inductance L 1,

The minus earth of described 7.4V lithium battery, the positive pole of 7.4V lithium battery connects the first pin of self-lock switch K1, and 2 pins of self-lock switch K1 are connected with the anode of the first diode D1, and the negative electrode of the first diode D1 connects VCC7.4V voltage output end;

The positive pole of the first electrochemical capacitor C1 in VCC7.4V voltage output end and VCC5.0V voltage conversion circuit, one end of the first tantalum capacitor C 2, 3 pins of the first voltage transitions chip AMS1117-5.0 connect, the negative pole of the first electrochemical capacitor C1 connects the other end of the first tantalum capacitor C 2, 1 pin of the first voltage transitions chip AMS1117-5.0, one end of the second tantalum capacitor C 3, the negative pole of the second electrochemical capacitor C4, the anode of the second diode D2, the negative pole of the 3rd electrochemical capacitor C5, one end of the 3rd tantalum capacitor C 6 is to ground, 2 pins of the first voltage transitions chip AMS1117-5.0 connect the other end of the second tantalum capacitor C 3, the positive pole of the second electrochemical capacitor C4, the negative electrode of the second diode D2, the anode of the 3rd diode D3, the negative electrode of the 3rd diode D3 connects the positive pole of the 3rd electrochemical capacitor C5, the other end of the 3rd tantalum capacitor C 6 is to the output terminal of 5V voltage conversion circuit,

3 pins of second voltage conversion chip AMS1117-3.3 in the output terminal of VCC5.0V voltage conversion circuit and VCC3.3V voltage conversion circuit, one end of the 4th tantalum capacitor C 7, the anodic bonding of the 4th electrochemical capacitor C8, the other end of the 4th tantalum capacitor C 7 connects the negative electrode of the 4th electrochemical capacitor C8, 1 pin of second voltage conversion chip AMS1117-3.3, one end of the 5th tantalum capacitor C 9, the negative electrode of the 5th electrochemical capacitor C10 is to ground, 2 pins of the first voltage transitions chip AMS1117-3.3 connect the other end of the 5th tantalum capacitor C 9, one end of the anode of the 5th electrochemical capacitor C10 and the first resistance R 1 is to the voltage output end of VCC3.3V, the other end of the first resistance R 1 connects the anode of the first power light DS1, the plus earth of the first power light DS1,

The anode of the 6th electrochemical capacitor C11 in the output terminal of VCC5.0V voltage conversion circuit and VCC4.0V voltage conversion circuit, 1 pin of the one MOSFET power tube FDS9435, 2 pins, 3 pins are connected with 8 pins of the first sluggish switch power converter LM3485, 4 pins of the one MOSFET power tube FDS9435 connect 7 pins of the first sluggish switch power converter LM3485, 5 pins of the one MOSFET power tube FDS9435, 6 pins, 7 pins, 8 pins connect the negative electrode of the 4th diode D4, 1 pin of the first sluggish switch power converter LM3485, one end of the first inductance L 1, the anodic bonding GND of the 4th diode D4, 2 pins of the first sluggish switch power converter LM3485, 6 pins connect GND, 5 pins of the first sluggish switch power converter LM3485 connect one end of the second resistance R 2, one end of the 6th tantalum capacitor C 12, the other end of the 6th tantalum capacitor C 12 connects 8 pins of the second resistance R 2 to first sluggish switch power converter LM3485, 3 pins of the first sluggish switch power converter LM3485 are built on stilts, 4 pins of the first sluggish switch power converter LM3485 connect one end of the 3rd resistance R 3, one end of the 4th resistance R 4, one end of the 7th tantalum capacitor C 13, the other end of the 3rd resistance R 3 connects GND, the other end of the 4th resistance R 4 connects the other end of the 7th tantalum capacitor C 13, the anode of the 7th electrochemical capacitor C14, the other end of the first inductance L 1 is to the voltage output end of VCC4.0V, the negative electrode of the 7th electrochemical capacitor C14 connects GND,

Described physiological parameter acquisition module comprises body temperature parameter acquisition unit, blood oxygen saturation and Pulse-Parameters collecting unit; Body temperature parameter acquisition unit adopts 24 pins of TSIC506 digital high accuracy body temperature trans and processor module to be connected, and data read and adopt Tsic ZAC bus communication protocol, and power end is connected with 5.0V voltage conversion circuit; The universal asynchronous receiving-transmitting interface UART3 of blood oxygen saturation and Pulse-Parameters collecting unit YS2000 and processor module is connected, and power end is connected with 5.0V voltage conversion circuit; Described blood oxygen saturation and Pulse-Parameters collecting unit comprise CY8C5566L high speed processor unit, voltage conversion circuit and filter circuit of pressure-stabilizing, and the signal of output is connected with the UART3 of processor;

Blood oxygen saturation and Pulse-Parameters collecting unit circuit comprise: splicing ear P1, splicing ear P2, the 8th tantalum capacitor C 15;

The RX pin of splicing ear P2 connects a RX pin of splicing ear P1,2 pin of splicing ear P2 connect a TX pin of splicing ear P1, the TX pin of splicing ear P2 connects GND, the supply pin of splicing ear P2 connects the voltage output end of VCC5.0V, one end of the 8th tantalum capacitor C 15, the other end of the 8th tantalum capacitor C 15 connects GND, another RX pin of splicing ear P1 connects the PB10 pin of processor STM32F103RBT6, and another TX pin of splicing ear P1 connects the PB11 pin of processor STM32F103RBT6;

Body temperature parameter acquisition unit circuit comprises: splicing ear P3, the 5th resistance R 5, the nine tantalum capacitor C 16; The power pins of the splicing ear P3 of body temperature parameter acquisition unit connects one end of the 5th resistance R 5, one end of the 9th tantalum capacitor C 16, the other end of the 5th resistance connects the voltage output end of VCC5.0V, the IO pin of splicing ear P3 connects the PC0 pin of processor STM32F103RBT6, the GND pin ground connection of splicing ear P3;

Described environmental parameter acquisition module comprises ambient temperature and humidity collecting unit, ambient atmosphere pressure collecting unit; Ambient temperature and humidity collecting unit adopts PB0, the PB1 pin of SHT11 digital high accuracy Temperature Humidity Sensor and processor to be connected, and data read and adopt class iic bus agreement, and power end is connected with VCC3.3V voltage output end; Ambient atmosphere pressure collecting unit adopts the PC pin of BMP085 digital high accuracy atmospheric pressure acquisition chip and processor to be connected, and power end is connected with VCC5.0V voltage output end;

Ambient temperature and humidity collecting unit comprises: the tenth tantalum capacitor C 17, the six resistance R 6, module splicing ear P4; The SDA pin of splicing ear P1 connects one end of the 6th resistance R 6, the PB1 pin of processor module STM32F103RBT6, the other end of the 6th resistance R 6 connects VCC3.3V Voltage-output terminal circuit, the power pins of module splicing ear P4 connects one end, the VCC3.3V Voltage-output terminal circuit of the tenth tantalum capacitor C 17, the GND pin ground connection of the other end link block splicing ear P6 of the tenth tantalum capacitor C 17, the SCL pin of splicing ear P6 connects the PB0 pin of processor module STM32F103RBT6;

Ambient atmosphere pressure collecting unit comprises: the 11 tantalum capacitor C 18, module splicing ear P6, terminals P 5, the power pins of splicing ear P6 connects one end of the 11 tantalum capacitor C 18, VCC5.0V voltage output end, the SCL pin of the SCL pin splicing ear P5 of module splicing ear P6, the SDA pin of the SDA pin splicing ear P5 of module splicing ear P6, the XCLR pin of the XCLR pin splicing ear P5 of module splicing ear P6, the NC pin of the NC pin splicing ear P5 of module splicing ear P6, the GND pin ground connection of module splicing ear P6, the SCL pin of terminals P 5 connects the PC0 pin of processor module STM32F103RBT6, the SDA pin of terminals P 5 connects the PC1 pin of processor module STM32F103RBT6, the XCLR pin of terminals P 5 connects the PC2 pin of processor module STM32F103RBT6, the NC pin of terminals P 5 connects the PC3 pin of processor module STM32F103RBT6,

GPS locating module comprises: module splicing ear P7, the 12 tantalum capacitor C 19; The power pins of module splicing ear P7 connects one end, the VCC5.0V voltage output end of the 12 tantalum capacitor C 19, the GND pin ground connection of module splicing ear P7, the TX pin of module splicing ear P7 connects the PA3 pin of processor module STM32F103RBT6, and the RX pin of module splicing ear P7 connects the PA2 pin of processor module STM32F103RBT6;

The universal asynchronous receiving-transmitting Universal Asynchronous Receiver/Transmitter of described GPRS transport module KS-97 and processor module, UART interface UART1 is connected, power end is connected with VCC4.0V voltage conversion circuit output terminal, the input terminal voltage of VCC4.0V voltage conversion circuit can reach 50V, change-over circuit takes into full account electromagnetic interference (EMI), VCC4.0V output voltage stabilization is reliable, and ripple is little, for GPRS module provides power supply; GPRS transport module circuit diagram comprises: the 13 tantalum capacitor C 20, the 7th resistance R 7, the 8th resistance R 8, the 9th resistance R 9, the second light emitting diode DS2, the 3rd light emitting diode DS3, the 4th light emitting diode DS4, GPRS core cell KS97, splicing ear P8, the second button K2;

1 pin of core cell KS97 in GPRS transport module circuit, 2 pins, 11 pins, 20 pins connect GND, 3 pins of the core cell KS97 of GPRS, 4 pins are connected to VCC4.0V output voltage terminal, 5 pins of GPRS core cell KS97 are connected with 1 pin of splicing ear P8, 1 pin of splicing ear P8 connects the PA9 pin of processor STM32F103RBT6, 6 pins of GPRS core cell KS97 are connected with 3 pins of splicing ear P8, 3 pins of splicing ear P8 connect the PA10 pin of processor STM32-64, 9 pins of GPRS core cell KS97 connect 3 pins of the second button K2, 1 pin of the second button K2 connects GND, 10 pins of GPRS core cell KS97 connect the 7th resistance R 7, the 7th resistance R 7 connects the anode of the second light emitting diode, the negative electrode of the second light emitting diode connects GND, 18 pins of GPRS core cell KS97 connect one end of the 8th resistance R 8, the other end of the 8th resistance R 8 connects the anode of the 3rd light emitting diode DS3, the negative electrode of the 3rd light emitting diode DS3 connects GND, 19 pins of GPRS core cell KS97 connect one end of the 9th resistance R 9, the other end of the 9th resistance R 9 connects the anode of the 4th light emitting diode DS4, the negative electrode of the 4th light emitting diode DS4 connects GND, other pins of GPRS core cell KS97 are all maked somebody a mere figurehead,

Described processor module, taking processor STM32F103RBT6 as core, has been built respectively reset circuit, crystal oscillating circuit, jtag interface circuit, RS-232 transceiver circuit, decoupling circuit in its periphery, and each power pins of processor is carried out moving back lotus root processing, the power end of processor connects VCC3.3V voltage output end, three UART interfaces in processor module are connected with GPRS transport module, GPS locating module, blood oxygen saturation and Pulse-Parameters collecting unit respectively, wherein RS-232 transceiver circuit comprises: the 14 tantalum capacitor C the 21, the 15 tantalum capacitor C the 22, the 16 tantalum capacitor C the 23, the 17 tantalum capacitor C 24, first serial plug-in unit COM1, a RS-232 transponder chip MAX3232, main processor unit circuit comprises: master chip STM32F103RBT6, the 18 tantalum capacitor C 25, the 19 tantalum capacitor C 26, the 20 tantalum capacitor C 27, the 21 tantalum capacitor C 28, the 22 tantalum capacitor C 29, the 23 tantalum capacitor C 30, the 24 tantalum capacitor C 31, the 25 tantalum capacitor C 32, the 26 tantalum capacitor C 33, the 27 tantalum capacitor C 34, the first crystal oscillator Y1, the second crystal oscillator Y2, the 3rd button K3, the 5th light emitting diode DS5, the tenth resistance R 10, the 11 resistance R 11, jtag interface circuit comprises: JTAG connector JTAG_20, the 12 resistance R the 12, the 13 resistance R the 13, the 14 resistance R the 14, the 15 resistance R the 15, the 16 resistance R the 16, the 28 tantalum capacitor C 35,

1 pin in RS-232 main circuit chip MAX3232 connects one end of the 16 tantalum capacitor C 23, the other end of the 16 tantalum capacitor C 23 connects 3 pins of MAX3232, 4 pins in MAX3232 connect one end of the 17 tantalum capacitor C 24, the other end of the 17 tantalum capacitor C 24 connects 5 pins of MAX3232, 2 pins in MAX3232 connect one end of the 14 tantalum capacitor C 21, the other end of the 14 tantalum capacitor C 21 connects GND, 2 pins in MAX3232 connect one end of the 15 tantalum capacitor C 22, the other end of the 15 tantalum capacitor C 22 connects GND, 13 pins in MAX3232 connect 3 pins of first serial socket COM1, 14 pins in MAX3232 connect 2 pins of first serial socket COM1, 11 pins in MAX3232 connect the PA9 of host processor chip STM32F103RBT6, 12 pins in MAX3232 connect the PA10 of host processor chip STM32F103RBT6, 16 pins in MAX3232 connect VCC5.0V voltage output end, 15 pins in MAX3232 connect GND, other pins in MAX3232 are all maked somebody a mere figurehead, 5 pins of first serial plug-in unit COM1 connect GND,

7 pins of the master chip STM32F103RBT6 of processor module connect one end of the 27 tantalum capacitor C 34 in reset circuit, one end of the tenth resistance R 10,3 pins of the 3rd button K3, and the other end that 1 pin of the 3rd button K3 connects the 27 tantalum capacitor C 34 is to GND; The other end of the tenth resistance R 10 connects one end, the VCC3.3V voltage output end of the 11 resistance R 11, the other end of the 11 resistance R 11 connects the anode of the 5th light emitting diode DS5, and the negative electrode of the 5th light emitting diode DS5 connects 53 pins of processor chips STM32F103RBT6; 5 pins of processor chips STM32F103RBT6 connect one end of the first crystal oscillator Y1, one end of the 23 tantalum capacitor C 30,6 pins of processor chips STM32F103RBT6 connect the other end of the first crystal oscillator Y1, one end of the 24 tantalum capacitor C 31, the equal ground connection of the other end of the other end of the 23 tantalum capacitor C 30 and the 24 tantalum capacitor C 31; 3 pins of processor chips STM32F103RBT6 connect one end of the second crystal oscillator Y2, one end of the 25 tantalum capacitor C 32,4 pins of processor chips STM32F103RBT6 connect the other end of the second crystal oscillator Y2, one end of the 26 tantalum capacitor C 33, the equal ground connection of the other end of the other end of the 23 tantalum capacitor C 32 and the 24 tantalum capacitor C 33; If crystal oscillating circuit starting of oscillation is undesirable, can be at a crystal oscillator Y1 and Y2 two ends resistance respectively in parallel; 13 pins of processor chips STM32F103RBT6 connect one end of the 18 tantalum capacitor C 25, and the other end of the 18 tantalum capacitor C 25 connects 12 pins of processor chips STM32F103RBT6 to GND; 19 pins of processor chips STM32F103RBT6 connect one end of the 19 tantalum capacitor C 26, and the other end of the 19 tantalum capacitor C 26 connects 18 pins of processor chips STM32F103RBT6 to GND; 32 pins of processor chips STM32F103RBT6 connect one end of the 20 tantalum capacitor C 27, and the other end of the 20 tantalum capacitor C 27 connects 31 pins of processor chips STM32F103RBT6 to GND; 48 pins of processor chips STM32F103RBT6 connect one end of the 21 tantalum capacitor C 28, and the other end of the 21 tantalum capacitor C 28 connects 47 pins of processor chips STM32F103RBT6 to GND; 64 pins of processor chips STM32F103RBT6 connect one end of the 22 tantalum capacitor C 29, and the other end of the 22 tantalum capacitor C 29 connects 63 pins of processor chips STM32F103RBT6 to GND;

3 pins of connector JTAG_20 in jtag interface circuit connect 56 pins of processor chips STM32F103RBT6, one end of the 12 resistance R 12, and the other end of the 12 resistance R 12 connects VCC3.3V voltage output end; 5 pins of connector JTAG_20 connect 50 pins of processor chips STM32F103RBT6, one end of the 13 resistance R 13, and the other end of the 13 resistance R 13 connects VCC3.3V voltage output end; 7 pins of connector JTAG_20 connect 46 pins of processor chips STM32F103RBT6, one end of the 14 resistance R 14, and the other end of the 14 resistance R 14 connects VCC3.3V voltage output end; 9 pins of connector JTAG_20 connect 49 pins of processor chips STM32F103RBT6, one end of the 15 resistance R 15, and the other end of the 15 resistance R 15 connects GND; 13 pins of connector JTAG_20 connect 55 pins of processor chips STM32F103RBT6, one end of the 16 resistance R 16, and the other end of the 16 resistance R 16 connects VCC3.3V voltage output end; 1 pin, 2 pins of connector JTAG_20 connect VCC3.3V voltage output end, 2 pins of connector JTAG_20 connect one end of the 28 tantalum capacitor C 35, the other end of the 28 tantalum capacitor C 35 connects 4 pins, 6 pins, 8 pins, 10 pins, 12 pins, 14 pins, 16 pins, 18 pins, 20 pins of connector JTAG_20, and other pins of connector JTAG_20 are all built on stilts.