CN112911991A - Mobile monitoring equipment, mobile monitoring system and monitored body area system - Google Patents

Abstract

A mobile monitoring device (10), a mobile monitoring system (100) and a monitored body area system (1000) are provided, the mobile monitoring device (10) comprises a host (11), the host (11) comprises a host shell (111), a processor (2121) and a first motion sensor (116) which are arranged in the host shell (111), the processor (2121) is electrically connected with the first motion sensor (116), the processor (2121) acquires motion data of a target object wearing the mobile monitoring device (10) according to motion sensing signals generated by the first motion sensor (116), and analyzes the motion amount and/or sleep condition of the target object wearing the mobile monitoring device (10) according to the motion data. The first motion sensor (116) is arranged on the host (11) of the mobile monitoring device (10) and used for sensing the motion data of the patient, and analyzing the motion condition and/or the sleep condition of the patient according to the motion data, so that the patient can be monitored daily more effectively.

Description

Mobile monitoring equipment, mobile monitoring system and monitored body area system Technical Field

The present application relates to the field of physiological parameter monitoring technologies, and in particular, to a mobile monitoring device, a mobile monitoring system, and a monitored body area system.

Background

Most of the existing monitoring systems are bedside monitoring, and in order to ensure the continuity of monitoring data, a patient is bound on a sickbed by accessories such as an electrocardiocable, a blood oxygen probe and the like, so that the patient is not beneficial to rehabilitation after illness. Most of the remote monitoring monitors are worn by being hung on the neck of a patient in the using process, the remote monitoring monitors swing on the body of the patient in the walking process, various monitoring accessories are pulled and wound, and inconvenience is brought to daily life of the patient. In the postoperative rehabilitation process of most patients with diseases, doctors encourage the patients to go to bed more and walk more, so that postoperative recovery is accelerated, but the traditional telemetering monitor cannot provide daily exercise data and/or sleep conditions of the patients for the doctors, and is not beneficial to providing guidance for postoperative recovery of the patients for the doctors.

Disclosure of Invention

The embodiment of the application discloses a mobile monitoring device, a mobile monitoring system and a monitoring body area system, which can detect daily movement data and/or sleep condition of a patient to solve the technical problem.

The embodiment of the application discloses a remove guardianship equipment, including the host computer, the host computer includes the host computer shell and sets up treater and first motion sensor in the host computer shell, the treater with first motion sensor electric connection, the treater basis motion-induced signal acquisition that first motion sensor produced wears the motion data of the target object of mobile guardianship equipment, and basis the motion data analysis is worn the amount of exercise and/or the sleep condition of the target object of mobile guardianship equipment.

The embodiment of the application discloses a remove monitoring system, including electrocardio/breathe lead cable, anti structure and the at least three electrode slice connector of defibrillating, the one end of electrocardio/breathe lead cable is used for connecting a removal monitoring equipment, electrocardio/breathe lead cable from being close to the one end of removing monitoring equipment is to keeping away from it serves one of moving monitoring equipment to serve and to have in proper order the cluster to be equipped with anti structure of defibrillating with at least three electrode slice connector, electrode slice connector is used for the centre gripping electrode slice.

The embodiment of the application discloses a guardianship body area system, includes: the mobile monitoring device comprises at least one mobile monitoring device worn on the body of a target object, wherein at least one mobile monitoring device in the at least one mobile monitoring device comprises a first wireless communication module, the first wireless communication module is used for establishing communication connection between the at least one mobile monitoring device and a second wireless communication module, the at least one mobile monitoring device acquires recovery state parameters corresponding to the target object and transmits the recovery state parameters to the second wireless communication module through the first wireless communication module, and the second wireless communication module is arranged on the target device which is in data communication with the mobile monitoring device.

The utility model provides a remove guardianship equipment, remove guardianship system and guardianship body area system is provided with first motion sensor on removing the host computer of guardianship equipment for the motion data of sensing patient to can go out patient's motion condition and/or sleep condition according to motion data analysis, can more effectually carry out daily guardianship to patient, just at least one removes guardianship equipment and acquires the recovery state parameter that the target object corresponds, and pass through second wireless communication module will recovery state parameter transmits extremely first wireless communication module, wherein, first wireless communication module set up with remove guardianship equipment and carry out on the equipment of data communication. Therefore, the monitoring data of the mobile monitoring equipment can be displayed and/or information prompted on the equipment which is in data communication with the mobile monitoring equipment, and the monitoring effect is better.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a mobile monitoring system according to an embodiment of the present application.

Fig. 2 is a disassembled view of the mobile monitoring system shown in fig. 1.

Fig. 3 is a schematic structural diagram of a mobile monitoring device according to an embodiment of the present application.

Fig. 4 is a schematic structural diagram of a mobile monitoring device in another direction according to the first embodiment of the present application.

Fig. 5 is a schematic view of the mobile monitoring device in the first embodiment of the present application in another orientation with the wristband removed.

Fig. 6 is a schematic structural diagram of a wrist strap module of a mobile monitoring device according to a first embodiment of the present application.

Fig. 7 is a schematic view of a mobile monitoring device according to a second embodiment of the present application in a first direction.

Fig. 8 is a schematic structural diagram of a mobile monitoring device in a second direction according to a second embodiment of the present application.

Fig. 9 is a schematic structural diagram of an electrode sheet connector in an embodiment of the present application.

Fig. 10 is a schematic structural diagram of an electrode sheet connector in another embodiment of the present application.

Fig. 11 is a schematic perspective view of a mobile monitoring device according to an embodiment of the present application.

Fig. 12 is a disassembled perspective view of the mobile monitoring device shown in fig. 11.

Fig. 13 is a schematic cross-sectional view of a mobile monitoring device according to an embodiment of the present application.

Fig. 14 is a schematic cross-sectional view of a mobile monitoring device according to another embodiment of the present application.

Fig. 15 is a schematic cross-sectional view of a parameter measurement circuit board according to an embodiment of the present application.

Fig. 16 is a schematic cross-sectional view of a parameter measurement circuit board according to another embodiment of the present application.

Fig. 17 is a schematic layout diagram of components of a parameter measurement circuit board according to an embodiment of the present application.

Fig. 18 is a schematic diagram illustrating a layout of components of a parameter measurement circuit board after being unfolded according to an embodiment of the present application.

FIG. 19 is a schematic diagram of a mobile monitoring device according to an embodiment of the present application after removing a screen assembly of a front housing.

FIG. 20 is a schematic diagram of a telemetry antenna in an embodiment of the present application.

FIG. 21 is a schematic diagram of a telemetry antenna layout in an embodiment of the present application.

FIG. 22 is a schematic cross-sectional view of a parametric measurement circuit board in another embodiment of the present application.

Fig. 23 is a block diagram of a mobile monitoring system according to another embodiment of the present application.

Fig. 24 is a circuit diagram of a body temperature measuring circuit according to an embodiment of the present application.

Fig. 25 is a schematic circuit diagram of a body temperature measurement circuit during zero resistance verification according to an embodiment of the present application.

FIG. 26 is a schematic circuit diagram of a body temperature measurement circuit during reference resistance verification according to an embodiment of the present application.

Fig. 27 is a schematic circuit diagram of a body temperature measurement circuit according to an embodiment of the present application when performing body temperature measurement.

FIG. 28 is a block diagram of a screen assembly in an embodiment of the present application.

FIG. 29 is a schematic view of a display interface of a display screen of a screen assembly in an embodiment of the present application.

Fig. 30 is a schematic interface diagram of a display screen displaying a battery power state according to an embodiment of the present application.

Fig. 31 is a schematic interface diagram of a display screen in displaying a network connection state according to an embodiment of the present application.

FIG. 32 is a block diagram of a monitored body area system according to an embodiment of the present application.

FIG. 33 is a block diagram of a monitor networking system according to an embodiment of the present application.

FIG. 34 is a block diagram of a monitored body area system according to another embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms "first," "second," and the like in the description and claims of the present application and in the above-described drawings are used for distinguishing between different objects and not for describing a particular order. Furthermore, the terms "comprises" and any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

While the specification concludes with claims describing preferred embodiments of the present application, it is to be understood that the above description is made only for the purpose of illustrating the general principles of the present application and is not intended to limit the scope of the present application. The protection scope of the present application shall be subject to the definitions of the appended claims.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a mobile monitoring system 100 according to an embodiment of the present application. The mobile monitoring system 100 includes a mobile monitoring device 10, an ecg/respiration lead cable 30, an anti-defibrillation structure 50, at least three electrode pad connectors 70, a blood oxygen cable 60, and a blood oxygen probe 90. The mobile monitoring device 10 is connected to one end of the ecg/respiration lead cable 30. The ecg/respiration lead cable 30 is provided with the anti-defibrillation structure 50 and the at least three electrode pad connectors 70 in series from the end close to the mobile monitoring device 10 to the end far from the mobile monitoring device 10. The electrode pad connector 70 is used to clamp the electrode pad 80. In one embodiment, the electrode pad 80 is a disposable electrode pad. It is understood that in another embodiment, the electrode pad 80 is a disposable electrocardioelectrode pad. One end of the blood oxygen cable 60 is connected to the mobile monitoring device 10, and the other end is connected to the blood oxygen probe 90.

In particular, in one embodiment, the mobile monitoring device 10 is a wearable physiological data monitoring device for being worn around the wrist of the target subject to monitor the physiological data signal of the target subject. In this embodiment, the mobile monitoring device 10 can be worn on the wrist of the patient, and a one-wire ecg/respiration lead cable is used to realize the ecg/respiration monitoring function, so that the whole mobile monitoring system 100 is small and portable, and comfortable to wear, and the influence of the mobile monitoring system 100 on the daily life of the target object is minimized. In some of the modified embodiments, the ecg/respiration lead cable 30 may be a single cable structure, and a single ecg/respiration lead cable formed by the defibrillation-resistant structure 50 and the at least three electrode pad connectors 70 may be serially connected in sequence, or a bifurcated cable structure may be used. If the ecg/respiration lead cable 30 is a bifurcated cable structure, the ecg/respiration lead cable 30 includes a main portion and at least three bifurcated portions, one end of the main portion is connected to the mobile monitoring device 10, the other end of the main portion is connected to the at least three bifurcated portions, each bifurcated portion is provided with at least one electrode connector 70, and the defibrillation-resistant structure 50 is disposed at any position on the main portion. Each electrode pad connector 70 is adapted to hold one electrode pad 80, and each electrode pad 80 is adapted to be attached to a portion of the body of a target subject to measure a physiological data signal or an impedance signal of the portion. The anti-defibrillation structure 50 houses a defibrillation protection circuit for protecting the ECG detection system from damage when defibrillation is performed on the target subject's heart if necessary to restore normal heartbeat. In the present application, the anti-defibrillation structure 50 is disposed independently of the mobile monitoring device 10, so that the mobile monitoring device 10 has a small size and is convenient to carry, and meanwhile, the strong current applied to the anti-defibrillation structure 50 is prevented from interfering with the signal in the mobile monitoring device 10.

Referring to fig. 2, in order to fix the mobile monitoring system 100 on the body of the target object, the mobile monitoring system 100 is divided into two parts that are detachably connected, specifically, the anti-defibrillation structure 50 is divided into a first anti-defibrillation part 51 and a second anti-defibrillation part 53. The first anti-defibrillation section 51 and the second anti-defibrillation section 53 are connected to each other to form the anti-defibrillation structure 50. In this embodiment, the first anti-defibrillation unit 51 and the second anti-defibrillation unit 53 are connected to each other by plugging. The first defibrillation-resistant unit 51 is connected to the mobile monitoring apparatus 10 via the ecg/respiration lead cable 30. The second defibrillation-resistant unit 53 is connected to the at least three electrode pad connectors 70 via the ecg/respiration lead cable 30. Accordingly, when the ecg/respiration lead cable 30 and the first defibrillation-resistant section 51 connected to the mobile monitoring device 10 are inserted from the inside of the sleeve of the target subject to the neck of the target subject and the at least three electrode pad connectors 70 are respectively attached to the predetermined portion of the body of the target subject while holding the electrode pads 80 therebetween when the mobile monitoring device 10 is attached to the wrist of the target subject, the ecg/respiration lead cable 30 and the second defibrillation-resistant section 53 connected to the at least three electrode pad connectors 70 are inserted from the inside of the clothes of the target subject to the neck of the target subject and connected to the first defibrillation-resistant section 51, and then the defibrillation-resistant structure 50 is clamped to the collar of the target subject by the clips provided to the first defibrillation-resistant section 51 and/or the second defibrillation-resistant section 53.

Referring also to fig. 3, the mobile monitoring device 10 includes a host 11. The host 11 includes a host housing 111 and a parameter measurement circuit board 112 disposed in the host housing 111. It is to be understood that the parameter measurement circuit board 112 shown in FIG. 3 is merely illustrative. The host 11 further includes a connector 115. The parameter measurement circuit board 112 is connected to the ecg/respiration lead cable 30 through the connector 115. Thus, the parameter measurement circuit board 112 can be electrically connected to the external anti-defibrillation structure 50 through the ecg/respiration lead cable 30.

Specifically, the host 11 further includes an ear portion 117. The ear part 117 is provided at a side of the main chassis 111. In one embodiment, the connector 115 is disposed within the ear portion 117. It is understood that in some of the modified embodiments, the ear portion 117 is a hollow housing, and the connector 115 is detachably mounted in the housing.

Further, the ear part 117 is provided at one end of the main chassis 111. The parameter measurement circuit board 112 is disposed at an end of the main housing 311 adjacent to the ear portion 117. The mobile monitoring device 10 also includes a battery 119. The battery 119 is disposed at an end of the main housing 111 away from the ear portion 117. The battery 119 is electrically connected to the parameter measurement circuit board 112.

Further, the ear portion 117 includes a first ear portion 1171 and a second ear portion 1173. The first ear portion 1171 and the second ear portion 1173 are respectively disposed at both sides of the main chassis 111. The above-described connector 115 includes a first connector 1151 and a second connector 1153. The first connector 1151 is disposed in the first ear portion 1171 and is connected to the parameter measurement circuit board 112. The first connector 1151 is also connected to the blood oxygen probe 90 via the blood oxygen cable 60. The second connector 1153 is disposed within the second ear portion 1173 and is coupled to the parameter measurement circuit board 112. The second connector 1153 is further connected to the at least three electrode pad connectors 70 via the ecg/respiration lead cable 30.

Further, the first ear portion 1171 is provided with a first connection port 1175. The first connector 1175 is connected to the first connector 1151. Accordingly, the first connector 1151 is connected to the blood oxygen cable 60 through the first connector 1175, and is further connected to the blood oxygen probe 90 through the blood oxygen cable 60.

Further, referring to fig. 4, the second ear portion 1173 is provided with a second connection port 1177. The second connection port 1177 is connected to the second connector 1153. Accordingly, the second connector 1153 is connected to the ecg/respiration lead cable 30 through the second connection port 1177, and is further connected to the electrode pad 80 through the ecg/respiration lead cable 30.

Further, in order to connect the blood oxygen cable 60 to the main unit 11 through the shortest path without the need of cable winding, and also to connect the ecg/respiration lead cable 30 to the main unit 11 through the shortest path, when the main unit 11 is worn on the wrist, the first connection port 1175 of the main unit 11 is disposed toward the human finger, and the second connection port 1177 of the main unit 11 is disposed toward the human body; specifically, the first connection port 1175 on the host 11 is oriented opposite to the second connection port 1177 on the host 11. The first connection port 1175 is located on a side of the first ear portion 1171 closer to the bottom end of the main body case 111, and the second connection port 1177 is located on a side of the second ear portion 1173 closer to the top end of the main body case 111.

The top end refers to the front side of the main body case 111 in the use state, specifically, facing the human body when the main body 11 is worn on the wrist, and the bottom end 117 refers to the rear side of the main body case 111 in the use state, specifically, facing the fingers when the main body 11 is worn on the wrist.

In some of these variations, the first ear portion 1171 is a first hollow compartment, and the first connector 1151 is detachably mounted in the first compartment. In some of these variations, the second ear portion 1173 is a second receptacle having a hollow interior, and the second connector 1153 is removably mounted in the second receptacle. Therefore, the blood oxygen accessory of the mobile monitoring system 100, for example, includes the first connector 1151, the blood oxygen cable and the blood oxygen probe 90 connected to the first connector 1151, and the electrocardiograph accessory, for example, includes the second connector 1153, the electrocardiograph cable 30 connected to the second connector 1153, the anti-defibrillation structure 50, the electrode connector 70, etc., which can be plugged in and pulled out, so that the medical staff can select the required monitoring parameters according to the actual situation of the patient, for example, whether to monitor blood oxygen, select three-lead electrocardiograph monitoring or five-lead electrocardiograph monitoring, etc., thereby reducing the influence of physiological monitoring on the daily life of the patient to the greatest extent, improving monitoring comfort, facilitating the medical staff to replace the monitoring accessory, and prolonging the service life of the whole machine.

Referring to fig. 5, the mobile monitoring device 10 further includes a wrist strap module 13. Fig. 5 is a schematic view showing only a part of the structure of the wristband module 13 in one embodiment. The wrist band module 13 is disposed at one side of the main body 11. Specifically, in this embodiment, the wristband module 13 is disposed on the back surface of the host 11. The wrist strap module 13 is used to fix the host computer 11 to a wrist of a target object.

Please refer to fig. 6, which is a schematic structural diagram of the wristband module 13 according to the first embodiment of the present application. The wristband module 13 includes a holder 131 and a wristband 133. The fixing frame 131 is disposed at one side of the main body 11. The fixing bracket 131 fixes the battery 119 between the main chassis 111 and the fixing bracket 131. The wrist band 133 is disposed on a side of the fixing frame 131 away from the main body 11. The wrist band 133 is used to fix the host machine 11 to the wrist of the target object.

Specifically, in some embodiments, the main housing 111 has a closed cavity therein for accommodating the parameter measurement circuit board 112. The battery 119 is disposed on the outer wall of the main chassis 111 and outside the enclosed cavity of the main chassis 111; the holder 131 is connected with the main chassis 111 and holds the battery 119 between the main chassis 111 and the holder 131. The battery 119 is detachably fixed on the host 11 through the fixing frame 131, so that the battery can be conveniently detached and installed, and is very convenient.

Specifically, a guide groove 1311 is provided on a side of the fixing frame 131 facing the main body 11. The guide groove 1311 is used to guide the host computer 11 to be mounted on the fixing frame 131. At least one through hole 1313 is symmetrically formed on one side of the fixing frame 131, which is away from the main body 11. The wrist band 133 is fixed to the holder 131 through the at least one through hole 1313. Preferably, the wrist band 133 is a flexible wrist band. The wrist band 133 may be, but not limited to, a silicone tape, a cloth tape, etc.

The wristband module 13 further includes a flexible rubber pad 135. The flexible rubber pad 135 is disposed on a side of the wrist band 133 away from the fixing frame 131. The flexible gel pad 135 is used to directly contact the skin of the target subject to protect the skin of the target subject.

Please refer to fig. 7 and fig. 8 together, which are schematic structural diagrams of the mobile monitoring device 10a according to another embodiment of the present application. The wrist strap module 13a of the mobile monitoring device 10a is different from the wrist strap module 13 in that the wrist strap module 13a is integrally provided with the host 11. The wristband module 13a is directly extended vertically from the ear 117 of the host 11. The first connector 1151 and the second connector 1153 are respectively provided in the wrist band module 13 a.

Specifically, the wristband module 13a includes two wristbands 133 a. The two wristbands 133a are vertically extended from the first ear portion 1171 and the second ear portion 1173 of the main body 11, and then fastened or adhered to each other to form a loop-shaped band.

Further, in this embodiment, the first connector 1151 is disposed on the wristband 133a adjacent to the first ear portion 1171. The second connector 1153 is disposed on the wristband 133a adjacent the second ear portion 1173. A first connection port 1331a is also formed on the wrist band 133a adjacent to the first ear portion 1171. The first connector 1331a is connected to the first connector 1151, so that the first connector 1151 is connected to the blood oxygen cable 60 via the first connector 1331a, and is further connected to the blood oxygen probe 90 via the blood oxygen cable 60. A second connection opening 1333a is formed in the wrist band 133a adjacent to the second ear portion 1173. The second connection port 1333a is connected to the second connector 1153, so that the second connector 1153 is connected to the ecg/respiration lead cable 30 through the second connection port 1333a, and is further connected to the electrode pad 80 through the ecg/respiration lead cable 30.

Further, the first connection port 1331a is located at a side of the wrist band 133a closer to the bottom end of the main body 11, and the second connection port 1333a is located at a side of the wrist band 133a closer to the top end of the main body 11.

Referring to fig. 9, fig. 9 is a schematic structural diagram of an electrode tab connector 70 according to an embodiment of the present application. The electrode pad connector 70 includes a frame main body 71 and two holding pieces 73 provided inside the frame main body 71. The outer frame host 71 is used for connecting with the electrocardiogram/respiration lead cable 30. The two holding pieces 73 are used for holding the electrode sheet 80.

Specifically, the outer frame main unit 71 is made of a flexible material and has a shape of a square.

Further, the frame main body 71 has a first side portion 711 and a second side portion 713 disposed opposite to each other. The two clamping pieces 73 are respectively disposed on the opposite sides of the first side portion 711 and the second side portion 713. The two holding pieces 73 are oppositely disposed to form a receiving space 731. The receiving space 731 receives and holds the electrode sheet 80. When the outer frame 71 is pinched and the distance between the first side portion 711 and the second side portion 713 is reduced, the accommodating space 731 is increased to release the electrode tab 80.

Further, the two holding pieces 73 are each formed in an L-shaped hook shape, and an O-shaped receiving space 731 is formed between the two holding pieces 73.

Further, the holding piece 73 is stepped. The electrode plate 80 is correspondingly provided with an inverted step. Accordingly, when the electrode tab 80 is held by the holding pieces 73, the inverted step of the electrode tab 80 is engaged with the step of the holding piece 73, so that the electrode tab 80 is stably held between the two holding pieces 73.

Specifically, the electrode sheet connector 70 further includes connection posts 75 disposed at both ends of the outer side of the outer frame main body 71. The connecting post 75 is used for connecting with the electrocardiograph/respiration lead cable 30.

Referring to fig. 10, fig. 10 is a schematic structural diagram of an electrode plate connector 70a according to another embodiment of the present application. The electrode pad connector 70a is different from the electrode pad connector 70 in that the electrode pad connector 70a has only one connection post 75. It is understood that the number of the connection posts 75 may be one if only one end of the electrode pad connector 70a is required to be connected to the ecg/respiration lead cable 30.

In the mobile monitoring device 10 and the mobile monitoring system 100 of the present application, the anti-defibrillation structure 50 is independent of the mobile monitoring device 10, the high current of the anti-defibrillation structure 50 does not affect the function of the mobile monitoring device 10, and the mobile monitoring device 10 can be made thinner and lighter, and is more portable.

Furthermore, to facilitate the placement of the mobile monitoring system 100 on the body of the target subject, the mobile monitoring system 100 is divided into two parts that can be plugged together, i.e., the anti-defibrillation structure 50 is divided into a first anti-defibrillation part 51 and a second anti-defibrillation part 53. The first anti-defibrillation section 51 and the second anti-defibrillation section 53 are connected to each other to form the above-described anti-defibrillation structure 50. The first anti-defibrillation section 51 is also connected to the mobile monitoring device 10 via the ecg/respiration lead cable 30. The second defibrillation-resistant section 53 is also connected to at least three electrode pad connectors 70 via the electrocardiograph/respiration lead cable 30. The mobile monitoring device 10 has at least two different wrist band modules, optionally more. The frame main body 71 of the electrode sheet connector 70 is flexible, and the electrode sheet 80 can be clamped or released by clamping the frame main body, so that the operability is better.

Referring to fig. 11 and 12 together, fig. 11 is a schematic structural diagram of a mobile monitoring device 10 according to another embodiment of the present application, and fig. 12 is a disassembled perspective diagram of the mobile monitoring device 10 according to another embodiment of the present application. Since the mobile monitoring device 10 is used in hospitals, it needs to be sterilized frequently, and it also involves defibrillation of the patient at any time, the main housing 111 is a plastic hollow housing, which is resistant to corrosion and electric shock. Specifically, in one embodiment, the main housing 111 includes a front housing 1111 and a rear housing 1112. The front case 1111 and the rear case 1112 are engaged with each other to form a hollow main housing 111 for accommodating the parameter measurement circuit board 112. The mobile monitoring device 10 also includes a screen assembly 113. The screen component 113 may be a display screen, a touch screen or a touch display screen. In this embodiment, the screen assembly 113 includes a display screen and a touch screen that are stacked. The screen assembly 113 is disposed on the front case 1111. It is understood that, in one embodiment, in order to enhance the overall strength of the main housing 111, the main housing 111 further includes a sheet metal member 1114, the sheet metal member 1114 is disposed between the front housing 1111 and the rear housing 1112, and the sheet metal member 1114 is parallel to the panel assembly 113. The sheet metal member 1114 fixes the shield member 113 to the front case 1111, thereby effectively protecting the shield member 113. It is understood that in one embodiment, to reduce the overall thickness, the back shell 1112 includes only a plastic rim that is secured to the sheet metal 1114. It is understood that in other embodiments, the screen assembly 113 described above may be omitted.

The rear housing 1112 secures the battery 119 on a side facing away from the front housing 1111. Specifically, the battery 119 is disposed at a top end of the rear case 1112 on a side facing away from the front case 1111. The rear case 1112 fixes the front case 1111 and the screen assembly 113 toward one side of the front case 1111, the screen assembly 113 occupies about two thirds of the position of the rear case 1112, and the other third of the position of the rear case 1112 toward one side of the front case 1111 is used to fix the parameter-measuring circuit board 112. Specifically, the parameter-measuring circuit board 112 is disposed at the bottom end of the rear case 1112 on the side facing the front case 1111. Specifically, in one embodiment, the rear housing 1112 is recessed toward the other third of the side of the front housing 1111 to form a receiving groove 1113 for receiving the parameter measurement circuit board 112. The receiving groove 1113 opens toward the front housing 1111. The parameter measurement circuit board 112 is accommodated in the accommodation groove 1113. Further, an electrical bonding portion 2110 is disposed on a side of the parameter measurement circuit board 112 adjacent to the battery 119. The back shell 1112 is provided with a conductive portion 11121 at a position corresponding to the electrical land 2110. The electrical bonding portion 2110 is electrically connected to the battery 119 through the conductive connection portion 11121.

Specifically, referring to fig. 13, the panel assembly 113 and the battery 119 are stacked. The parameter measurement circuit board 112 and the battery 119 are laid flat, and the parameter measurement circuit board 112 includes at least two circuit boards 21 stacked. Thus, the overall thickness of the mobile monitoring device 10 can be reduced. Referring to fig. 14, fig. 14 is a schematic structural diagram of a mobile monitoring device 10 according to another embodiment of the present application. Unlike the above embodiments, in the present embodiment, when the size of the screen assembly 113 of the mobile monitoring device 10 is larger than the size of the battery 119, the parameter measuring circuit board 112 is disposed in parallel with the battery 119, and the screen assembly 113 covers the battery 119 and the parameter measuring circuit board 112. Thus, the size of the screen assembly 113 can be made large, and a smaller overall size can be realized.

Further, the circuit board 21 is a common printed circuit board, and the at least two circuit boards 21 are electrically connected to each other. It is understood that, referring to fig. 15, in one embodiment, the at least two circuit boards 21 are electrically connected through a flexible circuit board 22 a. That is, two adjacent circuit boards 21 are electrically connected to each other through a flexible circuit board 22 a. Referring to fig. 16, in another variant embodiment, the at least two circuit boards 21 are electrically connected through a board-to-board connector 22 b. The board-to-board connector 22b includes a board-to-board plug and a board-to-board socket, and the board-to-board plug and the board-to-board socket are correspondingly connected. It should be noted that the height between the circuit boards 21 at two adjacent points should be less than or equal to the mating height of the board-to-board connector 22 b.

Referring to fig. 17, in one embodiment, the at least two circuit boards 21 include a first circuit board 211, a second circuit board 212, and a third circuit board 213 stacked together. The first circuit board 211 is located on the uppermost layer, the third circuit board 213 is located on the lowermost layer, and the second circuit board 212 is located on the middle layer, that is, the first circuit board 211 is located above the second circuit board 212, the third circuit board 213 is located below the second circuit board 212, and the second circuit board 212 is located between the first circuit board 211 and the third circuit board 213.

Note that, the above-mentioned upper side refers to a top side of the main chassis 111 in the use state, specifically, away from the wrist when the main chassis 11 is worn on the wrist, and the below refers to a bottom side of the main chassis 111 in the use state, specifically, toward the wrist when the main chassis 11 is worn on the wrist.

The first circuit board 211 is provided with a battery interface 2111 and a screen interface 2112. The battery interface 2111 is electrically connected to the battery 119. It is understood that the battery interface 2111 may be electrically connected to the battery 119 directly, or the battery interface 2111 may be electrically connected to the battery 119 through a battery adapter plate, which is not limited herein. The screen interface 2112 is electrically connected to the screen assembly 113. Among other things, the screen interface 2112 may be a display screen interface, a touch screen interface, or a touch display screen interface. In this embodiment, the screen interface 2112 includes a display screen interface and a touch screen interface which are arranged side by side. The screen assembly 113 includes a display screen and a touch screen, wherein the display screen interface is electrically connected to the display screen, and the touch screen interface is electrically connected to the touch screen. Since the battery interface 2111 and the screen interface 2112 are provided on the first circuit board 211 located on the top layer, the difficulty of assembly can be greatly reduced.

The processor 2121 is provided on the second circuit board 212. Specifically, the processor 2121 is disposed on an upper surface or a lower surface of the second circuit board 212. In this embodiment, the processor 2121 includes a first processor 21211 and a second processor 21212. Wherein the first processor 21211 is disposed on the upper surface of the second circuit board 212, and the second processor 21212 is disposed on the lower surface of the second circuit board 212, so as to simultaneously implement the shortest signal flow interaction path between the first processor 21211 and the second processor 21212 and the components on the first circuit board 211 and the second circuit board 212.

In order to leave more space for other components of the mobile monitoring device 10, please refer to fig. 15, the first circuit board 211, the second circuit board 212 and the third circuit board 213 are all double-sided mountable circuit boards, and the smaller the stacking height between the first circuit board 211, the second circuit board 212 and the third circuit board 213 is, the better. Therefore, in processing the layout of the components on the first circuit board 211, the second circuit board 212 and the third circuit board 213, the heights of the different components are taken into full account, and the taller components and the shorter components are located in different receiving spaces, for example, the taller components are placed on the upper surface of the second circuit board 212 facing the first circuit board 211 and the shorter components are placed on the upper surface of the first circuit board 211 facing away from the second circuit board 212, or, as shown in fig. 17, two shorter components correspond to one taller component, for example, the taller component 5 corresponds to two shorter components 4 and 3 arranged oppositely, that is, the taller components arranged on the first circuit board 211, the second circuit board 212 or the third circuit board 213 have a first height value and the sum of the heights of the shorter components arranged respectively on the two opposite circuit boards in the same receiving space as the taller components has And a second height value, wherein a difference value between the first height value and the second height value is smaller than a preset threshold value, so that the accommodating space among the first circuit board 211, the second circuit board 212 and the third circuit board 213 can be fully utilized, and collision of components on the first circuit board 211, the second circuit board 212 and the third circuit board 213 after stacking is avoided, thereby realizing the minimum stacking height of the board cards.

It should be noted that the above-mentioned higher and lower are relative concepts, and because the heights of the components disposed on the first circuit board 211, the second circuit board 212 and the third circuit board 213 are different, there are necessarily components with relatively higher heights and components with relatively lower heights.

Referring to fig. 18, fig. 18 is a schematic plan view of a parameter measurement circuit board 112 according to an embodiment of the present application. The first circuit board 211 is further provided with a key socket 2117. Further, the first circuit board 211 is further provided with a communication interface 2118 and a blood oxygen interface 2119, the parameter measurement circuit board 112 further includes an ecg/respiration side board 214 and a blood oxygen side board 217, the communication interface 2118 is connected to the ecg/respiration side board 214, and the blood oxygen interface 2119 is electrically connected to the blood oxygen side board 217.

Specifically, in one embodiment, the first circuit board 211 has a first side 2113 adjacent the screen assembly 113, a second side 2114 opposite the first side 2113, a third side 2115 connecting the first side 2113 and the second side 2114 and adjacent the first connection port 1175, and a fourth side 2116 opposite the third side 2115. The battery interface 2111, the screen interface 2112 and the key socket 2117 are disposed side by side on the first side 2113. Further, referring to fig. 11, a power button 1115 is further disposed on the top end of the main housing 111. The power button 1115 is electrically connected to the button socket 2117 of the parameter measurement circuit board 112, and the power button 1115 is used for controlling the power of the mobile monitoring device 10.

Further, referring to fig. 18 again, in one embodiment, the communication interface 2118 is disposed on the third side 2115 of the first circuit board 211. The communication interface 2118 is connected to the ecg/respiration side plate 214. The ecg/respiratory side plate 214 is disposed in the first connector 1151. The ecg/respiration side plate 214 is also electrically connected to an anti-defibrillation plate 215 disposed in the anti-defibrillation structure 50.

Further, in one embodiment, the communication interface 2118 is electrically connected to the electro-cardio/respiratory side panel 214 via a first electrical connection 216.

Further, in one embodiment, the blood oxygen interface 2119 is disposed on the fourth side 2116 of the first circuit board 211. The blood oxygen interface 2119 is used for electrically connecting with the blood oxygen side plate 217. The blood oxygen side plate 217 is disposed in the second connector 1153. The blood oxygen side plate 217 is further electrically connected to the blood oxygen probe 90 through the blood oxygen cable 60.

It is understood that, in other embodiments, the positions of the battery interface 2111, the screen interface 2112, the key socket 2117, the communication interface 2118 and the blood oxygen interface 2119 on the first circuit board 211 are not limited to the above description, and may be respectively disposed on other positions of the first circuit board 211.

The blood oxygen interface 2119 of the first circuit board 211 is electrically connected to the blood oxygen side plate 217 through a second electrical connector 218.

The first electrical connector 216 and the second electrical connector 218 are respectively one of a rigid flexible board and a flexible circuit board, and the first electrical connector 216 and the second electrical connector 218 are the same or different.

Further, in one embodiment, the first circuit board 211, the second circuit board 212 and the third circuit board 213 are parallel to each other, as shown in fig. 12 to 17, the ecg/respiration side board 214 and the blood oxygen side board 217 are vertically disposed between the first circuit board 211, the second circuit board 212 and the third circuit board 213, respectively, that is, the ecg/respiration side board 214 is vertically disposed on one side of the first circuit board 211, the second circuit board 212 and the third circuit board 213, and the blood oxygen side board 217 is vertically disposed on the other side of the first circuit board 211, the second circuit board 212 and the third circuit board 213, so that the number of stacked board cards can be reduced, and the overall thickness and the assembly difficulty of the mobile monitoring device 10 can be reduced.

Further, a telemetry antenna circuit 21112 and a telemetry antenna socket 21113 are provided on the upper surface of the first circuit board 211. The telemetry antenna circuit 21112 is located between the NFC circuit 21110 and the communication interface 2118. The telemetry antenna socket 21113 is positioned between the WMTS circuitry 21112 and the second side 2114. Referring to fig. 19, the mobile monitoring device 10 further includes an antenna disposed in the main housing 111 and electrically connected to the parameter measurement circuit board 112. In this embodiment, the antenna comprises a telemetry antenna 41. The WMTS circuit 21112 is coupled to the telemetry antenna 41 through the telemetry antenna socket 21113.

Specifically, referring to fig. 3 and 19, in one embodiment, the main housing 111 includes a plurality of inner sidewalls 1110 and a plurality of ear portions 117, the telemetry antenna 41 is disposed on at least one of the inner sidewalls 1110 and/or at least one of the ear portions 117, and a predetermined portion of the telemetry antenna 41 extends along an extending direction of at least one of the inner sidewalls 1110 and/or at least one of the ear portions 117 by a predetermined length.

The inner sidewalls 1110 include one or more inner sidewalls 1110. The plurality of ear portions 117 include one or more ear portions, such as the first ear portion 1171 and the second ear portion 1173.

In this embodiment, the telemetry antenna 41 is a WMTS (wireless medical telemetry service) antenna, and the operating frequency thereof is less than or equal to 1 GHz. It will be appreciated that in other embodiments, the telemetry antenna 41 may also be an ISM antenna or the like. Specifically, the telemetry antenna 41 is plugged into the telemetry antenna socket 21113 through a cable or a flexible circuit board, and is further electrically connected to the telemetry antenna circuit 21112.

Therefore, in the present application, the telemetry antenna 41 is disposed in the main chassis 111, and the predetermined portion of the telemetry antenna 41 extends along the extending direction of at least one of the inner sidewalls 1110 and/or at least one of the ears 117 by a predetermined length, the inner sidewalls 1110 or ears 117 of the main chassis 111 provide a sufficient clearance area for the telemetry antenna, which not only improves the antenna performance, but also effectively reduces the interference of the human body to the antenna signal and improves the antenna performance because the telemetry antenna 41 is disposed in the main chassis 111 without directly contacting with the human body, and further, because the telemetry antenna 41 consumes less energy than WIFI, thereby effectively improving the cruising ability of the device, expanding the range of the patient, and facilitating the physical rehabilitation of the patient.

Specifically, referring to fig. 20, in one embodiment, the telemetry antenna 41 is a flat structure as a whole. The telemetry antenna 41 includes a connection portion 411 and at least one wing portion 413 connected to the connection portion 411. The predetermined location is the at least one wing 413. The connecting portion 411 is disposed inside the main housing 111, specifically between the front housing 1111 and the rear housing 1112, and the at least one wing portion 413 is disposed at the at least one inner sidewall 1110 or the at least one ear portion 117 and extends a predetermined length along an extending direction of the at least one inner sidewall 1110 or the at least one ear portion 117.

Specifically, referring to fig. 19, in one embodiment, the main housing 111 includes a first side 111a and a second side 113a disposed opposite to each other. The inner sidewall 1110 includes at least one inner sidewall 1110 located on the first side 111a and/or the second side 113a, and when the at least one wing part 413 is disposed on the at least one inner sidewall 1110, each wing part 413 of the at least one wing part 413 is disposed adjacent to a corresponding inner sidewall 1110 of the at least one inner sidewall 1110 and extends a predetermined length along an extending direction of the corresponding inner sidewall 1110.

Specifically, in one embodiment, the plane of the at least one wing 413 is parallel to the plane of the connecting portion 411, and each wing 413 is perpendicular to the corresponding inner sidewall 1110. Thus, the telemetry antenna 41 is generally U-shaped and generally planar.

It is understood that, in one variant embodiment, the plane of the at least one wing 413 is perpendicular to the plane of the connecting portion 411, and each wing 413 is parallel to the corresponding inner sidewall 1110 and extends along the corresponding inner sidewall 1110. Accordingly, the at least one wing 413 is bent 90 degrees relative to the connection portion 411 and extends to fit the corresponding inner sidewall 1110. This increases the antenna headroom and saves space.

Specifically, in one embodiment, the at least one wing part 413 includes a first wing part 4131 and a second wing part 4133, and the first wing part 4131 and the second wing part 4133 are disposed on opposite sides of the connecting portion 411. The at least one inner sidewall 1110 includes a first inner sidewall 1110a on the first side 111a and a second inner sidewall 1110b on the second side 113 a. The first wing part 4131 and the second wing part 4133 are respectively disposed close to the first inner sidewall 1110a and the second inner sidewall 1110b, and respectively extend a predetermined length in an extending direction of the first inner sidewall 1110a and the second inner sidewall 1110b, and the extending direction of the first wing part 4131 and the second wing part 4133 is perpendicular to the extending direction of the long side of the connecting portion 411. The long side of the connecting portion 411 is parallel to the bottom end of the main chassis 111.

Referring to fig. 12, 19 and 20, in one embodiment, the front shell 1111 has a front shell protruding edge, the rear shell 1112 has a rear shell protruding edge corresponding to the front shell protruding edge, and when the rear shell 1112 and the front shell 1111 are fastened, the rear shell protruding edge and the front shell protruding edge are fastened to form the ear portion 117. The ear 117 has a receiving space formed therein. When the at least one wing part 413 is disposed at the at least one ear part 117, the at least one wing part 413 is disposed in the accommodating space and extends for a predetermined length.

Specifically, in one embodiment, the at least one wing part 413 includes a first wing part 4131 and a second wing part 4133, and the first wing part 4131 and the second wing part 4133 are disposed on opposite sides of the connecting portion 411. The main chassis 111 includes a first side 111a and a second side 113a disposed opposite to each other. The at least one ear portion 117 includes a first ear portion 1171 disposed on the first side 111a and a second ear portion 1173 disposed on the second side 113 a. The first wing portion 4131 and the second wing portion 4133 are respectively disposed in the receiving space formed by the first ear portion 1171 and the second ear portion 1173, and extend a predetermined length in the first ear portion 1171 and the second ear portion 1173, and the extending direction of the first wing portion 4131 and the second wing portion 4133 is perpendicular to the extending direction of the connecting portion 411.

Specifically, referring to fig. 12, the front shell 1111 is formed by a first front shell protruding edge 1111a protruding outward from the first side 111 a. The front shell 1111 is formed with a second front shell protruding edge 1111b protruding outward from the second side 113 a. A first rear case ledge 1112a is disposed on the rear case 1112 corresponding to the first front case ledge 1111 a. A second rear case ledge 1112b is disposed on the rear case 1112 corresponding to the second front case ledge 1111 b. When the rear shell 1112 and the front shell 1111 are fastened, the first front shell ledge 1111a cooperates with the corresponding first rear shell ledge 1112a to form the first ear portion 1171; the first rear shell ledge 1112a cooperates with the corresponding second rear shell ledge 1112b to form the second ear portion 1173. The first wing part 4131 is disposed in the receiving space between the first front shell ledge 1111a and the first rear shell ledge 1112a, and may be fixed to the first front shell ledge 1111a or the first rear shell ledge 1112 a. The second wing part 4133 is disposed in the receiving space between the second front case ledge 1111b and the second rear case ledge 1112b, and can be fixed to the second front case ledge 1111b or the second rear case ledge 1112 b.

Further, in one of the modified embodiments, one of the first wing-shaped part 4131 and the second wing-shaped part 4133 extends on the first inner side wall 1110a or the second inner side wall 1110b, and the other extends in the second ear part 1173 or the first ear part 1171.

It is understood that, in one variant embodiment, the first wing part 4131 and the second wing part 4133 may be disposed at two adjacent sides of the connecting portion 411. One of the first wing part 4131 and the second wing part 4133 extends on the first inner sidewall 1110a or the second inner sidewall 1110b, and the other wing part extends on the top end and the bottom end of the main chassis 111 in a direction parallel to the connection part 411.

Further, in one embodiment, the connecting portion 411 is disposed above the parameter-measuring circuit board 112, is located between the front shell and the parameter-measuring circuit board 112, and extends along a direction perpendicular to an extending direction of the at least one wing 413. The plane of the connecting portion 411 is parallel to the display surface of the panel assembly 113.

Further, referring to fig. 21, a circuit coupling node 4111 coupled to the parameter measurement circuit board 112 is disposed on the connecting portion 411. The parameter measurement circuit board 112 is provided with an elastic contact pin. The circuit coupling node 4111 of the connecting portion 411 corresponds to the elastic contact pin, and when the front housing 1111 is fastened to the rear housing 1112, the front housing 1111 applies a pressure to the connecting portion 411 to urge the circuit coupling node 4111 of the connecting portion 411 to electrically contact the elastic contact pin, thereby achieving a stable electrical connection. It is understood that the elastic contact pin has an elastic expansion direction perpendicular to the parallel direction of the connection portion 411, that is, the elastic expansion direction of the elastic contact pin is perpendicular to the display surface of the panel assembly 113.

Specifically, when the telemetry antenna 41 is an FPC antenna, the telemetry antenna 41 includes an antenna base 414 and a plurality of metal wires 415 disposed in series on the antenna base 414. The plurality of metal lines 415 are sequentially arranged along the surface of the antenna substrate 414 and electrically connected to the circuit coupling node 4111 to form the telemetry antenna 41. The plurality of metal lines 415 have different widths, and the metal lines 415 arranged in parallel are separated from each other by a spacing band with a certain width.

It will be appreciated that in one variation, the telemetry antenna 41 is not limited to a WMTS antenna, but may be another type of antenna, such as an ISM antenna. That is, the mobile monitoring device 10 further includes an antenna disposed in the main housing 111 and electrically connected to the parameter-measuring circuit board 112, wherein the antenna includes a connecting portion 411 and at least one wing 413 connected to the connecting portion 411, the connecting portion 411 is disposed in the main housing 111, the antenna is disposed at least one of the ear portions 117, and the at least one wing 413 extends along an extending direction of at least one of the ear portions 117 by a predetermined length.

It will be appreciated that, in one variant, when the telemetry antenna 41 is an FPC antenna, the at least one wing 413 is respectively disposed within the at least one ear 117 and is attached to the inside of the front housing ledge, in particular to the side facing the rear housing ledge. In another variant, when the telemetry antenna 41 is an LDS antenna, the at least one wing 413 is plated on the inner side of the front housing ledge, in particular on the side facing the rear housing ledge. Thus, the antenna structure is further simplified.

Further, referring to fig. 18 again, an NFC (Near Field Communication) circuit 21110 and an NFC antenna socket 21111 are further disposed on the first circuit board 211. The NFC circuit 21110 is provided at a substantially central position on the upper surface of the first circuit board 211. The NFC antenna socket 21111 is located between the NFC circuit 21110 and the blood oxygen interface 2119.

Referring again to fig. 12, 19 and 20, the mobile monitoring device 10 further includes an NFC antenna 42. The NFC antenna 42 is disposed between the screen assembly 113 and the rear case 1112. That is, the NFC antenna 42 is disposed below the screen assembly 113 and electrically connected to the parameter measurement circuit board 112. Specifically, the NFC antenna 42 is disposed parallel to the display surface of the screen assembly 113. The NFC antenna 42 is plate-shaped, extends from a side close to the top end to a side close to the receiving groove 1113, and is electrically connected to the NFC antenna socket 21111 through a cable or a flexible circuit board, and further electrically connected to the NFC circuit 21110 through the NFC antenna socket 21111. Therefore, the NFC antenna 42 is placed below the screen component 113 to provide a sufficient arrangement space for the NFC antenna 42, and the NFC antenna 42 can be made to have a relatively large size, and the NFC antenna 42 can be directly led to the outside through the screen component 113, so that the magnetic field coupling characteristic of the NFC antenna 42 can be well utilized, that is, the NFC antenna 42 has a large requirement on the area, but has a low requirement on the thickness and the metal sensitivity, and reduces data interference with other antennas.

Further, referring to fig. 18 again, the first motion sensor 116 is disposed on the upper surface of the first circuit board 211. In one embodiment, the first motion sensor 116 is disposed adjacent to the second side 2114 and between the NFC circuit 21110 and the blood oxygen interface 2119. The first motion sensor 116 is used to sense the acceleration of motion after the mobile monitoring device 10 is worn by the user. It will be appreciated that in other embodiments, the first motion sensor 116 described above may also be disposed on the second circuit board 212.

The processor 2121 is electrically connected to the first motion sensor 116, and the processor 2121 acquires motion data of the target subject wearing the mobile monitoring device 10 according to the motion sensing signal generated by the first motion sensor 116, and analyzes the amount of motion and/or the sleep condition of the target subject wearing the mobile monitoring device 10 according to the motion data.

In one embodiment, the first motion sensor 116 may record the motion data of the target object in real time. Accordingly, the processor 2121 can analyze the motion amount and/or the sleep condition of the target object according to the motion data obtained by the first motion sensor 116, so as to be used for performing ERAS (accelerated recovery surgery), which is helpful for rapid rehabilitation of the target object. Meanwhile, in the process of analyzing and calculating the ecg/respiration and blood oxygen data by the processor 2121, the motion data obtained by the first motion sensor 116 may be combined to perform data processing so as to eliminate the interference of the motion on the blood oxygen data and the ecg/respiration data of the target subject wearing the mobile monitoring device 10, thereby providing a more accurate analysis result.

Further, the second circuit board 212 is further provided with a bluetooth circuit 2122 and a bluetooth antenna socket 2123. The bluetooth antenna socket 2123 is disposed at an edge of the second circuit board 212 to facilitate connection with a bluetooth antenna. Preferably, the bluetooth antenna socket 2123 is disposed on an edge of the second circuit board 212 on a side close to the screen assembly 113. Referring again to fig. 12, 19 and 20, the mobile monitoring device 10 further includes a bluetooth antenna 43. The bluetooth circuit 2122 is connected to the bluetooth antenna 43 via the bluetooth antenna socket 2123. The working frequency band of the bluetooth antenna 43 is about 2.4 GHz. The bluetooth antenna 43 is disposed in the rear housing 1112 and adjacent to the top end of the main housing 111, and is electrically connected to the parameter measurement circuit board 112. Specifically, the bluetooth antenna 43 is electrically connected to the bluetooth antenna socket 2123 through a cable or a flexible circuit board, and further electrically connected to the bluetooth circuit 2122. Specifically, in one embodiment, the bluetooth antenna 43 is disposed parallel to the display surface of the screen assembly 113, perpendicular to the plane of the top end of the main housing 111, and adjacent to the top end of the main housing 111. Specifically, in one embodiment, the bluetooth antenna 43 is disposed between the sheet metal part 1114 and the rear housing 1112 and adjacent to the top end of the main housing 111, and an avoiding groove 1114a is disposed at a position of the sheet metal part 1114 corresponding to the bluetooth antenna 43 to allow the bluetooth antenna 43 to be exposed from the avoiding groove 1114 a. Therefore, the influence of the sheet metal part 1114 on the antenna performance of the bluetooth antenna 43 can be avoided.

Further, a blood oxygen module 2124 is disposed on the second circuit board 212. The blood oxygen module 2124 is electrically connected to the blood oxygen interface 2119. It is understood that in one embodiment, the blood oxygen module 2124 is disposed on a side of the second circuit board 212 close to the blood oxygen side board 217. Thus, the shortest signal flow interaction path is achieved between blood oxygen module 2124 and blood oxygen interface 2119.

Further, a WIFI (Wireless-Fidelity) circuit 2131 and a WIFI antenna socket 2132 are disposed on the third circuit board 213. Further, in one embodiment, the WIFI circuit 2131 is disposed on a substantially central position of the third circuit board 213. The WIFI antenna socket 2132 is disposed at an edge of the third circuit board 213 for convenient insertion.

Referring again to fig. 12, 19 and 20, the mobile monitoring device 10 further includes a WIFI antenna 44. The operating frequency band of the WIFI antenna 44 is about 2.4 GHz. The WIFI antenna 44 is disposed in the rear case 1112 and adjacent to the bottom end of the main case 111, and is electrically connected to the parameter measurement circuit board 112, and the WIFI antenna 44 and the telemetry antenna 41 are disposed at an interval. Specifically, the WIFI antenna 44 is electrically connected to the WIFI antenna socket 2132 through a cable or a flexible circuit board, and further electrically connected to the WIFI circuit 2131 through the WIFI antenna socket 2132. The plane on which the WIFI antenna 44 is located is parallel to the plane on which the side wall of the bottom end of the main chassis 111 is located, that is, the plane on which the WIFI antenna 44 is located is perpendicular to the plane on which the screen assembly 113 is located.

Specifically, in one embodiment, the WIFI antenna 44 is parallel to the bottom end of the main chassis 111.

Specifically, in one embodiment, a receiving slot 1113 with an opening facing the front housing 1111 is disposed on a side of the rear housing 1112 adjacent to the bottom end of the main housing 111, the parameter-measuring circuit board 112 is received in the receiving slot 1113, and the WIFI antenna 44 is disposed in the receiving slot 1113 and attached to a side wall of the receiving slot 1113 adjacent to the bottom end of the main housing 111.

Further, in one of the variant embodiments, the WIFI antenna 44 and the bluetooth antenna 43 may be implemented by a common antenna. Specifically, the common antenna may be disposed at the top end or the bottom end of the main chassis 111, and the common antenna is time-division controlled by the processor 2121, that is, functions of the bluetooth antenna 43 and the WIFI antenna 44 are respectively implemented in different time periods. For example, the WIFI function is turned off and the Bluetooth function is turned on in the first time period, the Bluetooth function is turned off and the WIFI function is turned on in the second time period, and the switching between the WIFI function and the Bluetooth function is performed in such a reciprocating manner. It can be understood that the first time period and the second time period are in the millisecond level, so that the user does not feel that the WIFI function and the bluetooth function are time-sharing controlled at all, and the user experience is not affected, but an antenna can be omitted, the cost is reduced, the internal space of the main chassis 111 is increased, and a larger space is provided for the arrangement of other elements in the main chassis 111.

Further, referring to fig. 18 again, a memory module 2133 is further disposed on the third circuit board 213, wherein the memory module 2133 may be, but is not limited to, an SD card and a flash memory. In this embodiment, the storage module 2133 includes an SD card 21331 and a flash memory 21332. The storage module 2133 is used for storing any data processed by the first processor 21211 and the second processor 21212 in the data processing.

Further, a buzzer socket 2134 is further disposed on the third circuit board 213. The mobile monitoring device 10 also includes a speaker. The buzzer socket 2134 is used for electrical connection with the speaker.

It is understood that other components can be disposed on the first circuit board 211, the second circuit board 212 and the third circuit board 213 of the parameter measurement circuit board 112, and are not described in detail since they are not relevant to the present application.

The anti-defibrillation board 215 is provided with an electrocardiogram/respiration measuring circuit 2151 and a third processor 2152. The electrocardio/respiration measuring circuit 2151 is connected with the communication interface 2118 of the first circuit board 211 through the electrocardio/respiration side plate 214. The side plate 214 is provided with an analog-to-digital conversion circuit 2141. The electrocardio/respiration measuring circuit 2151 is electrically connected to the electrode plate 80. The electrocardiogram/respiration measuring circuit 2151 is configured to collect electrocardiogram/respiration signals through the electrode slice 80 and send the signals to the third processor 2152 for processing to obtain electrocardiogram/respiration data, the third processor 2152 sends the obtained electrocardiogram/respiration data to the electrocardiogram/respiration side plate 214, and the analog-to-digital conversion circuit 2141 on the electrocardiogram/respiration side plate 214 converts the electrocardiogram/respiration data into data signals and sends the data signals to the processor 2121 of the parameter measuring circuit board 112 for processing. In this embodiment, the ecg/respiration measurement circuit 2151 integrates units having functions of filtering and amplifying parameters, acquiring parameters, and preprocessing parameters.

Wherein the anti-defibrillation board 215 is provided with a second motion sensor 2153. The second motion sensor 2153 is electrically connected to the third processor 2152. Since the anti-defibrillation structure 50 is clamped on the collar of the patient, the second motion sensor 2153 in the anti-defibrillation structure 50 can more accurately measure the motion data of the patient without being interfered by the motion of the arm of the patient, so that the motion amount and/or sleep condition of the patient can be accurately analyzed.

Further, referring to fig. 23, a body temperature measuring circuit 56 is further disposed on the third circuit board 213. The body temperature measuring circuit 56 is electrically connected to the third processor 2152. The body temperature measuring circuit 56 is also electrically connected to a body temperature measuring probe 57. The body temperature probe 57 is electrically connected to the body temperature measurement circuit 56 in the anti-defibrillation structure 50 through a cable, and the body temperature probe 57 is used for extending to a predetermined portion of the patient, for example, the armpit of the patient, to perform body temperature detection. It is understood that in one embodiment, the anti-defibrillation structure 50 is provided with a body temperature measurement probe 57 interface, and the body temperature measurement probe 57 interface is electrically connected to the body temperature measurement circuit 56. The thermometer probe 57 is disposed on the anti-defibrillation structure 50 through the thermometer probe 57 interface. Therefore, when the body temperature monitoring is not needed, the body temperature measuring probe 57 can be pulled off from the anti-defibrillation structure 50, which brings convenience to the actual operation.

Thus, in order to achieve the reliability of a pluggable ecg accessory for long-term use, the present application places the ecg/respiration measurement circuit 2151 on the anti-defibrillation structure 50 on the ecg/respiration lead cable 30, rather than in the mobile monitoring device 10, which brings many advantages to the mobile monitoring system 100 a: the pluggable interface between the defibrillation resisting structure 50 and the mobile monitoring device 10 is a digital communication interface instead of an analog signal, so that the requirements of the contact impedance, the safety distance, the number of the Pin needles, the insulation impedance between the Pin needles and the like of the butting plug-in are reduced, and the reliability of the product in long-term use is improved; the anti-defibrillation circuit is placed in the independent anti-defibrillation structure, so that the requirement of a safety electric gap and the area of the board card in the mobile monitoring equipment are reduced, the size and the weight of the mobile monitoring equipment are reduced, and the wearing comfort of a patient is improved; because the anti-defibrillation structure 50 is fixed on the trunk of the patient, the first motion sensor 116 and the second motion sensor 2153 are respectively disposed in the mobile monitoring device 10 and the anti-defibrillation structure 50, so that motion false detection caused by arm motion can be effectively reduced, and the statistical accuracy of the motion time and the sleep time of the patient can be improved. The body temperature measuring circuit 56 is placed inside the anti-defibrillation structure 50, so that the length of a cable of the body temperature measuring probe can be shortened, the armpit temperature of a patient can be conveniently measured, and the wearing comfort is further improved.

It is understood that in yet another variant embodiment, the anti-defibrillation board 215 may be omitted and all components on the anti-defibrillation board 215 may be preferentially arranged on the first circuit board 211. Of course, if the first circuit board 211 does not have enough space to arrange the components originally disposed on the anti-defibrillation board 215, a portion of the components may be allowed to be arranged on the second circuit board 212 and/or the third circuit board 213.

It will be appreciated that since the first motion sensor 116 is already disposed on the first circuit board 211, when the anti-defibrillation pad 215 is omitted, the second motion sensor 2153 originally disposed on the anti-defibrillation pad 215 may be omitted accordingly.

It is to be understood that, in yet another variant embodiment, when the at least two circuit boards 21 include only the first circuit board 211 and the second circuit board 212, the WIFI circuit 2131 and the WIFI antenna socket 2132 are disposed on the second circuit board 212. At this time, the first processor 21211 and the second processor 21212 may be disposed on the first circuit board 211, may be disposed on the second circuit board 212, and may be disposed on the first circuit board 211 and the second circuit board 212, respectively, specifically determined by the shortest signal flow interaction path and the arrangement space of the first circuit board 211 and the second circuit board 212. The memory module 2133 and the buzzer socket 2134 may also be disposed on the second circuit board 212, and may be staggered from the blood oxygen module 2124 originally disposed on the second circuit board 212, or disposed at an empty position of the first circuit board 211.

It is to be understood that, in another variant embodiment, when the at least two circuit boards 21 only include the first circuit board 211 and the second circuit board 212, the bluetooth circuit 2122 and the bluetooth antenna socket 2123 may be disposed on the first circuit board 211.

It is to be understood that, in another variant embodiment, when the at least two circuit boards 21 only include the first circuit board 211 and the second circuit board 212, the WIFI circuit 2131 and the WIFI antenna plug 2132 are disposed on the first circuit board 211, and the bluetooth circuit 2122 and the bluetooth antenna plug 2123 are disposed on the second circuit board 212.

In order to further save the thickness space of the board card and reduce the number of stacked layers of the board card, please refer to fig. 22, the third circuit board 213 is vertically disposed and can be juxtaposed with the first circuit board 211 and the second circuit board 212 which are stacked, and the third circuit board 213 is disposed perpendicular to the first circuit board 211 and the second circuit board 212. Therefore, the number of stacking layers of the board cards can be further reduced, and the thickness space of the board cards is saved. It is understood that some connectors may be preferentially disposed on the third circuit board 213 when the third circuit board 213 is vertically disposed. At this time, the WIFI circuits 2131 and 2132, the bluetooth circuits 2122 and 2123, the WMTS circuits 21112 and the telemetry antenna socket 21113, and the NFC circuits 21110 and the NFC antenna sockets 21111 are arranged on the first circuit board 211 and the second circuit board 212, as in the case where the at least two circuit boards 21 only include the first circuit board 211 and the second circuit board 212.

It can be understood that, since the first circuit board 211, the second circuit board 212 and the third circuit board 213 stacked up and down pass through the flexible circuit board 22a or the board-to-board connector 22b, in order to avoid the height of the adjacent circuit boards from being changed due to the compression of the first circuit board 211, the second circuit board 212 and the third circuit board 213, the support columns are further disposed between the adjacent circuit boards to support the adjacent circuit boards.

It is to be understood that, in the above embodiments, the number of layers of the circuit boards stacked and disposed in the parameter measurement circuit board 112 is not limited to two or three layers, and may be multiple layers.

It is understood that, in the above embodiments, the dimensions of the first circuit board 211, the second circuit board 212 and the third circuit board 213 included in the parameter measurement circuit board 112 may be any desired size, and are not limited herein.

Specifically, please refer to fig. 23, fig. 23 is a schematic structural diagram of a mobile monitoring system 100a according to a second embodiment of the present application. The mobile monitoring system 100a differs from the mobile monitoring system 100 in that the mobile monitoring system 100a further includes a body temperature measurement circuit 56 disposed in the anti-defibrillation structure 50. The mobile monitoring system 100a further includes a body temperature measurement probe 57. The temperature probe 57 is electrically connected to the temperature measurement circuit 56 and exits the anti-defibrillation structure 50 to extend to a predetermined portion of the patient, such as the armpit, for temperature sensing. Wherein the thermistor Rx of the body temperature measuring circuit 56 is disposed in the body temperature measuring probe 57, so that when the body temperature measuring probe 57 extends to a predetermined portion of a patient, for example, the armpit, and a body temperature is detected, a body temperature value of the predetermined portion of the patient can be determined according to a resistance value change of the thermistor Rx.

It will be appreciated that the temperature measurement probe 57 described above is removably connected to the anti-defibrillation structure 50 described above for ease of use.

Referring to fig. 24, fig. 24 is a circuit diagram of a body temperature measuring circuit 56 according to an embodiment of the present application. Specifically, the body temperature measuring circuit 56 includes a power supply module 61, a temperature sensing module 62, and a measurement control module 63. The power module 61 is electrically connected to the temperature sensing module 62, and the temperature sensing module 62 is electrically connected to the measurement control module 63. The temperature sensing module 62 includes a thermistor Rx, a reference resistor R1, and a zero resistor R0 connected in series in this order. The thermistor Rx is adjacent to the power module 61, the zero resistor R0 is distant from the power module 61, and the reference resistor R1 is located between the thermistor Rx and the zero resistor R0. The temperature sensing module 62 includes a measurement input 621 at an end of the thermistor Rx remote from the reference resistor R1. When the body temperature is measured, the power module 61 is conducted with the measurement input end 621 of the temperature sensing module 62. The current of the power module 61 flows through the thermistor Rx, the reference resistor R1 and the zero resistor R0. The measurement control module 63 calculates the resistance of the thermistor Rx according to the voltages applied to the thermistor Rx, the reference resistor R1 and the zero resistor R0, and determines a corresponding body temperature value according to the resistance of the thermistor Rx.

Therefore, when the body temperature is measured, the current flowing through the zero resistor R0, the reference resistor R1 and the thermistor Rx from the power module 61 is the current at the same time, the resistance value of the thermistor Rx is calculated by the measurement control module 63 according to the voltages applied to the zero resistor R0, the reference resistor R1 and the thermistor Rx, and the body temperature value is obtained by back-checking the characteristic curve of the thermistor Rx according to the resistance value of the thermistor Rx, so that the measured body temperature value is more accurate.

Specifically, in one embodiment, the temperature sensing module 62 includes a calibration gain input 622 between the thermistor Rx and the reference resistor R1 and a calibration zero input 623 between the reference resistor R1 and the zero resistor R0. The end of the zero resistor R0 remote from the reference resistor R1 is grounded, the voltage between the zero calibration input 623 and ground is a first voltage V0, the voltage between the gain calibration input 622 and ground is a second voltage V1, and the voltage between the measurement input 621 and ground is a third voltage V2. The measurement control module 63 calculates the resistance of the thermistor Rx according to the first voltage V0, the second voltage V1, the third voltage V2, and the resistance of the reference resistor R1.

Specifically, in one embodiment, the power module 61 is a constant current source. It is understood that, in one of the modified embodiments, the resistance of the thermistor Rx will change according to the change of the body temperature during the actual measurement process, but the resistance of the thermistor Rx will be kept constant after the measurement time reaches a preset time, for example, 5 minutes, and the resistance of the thermistor Rx will reach the balance with the body temperature of the patient. Therefore, the power module 61 can be replaced by a constant voltage source, and the functions of the constant voltage source and the constant current source are basically the same when the resistance of the thermistor Rx is balanced with the body temperature of the patient.

Specifically, in one embodiment, the zero resistor R0, the reference resistor R1, and the thermistor Rx are respectively implemented by one resistor, or two or more resistors connected in series or in parallel.

Further, the measurement control module 63 includes an a/D sampling unit 631 and a controller 632. The a/D sampling unit 631 samples the first voltage V0, the second voltage V1 and the third voltage V2 each time the body temperature is measured, and the controller 632 calculates the resistance value of the thermistor Rx according to the first voltage V0, the second voltage V1 and the third voltage V2 sampled by the a/D sampling unit 631 and the resistance value of the reference resistor R1, so that the body temperature measurement is more accurate.

Specifically, the a/D sampling unit 631 further converts the first voltage V0, the second voltage V1 and the third voltage V2 into digital signals that can be processed by the controller 632 after sampling the first voltage V0, the second voltage V1 and the third voltage V2, and the controller 632 calculates the resistance of the thermistor Rx according to the digital signals of the first voltage V0, the second voltage V1 and the third voltage V2 and the resistance of the reference resistor R1.

Further, the temperature sensing module 62 further includes an excitation source switch 624. The first excitation terminal of the excitation source switch 624 is connected to the power module 61, and the second excitation terminal is selectively connected to the measurement input terminal 621, the calibration gain input terminal 622, or the calibration zero input terminal 623. When measuring the body temperature, the second excitation terminal of the excitation source switch 624 is switched to be conductive with the measurement input terminal 621, the current of the power module 61 simultaneously flows through the zero resistor R0, the reference resistor R1 and the thermistor Rx, and the controller 632 calculates the resistance value of the thermistor Rx according to the resistance values of the first voltage V0, the second voltage V1, the third voltage V2 and the reference resistor R1 sampled by the a/D sampling unit 631.

Specifically, in one embodiment, the excitation source switch 624 includes a digital control type single-pole-three-throw switch, one end of the digital control type single-pole-three-throw switch serves as the first excitation end and is electrically connected to the power module 61, and the other end of the digital control type single-pole-three-throw switch serves as the second excitation end and includes a moving contact and three stationary contacts, the three stationary contacts are electrically connected to the zeroing input end 623, the gain calibration input end 622 and the measurement input end 621 respectively, and the moving contact is selectively electrically connected to the three stationary contacts to connect the zeroing input end 623, the gain calibration input end 622 and the measurement input end 621 respectively.

It is understood that, in one of the variant embodiments, the excitation source switch 624 includes three parallel-connected digitally-controlled single-pole single-throw switches; one end of each of the three single-pole single-throw switches is connected to serve as the first excitation terminal and is electrically connected to the power module 61, and the other end of each of the three single-pole single-throw switches serves as the second excitation terminal and is electrically connected to the zero calibration input terminal 623, the gain calibration input terminal 622, and the measurement input terminal 621, respectively.

It is understood that, in another variant embodiment, the excitation source switch 624 includes three parallel MOS transistors, sources of the three MOS transistors are connected to serve as the first excitation terminal and are electrically connected to the power module 61, drains of the three MOS transistors serve as the second excitation terminal and are electrically connected to the zeroing input terminal 623, the gain calibration input terminal 622 and the measurement input terminal 621, respectively, and gates of the three MOS transistors are electrically connected to the controller 632, respectively. Specifically, the three MOS transistors may be NMOS transistors or PMOS transistors.

Further, the temperature sensing module 62 further includes a sampling switch 625. The first sampling terminal of the sampling switch 625 is electrically connected to the a/D sampling unit 631, and the second sampling terminal of the sampling switch 625 is switched to be respectively connected to the measurement input terminal 621, the calibration gain input terminal 622, and the calibration zero input terminal 623 each time a body temperature is measured, so that the a/D sampling unit 631 samples the third voltage V2, the second voltage V1, and the first voltage V0, respectively, and thus the controller 632 may calculate the resistance value of the thermistor Rx according to the third voltage V2, the second voltage V1, the first voltage V0, and the resistance value of the reference resistor R1, which are sampled by the a/D sampling unit 631, and determine the body temperature value according to the resistance value of the thermistor Rx.

It is understood that, in one embodiment, the sampling switch 625 is a digital control type single-pole-three-throw switch, one end of the digital control type single-pole-three-throw switch serves as the first sampling end and is electrically connected to the a/D sampling unit 631, and the other end of the digital control type single-pole-three-throw switch serves as the second sampling end, and includes a movable contact and three fixed contacts, the movable contact is selectively electrically connected to the three fixed contacts, and the three fixed contacts are respectively connected to the zero calibration input 623, the gain calibration input 622 and the measurement input 621, so that the a/D sampling unit 631 respectively samples the first voltage V0, the second voltage V1 and the third voltage V2.

It is understood that, in one variant embodiment, the sampling switcher 625 includes three digitally controlled single-pole single-throw switches connected in parallel; one end of each of the three single-pole single-throw switches is connected to serve as the first sampling terminal and is electrically connected to the a/D sampling unit 631, and the other end of each of the three single-pole single-throw switches serves as the second excitation terminal and is electrically connected to the zero calibration input terminal 623, the gain calibration input terminal 622, and the measurement input terminal 623, respectively, so that the a/D sampling unit 631 samples the first voltage V0, the second voltage V1, and the third voltage V2, respectively.

It is understood that, in another modified embodiment, the sampling switch 625 includes three MOS transistors connected in parallel, sources of the three MOS transistors are connected to serve as the first excitation terminal and are electrically connected to the a/D sampling unit 631, drains of the three MOS transistors serve as the second excitation terminal and are electrically connected to the zeroing input terminal 623, the gain calibration input terminal 622 and the measurement input terminal 621 respectively, and gates of the three MOS transistors are electrically connected to the controller 632 respectively, so that the a/D sampling unit 631 samples the first voltage V0, the second voltage V1 and the third voltage V2 respectively. Specifically, the three MOS transistors may also be NMOS transistors or PMOS transistors.

Further, in order to eliminate the influence of the failure of the zero resistor R0 and/or the reference circuit R1 on the body temperature measurement, the body temperature measurement circuit 56 of the present application needs to perform a zero resistor check and a reference resistor check before performing the body temperature measurement.

Specifically, referring to fig. 25, when performing the zero point resistance calibration, the excitation source switch 624 is switched to be conductive with the calibration input terminal 623, the current of the power module 61 flows through the zero point resistor R0, and the controller 632 determines whether the zero point resistor R0 fails according to the first voltage V0 applied to the zero point resistor R0. Specifically, the controller 632 determines whether the first voltage V0 applied to the zero resistor R0 exceeds a preset voltage range, and if so, determines that the zero resistor R0 is disabled, otherwise, determines that the zero resistor R0 is normal. The failure of the zero resistor R0 may be caused by a short circuit, an open circuit, a failure of the resistor itself, or the like.

Further, in one embodiment, the sampling switch 625 controls the second sampling terminal of the sampling switch 625 to be switched to be connected to the zero calibration input terminal 623 so as to sample the first voltage V0 when performing the zero-point resistance calibration.

When the zero resistance is determined to be normal, reference resistance verification is required. Referring to fig. 26, when performing the reference resistance calibration, the excitation source switch 624 is switched to be conductive with the calibration gain input terminal 622, the current of the power module 61 simultaneously flows through the zero resistor R0 and the reference resistor R1, and the controller 632 determines whether the reference resistor R1 fails according to the second voltage V1 applied to the zero resistor R0 and the reference resistor R1. Specifically, the controller 632 determines whether the second voltage V1 applied to the zero resistor R0 and the reference resistor R1 exceeds a preset voltage range, and if so, determines that the reference resistor R1 is disabled, otherwise, determines that the reference resistor R1 is normal. The failure of the reference resistor R1 may be caused by a short circuit, an open circuit, a failure of the resistor itself, and the like.

Further, in one embodiment, when the reference resistor R1 is verified, the second sampling terminal of the sampling switch 625 is switched to be connected to the calibration gain input terminal 622 to sample the second voltage V1.

And when the zero resistance check and the reference resistance check are normal, normal body temperature measurement is carried out. In addition, in order to prevent the influence of the failure of the zero point resistor R0 and/or the reference circuit R1 on the body temperature value, the zero point resistor verification and the reference resistor verification need to be performed periodically.

In one embodiment, the measurement control module 63 further includes an amplifying circuit 633, the amplifying circuit 633 is electrically connected between the sampling switch 625 and the a/D sampling unit 631, the amplifying circuit 633 amplifies the third voltage V2, the second voltage V1 and the first voltage V0, respectively, the a/D sampling unit 631 samples the amplified third voltage V2', the second voltage V1' and the first voltage V0' and converts the sampled third voltage V2', the amplified second voltage V1' and the amplified first voltage V0' into digital signals, respectively, and the controller 632 calculates the resistance value of the thermistor Rx according to the digital signals of the third voltage V2', the second voltage V1' and the first voltage V0' and the resistance value of the reference resistor R1.

It is understood that, in some embodiments, the amplifying circuit 633 may be, but is not limited to, a fixed gain circuit or an adjustable gain circuit, and is not limited herein.

Specifically, when performing the zero-point resistance verification, the power module 61 flows through the zero-point resistance R0, and the first voltage V0 applied to the zero-point resistance R0 is amplified by a predetermined multiple through the amplifying circuit 633, then sampled by the a/D sampling unit 631, and transmitted to the controller 632 for calculation and processing. When the controller 632 determines that the amplified first voltage V0' is out of the preset voltage range, it determines that the zero resistor R0 is abnormal, otherwise, it determines that the zero resistor R0 is normal.

Specifically, when the reference resistance is verified, the power module 61 flows through the reference resistance R1 and the zero resistance R0, and the second voltage V1 applied to the reference resistance R1 and the zero resistance R0 is amplified by a preset multiple through the amplifying circuit 633, sampled by the a/D sampling unit 631, and transmitted to the controller 632 for calculation and processing. When the controller determines that the second voltage V1' amplified by the preset times exceeds a preset voltage range, the controller determines that the reference resistor R1 is abnormal, otherwise, the controller determines that the reference resistor R1 is normal.

Specifically, referring to fig. 27, when both the zero-point resistance verification and the reference resistance verification are normal, normal body temperature measurement is performed. When measuring the body temperature, the body temperature measuring probe 57 is led out from the anti-defibrillation structure 50 and extended into a predetermined portion of the patient for body temperature measurement, the resistance value of the thermistor Rx changes according to the temperature, the current of the power module 61 flows through the thermistor Rx, the reference resistor R1 and the zero resistor R0, the third voltage V2, the second voltage V1 and the first voltage V0 are respectively sampled by the sampling switch 625 through the amplification preset times of the amplification circuit 633 to obtain the amplified third voltage V2', the amplified second voltage V1' and the amplified first voltage V0', and the amplified third voltage V2', the amplified second voltage V1 'and the amplified first voltage V0' are transmitted to the controller 632 for calculation and processing.

Specifically, in one embodiment, the process of calculating the resistance value of the thermistor Rx by the controller 632 according to the sampled and amplified third voltage V2', second voltage V1', first voltage V0' and the resistance value of the reference resistor R1 is as follows:

the amplified third voltage V2', second voltage V1', and first voltage V0' respectively represent values of the third voltage V2, second voltage V1, and first voltage V0 amplified by a predetermined multiple by the amplifier circuit 633, and are sampled by the a/D sampling unit 631; wherein,

V0'＝K×V0＝K×Itemp×R0；

V1'＝K×V1＝K×Itemp×(R1+R0)＝K×Itemp×R1+V0；

V2'＝K×V2＝K×Itemp×(Rx+R1+R0)＝K×Itemp×Rx+K×Itemp×R1+V0；

V2′-V1′＝K×Itemp×Rx

V1′-V0′＝K×Itemp×R1

thereby obtaining

In the above formula, V0', V1' and V2' are all the actual sampling values of the a/D sampling unit 631, Itemp is the value of the current flowing through the thermistor Rx, the reference resistor R1 and the zero resistor R0, and R1 is the reference resistor.

It can be seen that the measurement accuracy of the thermistor Rx is related only to the accuracy of the reference resistor R1 and the accuracy of the a/D sampling unit 631, and is unrelated to the error of the amplifying circuit 633, the power supply accuracy, the circuit zero drift, and the accuracy of the zero resistor R0. Therefore, as long as the resistance precision of the reference resistor R1 and the sampling precision of the A/D sampling unit 631 are high enough, the requirement of high-precision body temperature measurement can be met, and meanwhile, when the body temperature is measured, the currents flowing through the thermistor Rx, the reference resistor R1 and the zero resistor R0 are current values at the same moment, and are irrelevant to the time drift of the currents, so that more accurate measurement can be ensured.

It is understood that, in other embodiments, the process of calculating the resistance value of the thermistor Rx according to the sampled and amplified third voltage V2', second voltage V1', first voltage V0' and the resistance value of the reference resistor R1 may be implemented by other suitable calculation processes, and is not limited herein.

Further, in one embodiment, the power module 61, the excitation source switch 624, the sampling switch 625, the amplifying circuit 633 and the a/D sampling unit 631 of the body temperature measuring circuit 56 are integrated on the same chip, so as to minimize the size.

Further, in one embodiment, the controller 632 controls the power module 61 to periodically apply the voltage to the body temperature measuring probe 57 through the excitation source switch 624, so as to avoid the deterioration of the measurement accuracy caused by the continuous voltage application to the body temperature measuring probe 57.

In some embodiments, the mobile monitoring system is provided with a plurality of operation buttons, the controller 632 is electrically connected to the excitation source switch 624 and the sampling switch 625, and the controller 632 controls the excitation source switch 624 and the sampling switch 625 to perform corresponding switching when the user operates the operation buttons or the screen assembly 113 to determine that the current body temperature measurement, the zero resistance verification, or the reference resistance verification is performed.

Therefore, in the body temperature measuring circuit and the mobile monitoring system of the present application, when the body temperature is measured, the current flowing through the zero resistor R0, the reference resistor R1 and the thermistor Rx from the power module 61 is the current value at the same time, the measurement control module 63 calculates the resistance value of the thermistor Rx according to the voltages applied to the zero resistor R0, the reference resistor R1 and the thermistor Rx, and obtains the body temperature value by back-checking the characteristic curve of the thermistor Rx according to the resistance value of the thermistor Rx, so that the measurement of the body temperature value is more accurate.

The host is provided with a photoelectric sensor on one side facing the wrist of the target object, the processor is electrically connected with the photoelectric sensor, and the processor measures the pulse rate of the target object according to the sensing signal of the photoelectric sensor.

Referring also to FIG. 28, the screen assembly 113 includes a display 1131. The display 1131 is electrically connected to the processor 2121. Specifically, in one embodiment, the display 1131 is a display with relatively low power, i.e., a display with low power consumption, for example, the power is less than or equal to 5 mW. It is understood that the low power display screen may be, but is not limited to, an electronic ink screen or a monochrome LCD, which has low power consumption.

Further, in one embodiment, the processor 2121 controls the display 1131 to enter the screen locking state when the display 1131 is in the unlocked state and the duration of time during which the touch signal from the touch screen 1133 is not received exceeds a preset duration. The predetermined time range may be factory preset time, for example, 1 minute, or may be customized through a setting menu of the mobile monitoring device 10.

Further, in one embodiment, after the processor 2121 controls the display 1131 to enter the lock state, the touch screen 1133 generates a touch signal in response to a touch input operation at any position of the touch screen, and the processor 2121 controls the display 1131 to unlock and enter the unlock state in response to the touch signal.

Specifically, in one embodiment, the recovery state parameters displayed by the processor 2121 in the unlocked state by the display 1131 include at least numerical information, waveform information and/or prompt information, wherein the waveform information includes, but is not limited to, an electrocardiographic waveform, an oximetry waveform, and the like. The processor 2121 further controls the display 1131 to display a part of the recovery status parameters displayed in the unlocked state in the locked state, for example, display numerical information and/or prompt information of the recovery status parameters in the locked state. That is, the processor 2121 controls the display 1131 to display the recovery state parameters in the unlocked state or the locked state, but the recovery state parameters displayed in the unlocked state are more detailed, and only some more critical data information in the recovery state parameters is displayed in the locked state, so that the purpose of reducing power consumption is achieved, and the critical information in the recovery state parameters is not missed.

Specifically, referring to fig. 29 together, the processor 2121 controls the display 1131 to display the amount of movement, for example, 2.6 hours of movement, and controls the total number of times that the display target object needs to move every day, for example, 6 hours. Further, in one embodiment, the processor 2121 controls the display 1131 to display a progress bar including the amount of movement and the total number of required movement hours, so as to wakedly remind the target object of performing the operation of the corresponding amount of movement.

Further, referring to fig. 30, since the display 1131 is a black and white display with low power consumption, the processor 2121 controls the display 1131 to remind the change of the battery capacity by the icon change on the display interface, for example, when the battery capacity is lower than a preset value, an icon with low battery capacity is displayed, so as to remind the medical staff to replace the battery timely.

Further, after the mobile monitoring device 10 is coupled to the ward-level monitoring device 2000 (as shown in fig. 33) in a pairing manner, or after the mobile monitoring device 10 is coupled to the ward-level monitoring device 2000 in a pairing manner and the ward-level monitoring device 2000 is communicatively coupled to the department-level monitoring device 3000 (as shown in fig. 33), the mobile monitoring device 10 and the ward-level monitoring device 2000 and/or the department-level monitoring device 3000 can achieve synchronous display.

Further, in one embodiment, when the mobile monitoring device 10 is coupled to the patient room-level monitoring device 2000 (as shown in fig. 33) in a pairing manner, and the processor 2121 controls the display 1131 to remind the user of the power change through the icon change on the display interface thereof, and the power is lower than the preset value, the patient room-level monitoring device 2000 and/or the department-level monitoring device 3000 coupled to the mobile monitoring device 10 in a pairing manner will generate an abnormal alarm.

Further, referring to fig. 31, in one embodiment, when the network connection is interrupted, the processor 2121 controls the display 1131 to display a network connection interruption symbol. It will be appreciated that the aforementioned network connection interruption includes, but is not limited to, a failure of the mobile monitoring device 10 resulting in no data being monitored, etc.

Specifically, in one embodiment, when the patient room monitoring device 2000 does not receive a target object parameter from the mobile monitoring device 10 after the mobile monitoring device 10 is coupled to the patient room monitoring device 2000 in a paired manner, the patient room monitoring device 2000 displays "-" in the display area of the target object parameter.

Referring to fig. 32, fig. 32 is a block diagram of a monitoring body area system 1000 according to an embodiment of the present application. The monitored body area system 1000 includes at least one mobile monitoring device 10 worn on the body of a target subject. At least one of the at least one mobile monitoring device 10 includes a first wireless communication module 1011. The first wireless communication module 1011 is used for establishing a communication connection between at least one mobile monitoring device 10 and the second wireless communication module 210. The at least one mobile monitoring device 10 obtains the recovery status parameter corresponding to the target object, and transmits the recovery status parameter to the second wireless communication module 210 through the first wireless communication module 1011. The second wireless communication module 210 is disposed on a target device for data communication with the mobile monitoring device 10.

Wherein, the recovery state parameter includes: physiological parameters, parameters related to exercise amount and time parameters of human body state, wherein the physiological parameters comprise at least one of blood oxygen parameters, blood pressure parameters, pulse rate parameters, body temperature parameters, electrocardio parameters, respiratory parameters and the like; the parameters related to the exercise amount comprise at least one of exercise steps, step frequency, exercise distance and calories; the human body state time parameters comprise time parameters which are related to movement or sleep and are used for representing human body states.

Referring to fig. 33, the target device in data communication with the mobile monitoring device 10 includes: at least one of a ward-level monitoring device 2000, a department-level monitoring device 3000, and an institution-level monitoring device 4000. The department-level monitoring device 3000 may be, but is not limited to, a department-level workstation, among others. The hospital-level monitoring apparatus 4000 may be, but is not limited to, a hospital-level data center or a hospital-level emergency center.

The second wireless communication module 210 performs wireless data communication with the first wireless communication module 1011 through the telemetry antenna 41, the NFC antenna 42, the bluetooth antenna 43, or the WIFI antenna 44.

Specifically, in one embodiment, when a plurality of mobile monitoring devices 10 are disposed on the body of the target subject, one of the mobile monitoring devices 10 is a main mobile monitoring device 101, and the main mobile monitoring device 101 includes the first wireless communication module 1011. Specifically, in one embodiment, the first wireless communication module 1011 includes a WMTS communication module, wherein the WMTS communication module includes at least the telemetry antenna 41 and the telemetry antenna circuit 21112. The main mobile monitoring device 101 further includes an NFC communication module and a bluetooth communication module, wherein the NFC communication module at least includes the NFC antenna 42 and the NFC circuit 21110. The bluetooth communication module at least comprises the bluetooth antenna 43 and the bluetooth circuit 2122. The main mobile monitoring device 101 collects the recovery state parameters acquired from other mobile monitoring devices through the NFC communication module or the bluetooth communication module, and wirelessly transmits the recovery state parameters to the ward monitoring device 2000 through the WMTS communication module.

The plurality of mobile monitoring devices 10 disposed on the body of the target subject includes at least one secondary mobile monitoring device 102. The primary mobile monitoring device 101 includes a primary bluetooth communication module 1012. The auxiliary mobile monitoring device 102 includes an auxiliary bluetooth communication module 1021. The recovery status parameters include a portion of the data acquired by the primary mobile monitoring device 101 and a portion of the data acquired by the secondary mobile monitoring device 102. The auxiliary mobile monitoring device 102 transmits a part of data to the main mobile monitoring device 101 through the auxiliary bluetooth communication module 1021 via bluetooth. The primary mobile monitoring device 101 receives the portion of data through the primary bluetooth communication module 1012.

The primary mobile monitoring device 101 further comprises: a first near field communication tag reading module 1013 and a master control module 1014. The secondary mobile monitoring device 102 also includes a first near field communication tag 1022 and a secondary control module 1023. The primary mobile monitoring device 101 reads the first near field communication tag 1022 of the secondary mobile monitoring device 102 through the first near field communication tag reading module 1013 to obtain a read signal. The primary mobile monitoring device 101 further obtains at least one bluetooth connection information according to the read signal through the main control module 1014, and controls the primary bluetooth communication module 1012 to initiate a bluetooth connection request to the auxiliary bluetooth communication module 1021 according to the at least one bluetooth connection information. The at least one auxiliary mobile monitoring device 102 controls the auxiliary bluetooth communication module 1021 to establish a bluetooth connection with the main bluetooth communication module 1012 through the auxiliary control module 1023.

When the distance between the main mobile monitoring device 101 and the ward monitoring device 2000 is within the distance range of bluetooth communication, the main mobile monitoring device 101 transmits the recovery status parameter to the ward monitoring device 2000 through the main bluetooth communication module 1012, so as to allow the ward monitoring device 2000 to receive the recovery status parameter through the bluetooth communication module.

The main mobile monitoring device 101 is provided with a WIFI wireless communication module. The WIFI wireless communication module at least includes the WIFI antenna 44 and the WIFI circuit 2131. The primary mobile monitoring device 101 also includes a master control module 1014. When the communication quality of the WIFI wireless communication module is better than that of the WMTS communication module, the main control module 1014 controls to switch from the WMTS communication module to the WIFI wireless communication module for data communication, otherwise, the main control module 1014 controls to maintain or switch to the WMTS communication module for data communication.

Referring to fig. 33, fig. 33 is a block diagram illustrating a monitor networking system 10000 for use in a hospital according to an embodiment of the present application. The system can be used for integrally storing the data of the monitor, centrally managing the patient information and the nursing information, and storing the patient information and the nursing information in an associated manner, so that the historical data can be conveniently stored and the alarm can be conveniently associated. In the system shown in fig. 33, a ward-level monitoring device 2000 may be provided for each patient bed, and the ward-level monitoring device 2000 may be a multi-parameter monitor or an add-on monitor. In addition, each ward-level monitoring device 2000 can also be paired with one monitoring body area system 1000 for transmission, the monitoring body area system 1000 provides a simple and portable multi-parameter monitor or module component, which can be worn on the body of a patient to perform mobile monitoring corresponding to the patient, and the recovery state parameters generated by the mobile monitoring can be transmitted to the ward-level monitoring device 2000 for display after the monitoring body area system 1000 is in wired or wireless communication with the ward-level monitoring device 2000, or transmitted to the department-level monitoring device 3000 through the ward-level monitoring device 2000 for being viewed by doctors or nurses, or transmitted to the data server 5000 for storage through the ward-level monitoring device 2000. In addition, the monitored body area system 1000 may also directly transmit the recovery state parameters generated by the mobile monitoring to the department-level monitoring device 3000 through the wireless network node 6000 arranged in the hospital for storage and display, or transmit the recovery state parameters generated by the mobile monitoring to the data server 5000 through the wireless network node 6000 arranged in the hospital for storage. It can be seen that the data corresponding to the physiological parameters displayed on the ward-level monitoring device 2000 may originate from a sensor accessory directly connected to the patient above the monitor, or from the monitoring body area system 1000, or from the data server 5000.

The wireless network transmission distances of the NFC antenna 42, the bluetooth antenna 43, the telemetry antenna 41 and the WIFI antenna 44 are different, and the wireless transmission distances are in sequence from small to large: NFC antenna 42, bluetooth antenna 43, telemetry antenna 41, WIFI antenna 44.

Specifically, when the distance between the host 11 of the mobile monitoring device 10 and the patient room monitoring device 2000 is smaller than a first predetermined distance, the recovery status parameter in the host 11 of the mobile monitoring device 10 is transmitted to the patient room monitoring device 2000 through the NFC antenna 42. When the distance between the monitoring body area system 1000 and the corresponding ward-level monitoring device 2000 is greater than a first preset distance and less than a second preset distance, the mobile monitoring system 100 of the monitoring body area system 1000 transmits the recovery state parameter to the ward-level monitoring device 2000 through the telemetry antenna 41. When the distance between the monitoring body area system 1000 and the corresponding ward-level monitoring device 2000 is greater than a second preset distance, the mobile monitoring system 100 of the monitoring body area system 1000 transmits the recovery state parameter to the ward-level monitoring device 2000 through the WIFI antenna 44 or directly to the department-level monitoring device 3000.

Since telemetry antenna 41 consumes less power than WIFI antenna 44, however, the transmission distance of telemetry antenna 41 is less than the transmission distance of WIFI antenna 44. When the distance between the monitoring body area system 1000 and the corresponding ward-level monitoring device 2000 is smaller than the second preset distance and larger than the first preset distance, that is, when the distance between the monitoring body area system 1000 and the corresponding ward-level monitoring device 2000 is within the transmission distance range of the telemetry antenna 41, the telemetry antenna 41 with low power consumption is used for data transmission. When the distance between the monitoring body area system 1000 and the corresponding ward-level monitoring device 2000 is greater than the second preset distance of the telemetry antenna 41, that is, the transmission distance between the monitoring body area system 1000 and the corresponding ward-level monitoring device 2000 is greater than the transmission distance range of the telemetry antenna 41, the monitoring body area system can be automatically switched to the WIFI antenna 44 for data transmission. Therefore, according to different transmission distances, different wireless networks are adopted for data transmission, the range of motion of a patient can be expanded, the uninterrupted transmission of recovery state parameters is realized, and the requirement of long-time cruising of the monitor networking system 10000 can be met.

Referring to fig. 34, fig. 34 is a block diagram of a monitoring body area system 1000a according to another embodiment of the present application. The monitoring body area system 1000a includes a mobile monitoring device 10 and a plurality of patch-style recovery state parameter monitoring devices 80 a. The mobile monitoring device 10 includes a display 1131 and a wireless communication module. The mobile monitoring device 10 is worn on the wrist of the target subject. The mobile monitoring device 10 is in wireless communication with the patch-type recovery state parameter monitoring devices 80 a. Each patch type recovery state parameter monitoring device 80a corresponds to a recovery state parameter to be collected. The recovery state parameters collected by each patch type recovery state parameter monitoring device 80a are sent to the mobile monitoring device 10 in a wireless communication manner. The mobile monitoring device 10 displays the recovery status parameters respectively collected by the patch recovery status parameter monitoring devices 80 a.

The mobile monitoring device 10 further sends the recovery status parameter to the ward monitoring device 2000, the department monitoring device 3000, or the hospital monitoring device 4000 via the wireless communication module.

The mobile monitoring device, the mobile monitoring system and the monitoring body area system are characterized in that a first motion sensor is arranged on a host of the mobile monitoring device and used for sensing motion data of a patient, the motion situation and/or the sleep situation of the patient can be analyzed according to the motion data, the patient can be monitored daily more effectively, at least one mobile monitoring device obtains recovery state parameters corresponding to the target object, and the recovery state parameters are transmitted to the first wireless communication module through the second wireless communication module, wherein the first wireless communication module is arranged on a device which is in data communication with the mobile monitoring device. Therefore, the monitoring data of the mobile monitoring equipment can be displayed and/or information prompted on the equipment which is in data communication with the mobile monitoring equipment, and the monitoring effect is better.

In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to the related descriptions of other embodiments.

The foregoing detailed description of the embodiments of the present application has been presented to illustrate the principles and embodiments of the present application, and the above description of the embodiments is only provided to help understand the method and the core concept of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (56)

1. The utility model provides a mobile monitoring equipment, includes the host computer, its characterized in that, the host computer includes the host computer shell and sets up treater and the first motion sensor in the host computer shell, the treater with first motion sensor electric connection, the treater obtains wearing the motion data of the target object of mobile monitoring equipment according to the motion induction signal that first motion sensor produced, and according to the motion data analysis the amount of exercise and/or the sleep condition of the target object of wearing mobile monitoring equipment.
2. The mobile monitoring device of claim 1, wherein the host is provided with a first ear portion and a second ear portion opposite to each other, the host further comprises a first connector and a second connector electrically connected to the processor, the first connector is disposed in the first ear portion, the first connector is configured to be connected to the blood oxygen probe via a blood oxygen cable to obtain blood oxygen data sensed by the blood oxygen probe, the second connector is disposed in the second ear portion, and the second connector is configured to be connected to an electrode pad via an electrocardiogram/respiration lead cable to obtain electrocardiogram/respiration data sensed by the electrode pad.
3. The mobile monitoring device of claim 2, wherein the processor performs data processing according to the acquired blood oxygen data and the electrocardiographic/respiratory data, and further performs data processing according to the motion data acquired by the first motion sensor, so as to eliminate interference of motion on the blood oxygen data and the electrocardiographic/respiratory data of a target object wearing the mobile monitoring device.
4. The mobile monitoring device according to claim 2, wherein the first ear portion is provided with a first connector, the first connector is connected to the blood oxygen cable through the first connector and further connected to the blood oxygen probe through the blood oxygen cable, the second ear portion is provided with a second connector, and the second connector is connected to the ecg/respiration lead cable through the second connector and further connected to the electrode pad through the ecg/respiration lead cable.
5. The mobile monitoring device of claim 1, further comprising a wrist strap module disposed on a side of the host, the wrist strap module for securing the host to a wrist of a target subject, the wrist strap module comprising a holder and a wrist strap, the holder being disposed on a side of the host, the wrist strap being disposed on a side of the holder facing away from the host.
6. The mobile monitoring device of claim 5, wherein the main housing has an enclosed cavity therein for receiving the processor, the main housing further comprising a battery disposed on an outer wall of the main housing and outside the enclosed cavity of the main housing; the mount with the mainframe shell is connected and will the battery centre gripping is in the mainframe shell with between the mount.
7. The mobile monitoring device of claim 1, further comprising a wristband module integrally disposed with the host; the wrist strap module comprises two wrist straps which respectively vertically extend out of the first ear part and the second ear part and are connected into a ring-shaped strap after extending out.
8. The mobile monitoring device of claim 7, wherein the host further comprises a first connector and a second connector electrically connected to the processor, the first connector being disposed in a wrist band adjacent the first ear portion, the second connector being disposed in a wrist band adjacent the second ear portion, the first connector being adapted to connect to a blood oxygen probe via a blood oxygen cable connection, the second connector being adapted to connect to an electrode pad via an ECG/respiration lead cable.
9. The mobile monitoring device of claim 8, wherein a first connector is disposed on the wristband adjacent the first ear portion, the first connector being connected to a blood oxygen cable via the first connector, and a second connector is disposed on the wristband adjacent the second ear portion, the second connector being connected to an ecg/ecg lead cable via the second connector.
10. The mobile monitoring device of claim 4 or 9, wherein the first connection port is oriented opposite to the second connection port, and wherein the first connection port is oriented toward a human finger and the second connection port is oriented toward a side of a human body when the host is worn on a wrist.
11. The mobile monitoring device of claim 2, wherein the first ear portion is a first receptacle having a hollow interior, the first connector being removably mounted in the first receptacle, and the second ear portion is a second receptacle having a hollow interior, the second connector being removably mounted in the second receptacle.
12. The mobile monitoring device of claim 1, further comprising a screen assembly, a battery, and a parameter measurement circuit board, wherein the screen assembly and the battery are stacked, the parameter measurement circuit board is tiled alongside the battery, the parameter measurement circuit board comprises at least a first circuit board and a second circuit board stacked, and the processor and the first motion sensor are disposed on the first circuit board or the first circuit board.
13. The mobile monitoring device of claim 12, wherein the parameter measurement circuit board is tiled alongside and to the side of the stacked arrangement of the battery and the screen assembly; or, the parameter measurement circuit board with the battery tiles the setting side by side, and is located the side of battery, the screen subassembly lid is established the battery with the top of parameter measurement circuit board.
14. The mobile monitoring device of claim 13, wherein the first circuit board is disposed above the second circuit board, the first circuit board having a battery interface and a screen interface, the battery interface being electrically connected to the battery, the screen interface being electrically connected to the screen assembly.
15. The mobile monitoring device of claim 14, wherein the first circuit board is provided with a communication interface and a blood oxygen interface, the parameter measurement circuit board further comprises an electrocardiogram/respiration side board and a blood oxygen side board, the communication interface is connected with the electrocardiogram/respiration side board, and the blood oxygen interface is electrically connected with the blood oxygen side board.
16. The mobile monitoring device of claim 15, wherein the ecg/fe side board and the oximetry side board are disposed vertically on opposite sides of the first circuit board, respectively.
17. The mobile monitoring device of claim 15, wherein the parameter measurement circuit board further comprises a blood oxygen module disposed on the first circuit board or the second circuit board, the blood oxygen module being electrically connected to the blood oxygen interface.
18. The mobile monitoring device of claim 14, wherein the first circuit board further comprises a telemetry antenna circuit and a telemetry antenna socket, the mobile monitoring device further comprises a telemetry antenna, the main housing comprises a plurality of inner sidewalls and a plurality of ear portions, the telemetry antenna is disposed on at least one of the inner sidewalls and/or at least one of the ear portions, and the predetermined portion of the telemetry antenna extends along the extending direction of at least one of the inner sidewalls and/or at least one of the ear portions by a predetermined length.
19. The mobile monitoring device of claim 18, wherein the telemetry antenna comprises a connector portion and at least one winged fin portion connected to the connector portion, the predetermined location being the at least one winged fin portion; the connecting part is arranged in the main chassis, and the at least one wing part is arranged on the at least one inner side wall or the at least one ear part and extends for a preset length along the extending direction of the at least one inner side wall or the at least one ear part.
20. The mobile monitoring device of claim 19, wherein the main housing includes a first side and a second side disposed opposite to each other, the inner sidewall includes at least one inner sidewall at the first side and/or the second side, each of the at least one wing portion is disposed adjacent to a corresponding one of the at least one inner sidewall and extends a predetermined length along an extension direction of the corresponding inner sidewall when the at least one wing portion is disposed at the at least one inner sidewall.
21. The mobile monitoring device of claim 20, wherein the at least one winged-fin portion includes a first winged-fin portion and a second winged-fin portion, and the first winged-fin portion and the second winged-fin portion are disposed on opposite sides of the connection portion; at least one inside wall is including being located the first inside wall of first side with be located the second inside wall of second side, first wing portion with second wing portion is close to respectively first inside wall with the second inside wall sets up to extend predetermined length along the extending direction of first inside wall and second inside wall respectively, just first wing portion with the extending direction of second wing portion with the extending direction looks perpendicular on the long limit of connecting portion.
22. The mobile monitoring device of claim 19, wherein the main housing comprises a rear housing and a front housing, the front housing and the rear housing are engaged with each other to form the main housing, the front housing has a front housing protruding edge, a rear housing protruding edge is disposed on the rear housing at a position corresponding to the front housing protruding edge, when the rear housing and the front housing are engaged, the rear housing protruding edge and the front housing protruding edge are engaged to form the ear portion, a receiving space is formed in the ear portion, and when the at least one wing portion is disposed at least one of the ear portions, the at least one wing portion is disposed in the receiving space and extends a predetermined length.
23. The mobile monitoring device of claim 22, wherein the at least one wing includes a first wing and a second wing, and the first wing and the second wing are disposed on opposite sides of the connecting portion, the main chassis includes a first side and a second side disposed opposite to each other, the at least one ear includes a first ear portion disposed on the first side and a second ear portion disposed on the second side, the first wing and the second wing are disposed in the first ear portion and the second ear portion, respectively, and extend a predetermined length in the first ear portion and the second ear portion, and an extending direction of the first wing and the second wing is perpendicular to an extending direction of the connecting portion.
24. The mobile monitoring device of claim 22, wherein the connector has a circuit coupling node coupled to the parameter measurement circuit board, the parameter measurement circuit board has a resilient contact pin, the circuit coupling node of the connector is disposed corresponding to the resilient contact pin, and when the front housing is fastened to the rear housing, the front housing applies a pressure to the connector to urge the circuit coupling node of the connector to electrically contact the resilient contact pin.
25. The mobile monitoring device of claim 22, wherein an NFC circuit and an NFC antenna socket are further disposed on the first circuit board, the mobile monitoring device further comprises an NFC antenna, the screen assembly is disposed on the front housing, the NFC antenna is disposed between the screen assembly and the rear housing and electrically connected to the parameter measurement circuit board, the NFC antenna is plate-shaped and disposed parallel to the display surface of the screen assembly, and the NFC circuit is electrically connected to the NFC antenna through the NFC antenna socket.
26. The mobile monitoring device of claim 22, wherein the second circuit board further comprises a bluetooth circuit and a bluetooth antenna socket, and the mobile monitoring device further comprises a bluetooth antenna disposed in the rear housing and adjacent to the top end of the main housing, and electrically connected to the parameter measurement circuit board; the plane of the Bluetooth antenna is perpendicular to the plane of the top end of the main case, and the Bluetooth circuit is connected with the Bluetooth antenna through the Bluetooth antenna socket.
27. The mobile monitoring device of claim 22, wherein the second circuit board further has a WIFI circuit and a WIFI antenna socket disposed thereon; the mobile monitoring equipment further comprises a WIFI antenna, the WIFI antenna is arranged in the rear shell, is close to the bottom end of the main shell and is electrically connected with the parameter measuring circuit board, and the WIFI antenna and the telemetering antenna are arranged at a preset distance; the WIFI antenna is parallel to the bottom end of the main case; the WIFI circuit passes through the WIFI antenna socket with electric connection between the WIFI antenna.
28. The mobile monitoring device of claim 13, wherein the parameter measurement circuit board further comprises a third circuit board positioned below the second circuit board, the first circuit board, the second circuit board, and the third circuit board being stacked one on top of the other, the processor being disposed on the second circuit board; the third circuit board is further provided with a WIFI circuit and a WIFI antenna socket, the mobile monitoring equipment further comprises a WIFI antenna, and the WIFI circuit is electrically connected with the WIFI antenna through the WIFI antenna socket.
29. The mobile monitoring device of claim 13, wherein the parameter measurement circuit board further comprises a third circuit board positioned on one side of and perpendicular to the first circuit board and the second circuit board in a stacked arrangement.
30. The mobile monitoring device of claim 1, further comprising a screen assembly, the screen assembly including a display screen, the display screen being a low power display screen, the processor controlling the low power display screen to display recovery state parameters and/or prompt information, the recovery state parameters including at least an amount of exercise.
31. The mobile monitoring device of claim 30, wherein the processor controls the display to alert the change in the amount of power by a change in an icon on the display interface.
32. The mobile monitoring device of claim 1, wherein a photoelectric sensor is disposed on a side of the host computer facing a wrist of the target subject, the processor is electrically connected to the photoelectric sensor, and the processor measures a pulse rate of the target subject according to a sensing signal of the photoelectric sensor.
33. A mobile monitoring system comprises an electrocardio/respiration lead cable, an anti-defibrillation structure and at least three electrode plate connectors, wherein one end of the electrocardio/respiration lead cable is used for being connected with a mobile monitoring device, the mobile monitoring device is the mobile monitoring device according to any one of claims 1 to 32, the electrocardio/respiration lead cable is sequentially provided with the anti-defibrillation structure and the at least three electrode plate connectors in series from one end close to the mobile monitoring device to one end far away from the mobile monitoring device, and the electrode plate connectors are used for clamping electrode plates.
34. The mobile monitoring system of claim 33, wherein the anti-defibrillation structure further comprises an anti-defibrillation board, the anti-defibrillation board is provided with a defibrillation protection circuit and a processor, the processor is electrically connected to the defibrillation protection circuit, and the defibrillation protection circuit is used for protecting the ECG detection system from damage when the target subject is defibrillated for restoring normal heartbeat when necessary.
35. The mobile monitoring system of claim 34, wherein the anti-defibrillation board has an ecg/resp circuit disposed thereon.
36. The mobile monitoring system of claim 34, wherein the anti-defibrillation board further has a second motion sensor disposed thereon, the second motion sensor being electrically connected to the processor.
37. The mobile monitoring system of claim 34, wherein the anti-defibrillation board is further provided with a body temperature measurement circuit electrically connected to the processor, the mobile monitoring system further comprises a body temperature probe, one end of the body temperature probe is electrically connected to the body temperature measurement circuit on the anti-defibrillation board through a cable, and the other end of the body temperature probe is led out of the anti-defibrillation structure for measuring body temperature.
38. The mobile monitoring system according to claim 37, wherein the body temperature measuring circuit comprises a power module, a temperature sensing module and a measurement control module, the power module is electrically connected to the temperature sensing module, the temperature sensing module is electrically connected to the measurement control module, the temperature sensing module comprises a thermistor, a reference resistor and a zero resistor connected in series in sequence, the temperature sensing module further comprises a measurement input terminal located at an end of the thermistor away from the reference resistor, the power module is connected to the measurement input terminal when body temperature measurement is performed, current of the power module flows through the thermistor, the reference resistor and the zero resistor, the measurement control module calculates a resistance value of the thermistor according to voltages applied to the thermistor, the reference resistor and the zero resistor, and determining the corresponding body temperature value according to the resistance value of the thermistor.
39. The mobile monitoring system of claim 38, wherein the temperature sensing module further comprises a calibration gain input terminal between the thermistor and the reference resistor and a calibration zero input terminal between the reference resistor and the zero resistor, wherein one end of the zero resistor remote from the reference resistor is grounded, a voltage between the calibration gain input terminal and ground is a first voltage, a voltage between the calibration gain input terminal and ground is a second voltage, a voltage between the measurement input terminal and ground is a third voltage, and the measurement control module calculates the resistance of the thermistor according to the first voltage, the second voltage, the third voltage, and the resistance of the reference resistor.
40. The mobile monitoring system according to claim 39, wherein the measurement control module includes an A/D sampling unit and a controller electrically connected to the A/D sampling unit, the A/D sampling unit samples the first voltage, the second voltage, and the third voltage respectively every time a body temperature is measured, and the controller calculates the resistance of the thermistor according to the first voltage, the second voltage, and the third voltage sampled by the A/D sampling unit and the resistance of the reference resistor.
41. The mobile monitoring system of claim 40, wherein the temperature sensing module further comprises an excitation source switch, the first excitation end of the excitation source change-over switch is connected with the power supply module, the second excitation end is selectively connected with the zero calibration input end, the gain calibration input end or the measurement input end, when the body temperature is measured, the second excitation end of the excitation source change-over switch is switched to be conducted with the measurement input end, the current of the power supply module flows through the zero resistor, the reference resistor and the thermistor at the same time, the A/D sampling unit samples the current respectively to obtain a first voltage, a second voltage and a third voltage, and the controller calculates the resistance value of the thermistor according to the first voltage, the second voltage and the third voltage obtained by sampling by the A/D sampling unit and the resistance value of the reference resistor.
42. The mobile monitoring system of claim 41, wherein the temperature sensing module further comprises a sampling switch, a first sampling end of the sampling switch is electrically connected to the A/D sampling unit, and a second sampling end of the sampling switch is switched to be respectively connected to the zero calibration input, the gain calibration input and the measurement input when the body temperature measurement is performed each time, so that the A/D sampling unit respectively samples the first voltage, the second voltage and the third voltage.
43. The mobile monitoring system of claim 42, wherein the measurement control module further comprises an amplifying circuit, the amplifying circuit is electrically connected between the sampling switch and the A/D sampling unit, the amplifying circuit is configured to amplify the third voltage, the second voltage, or the first voltage connected to the sampling switch and transmit the amplified third voltage, the second voltage, or the first voltage to the A/D sampling unit, and the A/D sampling unit samples the amplified third voltage, the amplified second voltage, and the amplified first voltage to obtain the amplified third voltage, the amplified second voltage, and the amplified first voltage; and the measurement control module calculates the resistance value of the thermistor according to the amplified third voltage, the amplified second voltage, the amplified first voltage and the resistance value of the reference resistor.
44. A monitored body area system, comprising: the mobile monitoring device comprises at least one mobile monitoring device worn on the body of a target object, wherein at least one mobile monitoring device in the at least one mobile monitoring device comprises a first wireless communication module, the first wireless communication module is used for establishing communication connection between the at least one mobile monitoring device and a second wireless communication module, the at least one mobile monitoring device acquires recovery state parameters corresponding to the target object and transmits the recovery state parameters to the second wireless communication module through the first wireless communication module, and the second wireless communication module is arranged on the target device which is in data communication with the mobile monitoring device.
45. The monitored body area system of claim 44, wherein after said primary mobile monitoring device establishes a communication connection with a target device, the content displayed on the display screen of said primary mobile monitoring device is also displayed on said target device synchronously.
46. The monitored body area system of claim 44, wherein an abnormality alarm is generated on said target device when the display screen of said primary mobile monitoring device alerts that the power level is below a preset power level value by a change in an icon on the display interface.
47. The monitored body area system according to any one of claims 44 to 46, wherein said target device comprises: at least one of a ward-level monitoring device, a department-level monitoring device, and an institution-level monitoring device.
48. The monitored body area system of claim 44, wherein said first wireless communication module and said second wireless communication module communicate wirelessly based on WMTS, WIFI, RF or Bluetooth communication.
49. The monitored body area system of claim 44, wherein said recovery state parameters comprise: the physiological parameters comprise at least one of blood oxygen parameters, blood pressure parameters, pulse rate parameters, body temperature parameters, electrocardio parameters and breathing parameters; the exercise amount related parameters comprise at least one of exercise steps, step frequency, exercise distance and calories; the human body state time parameters comprise time parameters which are related to movement or sleep and are used for representing human body states.
50. The monitored body area system of claim 44, wherein when a plurality of mobile monitoring devices are disposed on the body of the target subject, one of said plurality of mobile monitoring devices is a primary mobile monitoring device, said primary mobile monitoring device having said first wireless communication module disposed thereon, said first wireless communication module comprising a WMTS communication module, said primary mobile monitoring device collecting said recovery status parameters obtained from other mobile monitoring devices and transmitting said recovery status parameters to said ward-level monitoring device via said WMTS communication module.
51. The monitored body area system of claim 50, wherein said plurality of mobile monitoring devices disposed on the body of the target subject includes at least one secondary mobile monitoring device, said primary mobile monitoring device including a primary Bluetooth communication module, said secondary mobile monitoring device including a secondary Bluetooth communication module; the recovery state parameters comprise partial data acquired by the primary mobile monitoring device and partial data acquired by the secondary mobile monitoring device; the auxiliary mobile monitoring equipment transmits partial data to the main mobile monitoring equipment in a Bluetooth transmission mode through the auxiliary Bluetooth communication module; and the main mobile monitoring equipment receives the partial data through the main Bluetooth communication module.
52. The monitored body area system of claim 51, wherein said primary mobile monitoring device further comprises: the first near field communication tag reading module and the main control module, the auxiliary mobile monitoring device further comprises: the system comprises a first near field communication tag and an auxiliary control module; the primary mobile monitoring device reads the first near field communication label of the secondary mobile monitoring device through the first near field communication label reading module to obtain a reading signal; the main mobile monitoring equipment also acquires at least one piece of Bluetooth connection information according to the reading signal through the main control module, and controls the main Bluetooth communication module to initiate a Bluetooth connection request to the auxiliary Bluetooth communication module according to the at least one piece of Bluetooth connection information; the at least one auxiliary mobile monitoring device controls the auxiliary Bluetooth communication module to establish Bluetooth connection with the main Bluetooth communication module through the auxiliary control module respectively.
53. The monitored body area system of claim 51, wherein said main mobile monitoring device transmits said recovery state parameter to said ward-level monitoring device via said main Bluetooth communication module when the distance between said main mobile monitoring device and said ward-level monitoring device is within the distance range of Bluetooth communication, so as to allow said ward-level monitoring device to receive said recovery state parameter via its Bluetooth communication module.
54. The monitored body area system of claim 50, wherein said first wireless communication module further comprises a WIFI wireless communication module, and said primary mobile monitoring device further comprises a main control module, wherein when the communication quality of said WIFI wireless communication module is better than that of said WMTS communication module, said main control module controls to switch from said WMTS communication module to said WIFI wireless communication module for data communication, otherwise, said main control module controls to maintain or switch to said WMTS communication module for data communication.
55. The utility model provides a guardianship body area system, includes mobile guardianship equipment and a plurality of SMD recovery state parameter monitoring facilities, mobile guardianship equipment includes display screen and wireless communication module, mobile guardianship equipment wears on the target object wrist, mobile guardianship equipment with a plurality of SMD recovery state parameter monitoring facilities wireless communication are connected, and every SMD recovery state parameter monitoring facilities corresponds a recovery state parameter that needs to gather, and the recovery state parameter that every SMD recovery state parameter monitoring facilities gathered sends to through the wireless communication mode on the mobile guardianship equipment, mobile guardianship equipment shows the recovery state parameter that a plurality of SMD recovery state parameter monitoring facilities gathered respectively.
56. The monitored body area system of claim 55, wherein said mobile monitoring device further transmits recovery status parameters to a ward-level monitoring device, a department-level monitoring device or an institution-level monitoring device via said wireless communication module. 57. The monitored body area system of claim 55, wherein said recovery state parameters comprise physiological parameters, motion quantity related parameters and body state time parameters, said physiological parameters comprising at least one of blood oxygen parameters, blood pressure parameters, pulse rate parameters, body temperature parameters, electrocardiographic parameters, respiratory parameters; the exercise amount related parameters comprise at least one of exercise steps, step frequency, exercise distance and calories; the human body state time parameters comprise time parameters which are related to movement or sleep and are used for representing human body states.

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