CN107633880B - Intelligent communication system and maintenance mechanism intelligent management system - Google Patents

Abstract

The invention relates to an intelligent communication system and an intelligent management system of a maintenance mechanism, which comprise: the system comprises indoor extension sets, sensors, monitoring devices, a host and a control host; the sensor and the monitoring device are respectively connected with the indoor extension, and the host, the indoor extension and the control host are communicated with each other through the internet and are respectively communicated with the cloud server; the host receives the extension instruction and sends the extension instruction to the corresponding host and the control host; the indoor extension calls a sensor to collect indoor environment parameters in real time, sends the collected environment parameters to the host and uploads the environment parameters to the cloud server, and outputs alarm information to the host, the control host and the cloud server when the environment parameters are abnormal; and the indoor extension also calls the monitoring device to collect indoor monitoring images.

Description

Intelligent communication system and maintenance mechanism intelligent management system

Technical Field

The invention relates to the technical field of communication, in particular to an intelligent communication system and an intelligent management system of a maintenance mechanism.

Background

With the improvement of science and technology and the improvement of living standard, maintenance mechanisms put forward higher and higher requirements on the safety and convenience of living environment. However, the information level of the current maintenance institution is backward, the management efficiency is low, and professional medical care personnel are generally needed to take care of patients. However, most medical staff cannot accompany patients all day long, and therefore, the living environment of the patients cannot be monitored timely and effectively.

To sum up, the traditional maintenance mechanism has poor monitoring effect on the patient.

Disclosure of Invention

Therefore, it is necessary to provide an intelligent communication system and an intelligent management system for a maintenance organization, aiming at the problem that the traditional maintenance organization has poor monitoring effect on patients.

An intelligent communications system, comprising:

the system comprises indoor extension sets, sensors, monitoring devices, a host and a control host;

the sensor and the monitoring device are respectively connected with the indoor extension, and the host, the indoor extension and the control host are communicated with each other through the internet and are respectively communicated with the cloud server;

the host receives the extension instruction and sends the extension instruction to the corresponding host and the control host;

the indoor extension calls a sensor to collect indoor environment parameters in real time, sends the collected environment parameters to the host and uploads the environment parameters to the cloud server, and outputs alarm information to the host, the control host and the cloud server when the environment parameters are abnormal;

and the indoor extension also calls the monitoring device to collect indoor monitoring images.

The utility model provides a maintenance mechanism intelligent management system, includes intelligent communication system, the ward of maintenance mechanism is located to indoor extension, the room on duty of maintenance mechanism is located to the host computer, the administrative center of maintenance mechanism is located to the main control system, the sensor acquisition environmental parameter in the ward, monitoring device gathers monitoring image in the ward.

According to the intelligent communication method and system and the intelligent management system of the maintenance mechanism, the sensor and the monitoring device are used for respectively acquiring the environmental parameters and the monitoring images, the environmental parameters and the monitoring images are sent to the host through the indoor extension set and then forwarded to the control host through the host, all-weather monitoring can be carried out on the living environment of the patient, and the monitoring effect on the patient is improved.

Above-mentioned intelligent communication system, maintenance mechanism intelligent management system gather environmental parameter and surveillance image respectively through sensor and monitoring device to send environmental parameter and surveillance image to the host computer through indoor extension, transmit to the control host computer again through the host computer, can carry out all-weather control to the living environment of patient, improved the monitoring effect to the disease.

Drawings

FIG. 1 is a schematic diagram of an intelligent communications system according to an embodiment;

FIG. 2 is a schematic diagram of a kernel configuration interface, according to an embodiment;

FIG. 3 is a flow diagram of an MFC application of an embodiment;

FIG. 4 is a schematic diagram of a login interface, according to an embodiment;

FIG. 5 is a diagram of an interaction module, according to an embodiment;

FIG. 6 is a schematic view of a monitoring module according to one embodiment;

FIG. 7 is a schematic diagram of an alarm module according to one embodiment;

FIG. 8 is a schematic view of a setup module according to one embodiment;

FIG. 9 is a software flow diagram of one embodiment.

Detailed Description

The technical solution of the present invention will be explained below with reference to the accompanying drawings.

As shown in fig. 1, the present invention provides an intelligent communication system, which may include:

the system comprises indoor extension sets, sensors, monitoring devices, a host and a control host;

the sensor and the monitoring device are respectively connected with the indoor extension, and the host, the indoor extension and the control host are communicated with each other through the internet and are respectively communicated with the cloud server;

the host receives the extension instruction and sends the extension instruction to the corresponding host and the control host;

the indoor extension calls a sensor to collect indoor environment parameters in real time, sends the collected environment parameters to the host and uploads the environment parameters to the cloud server, and outputs alarm information to the host, the control host and the cloud server when the environment parameters are abnormal;

and the indoor extension also calls the monitoring device to collect indoor monitoring images.

In one embodiment, the sensor may include a light sensor, a temperature sensor, a humidity sensor, a shock sensor, a flame sensor, a smoke sensor, and/or a proximity sensor. Correspondingly, illumination monitoring, temperature detection, humidity monitoring, earthquake early warning, smoke early warning and/or personnel access monitoring can be achieved through the sensor. The sensors form a multi-sensor system for omni-directional monitoring of the indoor environment. In another embodiment, the monitoring device may employ a camera, and further, may employ a 360 degree panoramic camera. The 360-degree panoramic camera can monitor the coverage area of 400 square meters without blind spots, is provided with a fisheye lens and has a 360-degree panoramic view. A360-degree panoramic camera can replace a plurality of ordinary cameras, and seamless monitoring is achieved. Environmental parameters collected by the sensor and monitoring images collected by the monitoring device can be transmitted to the indoor extension set. Further, the sensor can be connected with indoor extension through zigBee, if the quantity of sensor is a plurality of, each sensor all can be connected with indoor extension through zigBee. Alternatively, the indoor extension may employ an S5pv210 chip. Correspondingly, the host and the control host can also adopt an S5pv210 chip.

The S5PV210 is an 16/32 bit RISC microprocessor with the advantages of low cost, low power consumption and high performance. The S5PV210 comprises a plurality of powerful hardware accelerators and is very suitable for applications such as audio and video, 2D graphics, display operation and the like. The internal integrated MFC (Multi-Format CODEC) supports MPEG4/H.263/H.264 CODECs, which support real-time video conferencing and television output (NTSC and PAL). The S5PV210 has an optimized external memory interface to accommodate the high memory bandwidth required by high-end communication services. The memory system has two external memory interfaces, where the DRAM interface can be configured to support LPDDR1(MobileDDR), DDR2 and LPDDR2, while the Flash/ROM interface supports NOR-Flash, NAND-Flash, OneNAND, SRAM and ROM type peripherals. The S5PV210 comprises a plurality of hardware peripherals, such as a camera interface, a 24-bit true color LCD controller, a 4-way UART, a 24-way DMA, a 4-way timer, a GPIO, an AC97, an IIS, an IIC, a USBHost2.0, a USB2.0OTG, a 4-way SD/MMC controller and the like. The S5PV210 is based on an ARMCortex-A8 core, including 32KB instructions and 32KB data Caches, 512KBL2Cache, MMU to support virtual memory management.

ZigBee can be implemented using the CC253x chip. The 8051CPU core used in the CC253x chip family is a single cycle 8051 compatible core, with 8-KB SRAM mapped to DATA storage space and partial XDATA storage space. The 8-KB SRAM is an ultra-low power SRAM that retains its contents even if the digital portion is powered down (power modes 2 and 3). This is a function that is important for low power applications.

The host and the control host can adopt a Linux operating system. The Linux operating system has the characteristics of source code openness, portability, high performance of operation, easy maintainability and the like, so that the Linux operating system becomes the first choice in embedded development. Among all operating systems, Linux is the fastest growing and most widely used operating system. The present invention may use the s3c-Linux-2.6.21 Linux operating system. The hardware resources of the embedded system are limited, so that Linux capable of running on a PC cannot be directly used as an operating system in the embedded system, and various functional modules need to be tailored to specific hardware platforms and specific functions to be realized. The Linux kernel has good modularity and scalability, and can obtain obvious effect through reasonable cutting under the condition of strict resource requirement.

Firstly, configuring a kernel and shielding redundant source codes in the kernel. The kernel configuration interface is shown in FIG. 2. The Linux kernel configuration system can generate a kernel configuration menu, so that kernel configuration is facilitated. The configuration system mainly comprises Makefile, Kconfig and a configuration tool, and can generate a configuration interface. The Linux kernel configuration command comprises the following steps: make config, make menuconfig and make xconfig are the configuration interfaces of character interface, ncurses cursor menu and X-window graphic window respectively. The paper selects a ncurses cursor menu interface. In each level of sub-menu items, there are 3 choices for selecting the corresponding configuration, which represent the following meanings: y-represents the compilation of the function into the kernel, N-represents the compilation of the function into the kernel, and M-represents the compilation of the function into modules that can be dynamically inserted into the kernel as needed.

Executing the make menuconfig command, wherein the specific configuration is selected as follows:

1. selecting Enable Loadable module support in the Loadable module support causes the kernel to support the module dynamic loading.

2. Add support for the System platform in the System Type. For different architectures, different hints are displayed.

3. The required Device Drivers are selected in the Device Drivers. Adding support for a camera in a Memory technology device submenu, wherein other options can directly use default values thereof, saving and exiting after configuration is completed, and then completing kernel compiling through the following steps: establishing a kernel dependency relationship and creating a kernel image file respectively.

Because the embedded system generally adopts FLASH as a storage medium, both the internal memory and the external memory resources need to be saved. FLASH has unique physical characteristics and must use a specialized embedded file system. At present, the file systems supported by FLASH mainly comprise JFFS2, YAFFS2, RAMFS, CRAMFS, ROMFS and the like. The system adopts the coexistence of the CRAMFS file system and the YAFFS file system.

cramfs is a compressed, extremely simple read-only file system with the main advantage of storing file data in compressed form, and decompressing when needed. It does not need to decompress all the contents in the file system into the memory at one time, but just when the system needs to access the data at a certain position, it immediately calculates the position of the data in cramfs, and decompresses it into the memory in real time, and then accesses the memory to obtain the data to be read in the file system. The decompression in the cramfs and the storage position of the data in the memory after the decompression are maintained by the cramfs file system, and a user does not need to know the specific implementation process. Generally, the price of an embedded memory is higher, a cramfs file system is used for saving space, and the cramfs is a good choice for a small system such as FLASH.

The Cramfs file system adopts a real-time decompression mode. The data of cramfs is processed and packed, and writing operation on the data has certain difficulty. So cramfs does not support write operations, and this feature is well suited for the case where Flash storage file systems are used in embedded applications.

The yaffs (yet antenna Flash File system) File system is an embedded File system designed specifically for NAND Flash memories. In yaffs, files are stored in fixed-size data blocks, which may be 512 bytes, 1024 bytes, or 2048 bytes in size. This implementation relies on its ability to associate a data block header with each data block. Each file (including directory) has a data block header corresponding to it, in which the ecc (error Correction code) and the organization information of the file system are stored for error detection and bad block processing. Fully considering the characteristics of NAND Flash, yaffs stores the data block head in the 16-byte spare space of Flash. When the file system is mounted, the file system information can be read into the memory only by scanning the spare space of the storage and is stored in the memory, so that the loading speed of the file system is increased, the access speed of the file is also increased, and the consumption of the memory is increased.

Comprehensively, the system adopts a method of combining two file systems, uses cramfs as a root file system, and adds support for yaffs file system. The invention adopts a cramfs file system and downloads the cramfs file system to a development board through a USB.

The invention can also adopt a hardware coding and decoding module (MFC-Multi-Format Codec) to carry out high-efficiency compression on the H.264 video. The following are the steps of MFC module driven migration:

in the first step, Boot option is configured. Some devices are required to reserve storage space because they must allocate contiguous physical space. This requires modification of the RESERVED _ MEM. h file under the core/asm-arm/arch-s 3c2410 directory in the kernel source code, i.e., reserving # define CONFIG _ RESERVED _ MEM _ MFC. Then compiling the kernel, and executing a command make smdk6410mtd _ defconfig; make menuconfig;

in the second step, kernel configuration is performed, then a Default kernel command string is selected, and if "mem ═ 128M" is displayed, it is removed because memory has been reserved for MFC before. And finally, saving and quitting, and downloading the generated zImage file to a development board.

Third, the MFC drivers are compiled. Firstly, Makefile is modified, and the position of kernel source code is modified, namely:

KERNEL_DIR:＝/home/mobile/workspace/s3c-linux-2.6.24；

TOPDIR:＝/home/mobile/workspace/s3c-linux-2.6.24。

after compiling, a file s3c _ mfc.ko is generated, and after being downloaded to a development board, the execution authority is modified, namely chmod777s3c _ mfc.ko, and then dynamically inserted into the memory through a command insmod s3c _ mfc.ko, so that loading can be driven.

The wireless video monitoring system consists of a monitoring front end, a monitoring terminal and a wireless network. The monitoring front end collects video data by using a monitoring device (such as a camera), the video data is transmitted to a monitoring terminal (namely, a host and a control host, and also can be an intelligent terminal) through a wireless network after being compressed, and an application program of the monitoring terminal decodes, stores and displays the video data, so that the remote video monitoring function is realized.

If the camera captures images at a speed of 15 frames/second, and the size of one frame of image is set to be 640 × 480 (in units of pixels) in the capture program, and the format of YUV420P is adopted, the size of one frame of image is 640 × 480 × 1.5 — 460800 Byte. The amount of data transmitted in one second is 460800 × 15 to 6.6Mbyte, and it is seen that the amount of data is very large. Such large image information can put a great deal of pressure on the storage capacity of the memory, the bandwidth of the network communication channel, and the processing speed of the processor. This requires compression encoding prior to data transmission to reduce the amount of data.

The invention adopts the multimedia coding and decoding module MFC integrated in the S5PV210 to carry out H.264 video compression coding. The MFC module has a high-performance video coding and decoding function, supports the coding and decoding of MPEG4, H.263 and H.264, supports VC1 decoding, and can achieve full-duplex 30fps @640 x 480 simultaneous coding and decoding and half-duplex 30fps @720 x 480 or 25fps @720 x 576 coding and decoding. The MFC application for h.264 based video compression coding is shown in fig. 3. After the program starts, firstly, the MFC equipment is opened, after the MFC equipment is successfully opened, the coding parameters are set, then the configuration parameters are reset, the output stream format is selected, if the reset is successful, the MFC coding information is initialized, if the initialization is successful, the coding data is received and coded (for example, H.264 coding) is carried out, and finally the coded data is transmitted. When resetting the configuration parameters, if an abnormal error occurs, the error processing can be carried out, and the process of judging whether the MFC equipment is opened or not is returned.

In one embodiment, the host and the control host may employ a large-screen Liquid Crystal Display (LCD). The host and the control host can acquire indoor visual parameters, and the visual parameters can enable a user to know the application condition of the system more intuitively, wherein the application condition comprises field monitoring and remote terminal monitoring.

Further, if the environmental parameters and the monitoring images are abnormal, the indoor extension set can generate alarm information and give an alarm to the host. For example, when the indoor temperature exceeds a preset temperature range, the indoor extension set can alarm the host machine. For another example, when the flame sensor detects a fire source, the indoor extension may alert the host. Further, when a plurality of sensors exist, if the indoor environment information acquired by any one sensor is abnormal or the monitoring image acquired by the monitoring device is abnormal, the indoor extension set can give an alarm to the host and simultaneously send the environment information and the monitoring image to the host. The host can forward the alarm information, the environmental parameters and the monitoring images to the control host, and the control host can upload the environmental parameters and the monitoring images to the server. The server may store the environmental parameters and the monitored images.

Furthermore, the indoor extension set and the host can carry out visual talkback through one-key calling. The user can press the call key on the indoor extension to actively call the host, and the host can forward the call to the control host. In turn, the controlling host may also call the host, which may forward the call to the indoor extension. By the mode, the communication among the indoor extension set, the host and the control host is convenient to realize. In practical application, the indoor extension set can communicate with the host through a wireless network such as a local area network; in practical applications, the host may communicate with the control host via a wireless network, such as a local area network.

Further, the intelligent communication system of the present invention may further include an intelligent terminal that communicates with the cloud server; and the intelligent terminal is used for acquiring the environmental parameters and the monitoring image from the server. The smart terminal may include, but is not limited to, one or more of a cell phone, a tablet, a laptop, a netbook, a desktop computer. The intelligent terminal can firstly send an authentication request to the cloud server, and if the authentication request passes, the intelligent terminal sends a data acquisition request to the cloud server; the cloud server can respond to the data acquisition request and send the environment parameters and the monitoring image to the intelligent terminal. The authentication request may be in the form of an account number and a password, that is, the user inputs the account number and the password through a login interface (as shown in fig. 4) of the intelligent terminal, the intelligent terminal sends the account number and the password to the server for authentication, and if the account number and the password are matched, the authentication request passes; otherwise the authentication request does not pass. The environment parameters and the monitoring images are obtained through the intelligent terminal, so that a holder of the intelligent terminal can know the information of the environment where the monitored person is located at any time and any place. Furthermore, the system security can be improved through the identity authentication, and the situation that an unauthorized person steals environmental parameters and monitoring images is prevented.

Furthermore, the intelligent terminal can also carry out visual talkback with the indoor extension. Specifically, the intelligent terminal can establish communication connection with the monitoring device through the cloud server, and can perform visual talkback with the monitoring device through the communication connection.

The monitoring device can comprise a first monitoring device and a second monitoring device, the first monitoring device can be fixed on the indoor extension and is connected with the host and the control host through the indoor extension, and managers can check indoor monitoring images; the second monitoring device can be connected with the intelligent terminal through the server, so that the holder of the intelligent terminal can conveniently check the indoor condition. The intelligent terminal can perform visual talkback with the second monitoring device through the cloud server.

Further, the intelligent terminal of the present invention may also control the monitoring device, for example, control the monitoring device to move up and down and left and right, and specifically, the intelligent terminal may send a monitoring device control command to the cloud server; the cloud server sends the monitoring device control command to the host through the control host, the host sends the monitoring device control command to the corresponding indoor extension set according to the monitoring device identification information, and the indoor extension set sends the monitoring device control command to the monitoring device to control the monitoring device. In this way, the holder of the intelligent terminal can be more comprehensively made to observe the environment where the monitored person is located.

In one embodiment, the smart communications system of the present invention may further include a controller; the controller is respectively communicated with the host, the control host, the intelligent terminal and the indoor household appliance; the controller receives household appliance control information sent by the host, the control host or the intelligent terminal and controls the indoor household appliances. The indoor household electrical appliance can be a common household electrical appliance such as a curtain, a lamp, a fan and the like, and the state of the indoor household electrical appliance can be controlled through the controller, for example, the opening and closing of the curtain, the air volume of the fan and the like are controlled. Furthermore, the controller can be controlled through the intelligent terminal; the intelligent terminal sends a controller control command to the cloud server, the cloud server sends the controller control command to the host through the control host, the host sends the controller control command to the corresponding indoor extension set according to the controller identification information, and the indoor extension set sends the controller control command to the controller to control the controller.

The user right is a range of the sensor which can be controlled by the holder of the intelligent terminal, and the range can be preset according to the distribution position of the sensor. Multiple levels of user permissions may be set, a first level of user permissions may control sensors within a first region, a second level of user permissions may control sensors within a second region, and a third level of user permissions may control sensors within a third region, wherein the range of the first region includes the second region and the range of the second region includes the third region. In this way, management of sensors in different areas is facilitated.

In another embodiment, the intelligent terminal may further send an alarm notification and/or play an alarm sound to the user when the alarm information is detected. The intelligent terminal can realize automatic abnormal alarm, a user can set alarm for the sensor, after the intelligent terminal obtains data from the cloud server, a software program on the intelligent terminal can operate an automatic alarm mechanism in a background mode, and after the data are analyzed and processed, if alarm information is found, the user can be reminded in a mode of sending a notice and playing alarm sound. The automatic alarm mechanism can be always effective as long as the software program is hung in the background and is not closed.

In another embodiment, the intelligent communication system of the present invention may further include a wearable device, and the wearable device collects sign information of the user and uploads the sign information to the server. The wearable device may include, but is not limited to, one or more of a smart bracelet, smart glasses, and the like. The vital sign information collected by the wearable device may include, but is not limited to, one or more of blood pressure, pulse, body temperature, etc. If the intelligent communication system comprises the intelligent terminal, the intelligent terminal can acquire physical sign information besides the environmental parameters and the monitoring images, so that the physical state of the monitored person can be further monitored.

According to the intelligent communication system, the sensor and the monitoring device are used for collecting the environmental parameters and the monitoring images respectively, the environmental parameters and the monitoring images are sent to the host through the indoor extension set and then forwarded to the control host through the host, all-weather monitoring can be carried out on the living environment of the patient, and the monitoring effect on the patient is improved.

Further, above-mentioned intelligent communication system gathers the sign information of disease through wearable equipment to upload sign information to the server, can download sign information from the server by intelligent terminal, thereby realize the control to disease health, further improved the monitoring effect to the disease.

The invention further provides an intelligent management system of the maintenance mechanism, which can comprise the intelligent communication system, wherein the indoor extension set is arranged in a ward of the maintenance mechanism, the host is arranged in a duty room of the maintenance mechanism, the control host is arranged in a management center of the maintenance mechanism, the sensor acquires environmental parameters in the ward, and the monitoring device acquires monitoring images in the ward.

In one embodiment, the maintenance facility may include a plurality of buildings, each building including a plurality of levels, each level including a plurality of wards, a plurality of sensors may be located in each ward, a duty room located in each level or building, and a management center located within the maintenance facility.

Furthermore, the intelligent terminal can be divided into a family intelligent terminal and a medical staff intelligent terminal according to the user. Further, different permissions may be set for different users, for example, a first level of permission being a super user permission, i.e., a control permission for all sensors in the maintenance facility, a second level of permission being an administrator permission, i.e., a control permission for all sensors in a building, and a third level of permission being an in-person user permission, i.e., a control permission for sensors in a ward. The cloud server can send authority information to the intelligent terminal according to different user login information and verification, and the intelligent terminal and the server can establish socket connection. After the login is successful, the intelligent terminal can immediately send a data request to the cloud service. Later, data is retrieved from the cloud server at intervals, which is achieved by starting a timing task, and the user can define the specific interval by himself, and in one embodiment, the data is retrieved at intervals of 5 seconds as a default.

After a request is sent, the input stream of the socket can be received, after data is obtained, the intelligent terminal can use a sub-thread to analyze the data, the request comprises a login request, a registration request, a data obtaining request and the like, and data analysis and logic judgment are carried out in a message queue. The data includes user authority data, monitoring images, environmental parameters, user physical sign data and the like.

The data sent or received by the server strictly follow a specific data format so as to facilitate the analysis of the sensor data, and each data contains the length of the data, so that when the data sent by the server is too long and is packetized, the intelligent terminal can judge whether the data packet is ended or not when receiving the data, and the data analysis error caused by incomplete data is avoided. And after the data analysis is finished, the data can be stored in a database. Taking the android system as an example, the data can be stored in an SQLITE database of the android after the data analysis is completed.

The functions of the intelligent terminal can be realized through an application program (APP) installed on the intelligent terminal. During operation, the user can get into APP's main interface, has mainly 4 modules: an interaction module (as shown in fig. 5), a monitoring module (as shown in fig. 6), an alarm module (as shown in fig. 7), and a setting module (as shown in fig. 8), each of which is a FRAGMENT slice including 4 sub-modules, and the interaction, monitoring, alarm, and setting modules.

The interactive module has the common functions of a monitoring camera, such as previewing, recording, monitoring, talkback, screenshot, lens control and the like. The camera is a product of a Haikangwei Fluorite cloud platform, and the camera shooting function is realized by using an SDK (software development kit) with the platform opened to the outside.

The monitoring module is used to view the sensors and related data for the room. Data are shown as LISTVIEW. In the module, the size of the displayed data is different according to different types of users, all rooms in a building are displayed on the page at most, and after clicking the room, the data in the room can be seen, and the room data can be contracted. The data is mainly divided into 2 types, sensors and controllers, and the controllers can send control requests to realize remote control of users. Each sensor and controller information in the room is displayed via a LISTVIEW control. The user can manually refresh the latest data in the database. The acquisition of data and the adaptation of room data is performed by a specific algorithm, which is time consuming and runs in a background thread ASYNCTASK. The user can specifically locate data of a room or a building within the permission range so as to be quickly viewed.

The alarm module is used to control the room sensors, such as turning on and off lights, adjusting temperature, etc. The control information is sent by a SOCKET to send a control request with a specific format. In this module, the user can set the alarm flag of the sensor data of a certain room by himself. For example, the alarm flag for setting the temperature alarm is as follows: above 35 degrees celsius. When the APP obtains and analyzes data in the background, if the data is found to reach the identifier, namely, the temperature is more than or equal to 35 ℃, the APP gives a notice and gives an alarm sound.

The setting module is mainly a module which is set by a user in a self-defining way. Such as default storage paths for video files and monitoring screenshots, APP theme changes, intervals for data refreshing, user password modifications, and the like.

The general flow of the software program executed by the intelligent terminal of the present invention is shown in fig. 9.

According to the intelligent communication method and system and the intelligent management system of the maintenance mechanism, the sensor and the monitoring device are used for respectively acquiring the environmental parameters and the monitoring images, the environmental parameters and the monitoring images are sent to the host through the indoor extension set and then forwarded to the control host through the host, all-weather monitoring can be carried out on the living environment of the patient, and the monitoring effect on the patient is improved.

The logic and/or steps represented in the flowcharts or otherwise described herein, e.g., an ordered listing of executable instructions that can be considered to implement logical functions, can be embodied in any computer-readable medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions. For the purposes of this description, a "computer-readable medium" can be any means that can contain, store, communicate, propagate, or transport the program for use by or in connection with the instruction execution system, apparatus, or device.

More specific examples (a non-exhaustive list) of the computer-readable medium would include the following: an electrical connection (electronic device) having one or more wires, a portable computer diskette (magnetic device), a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or flash memory), an optical fiber device, and a portable compact disc read-only memory (CDROM). Additionally, the computer-readable medium could even be paper or another suitable medium upon which the program is printed, as the program can be electronically captured, via for instance optical scanning of the paper or other medium, then compiled, interpreted or otherwise processed in a suitable manner if necessary, and then stored in a computer memory.

It should be understood that portions of the present invention may be implemented in hardware, software, firmware, or a combination thereof. In the above embodiments, the various steps or methods may be implemented in software or firmware stored in memory and executed by a suitable instruction execution system. For example, if implemented in hardware, as in another embodiment, any one or combination of the following techniques, which are known in the art, may be used: a discrete logic circuit having a logic gate circuit for implementing a logic function on a data signal, an application specific integrated circuit having an appropriate combinational logic gate circuit, a Programmable Gate Array (PGA), a Field Programmable Gate Array (FPGA), or the like.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. An intelligent communications system, comprising:

the system comprises indoor extension sets, sensors, a monitoring device, a host, a control host, an intelligent terminal and wearable equipment;

the sensor and the monitoring device are respectively connected with the indoor extension, and the host, the indoor extension and the control host are communicated with each other through the internet and are respectively communicated with the cloud server;

the host receives the extension instruction and sends the extension instruction to the corresponding host and the control host;

the indoor extension calls a sensor to collect indoor environment parameters in real time, sends the collected environment parameters to the host and uploads the environment parameters to the cloud server, and outputs alarm information to the host, the control host and the cloud server when the environment parameters are abnormal;

the indoor extension also calls the monitoring device to collect indoor monitoring images;

the indoor extension set comprises a calling key, and the calling key is used for initiating visual intercommunication between the indoor extension set and the host;

the monitoring device comprises a first monitoring device and a second monitoring device, the first monitoring device is positioned on the indoor extension, the first monitoring device is connected with the host and the control host through the indoor extension, and the indoor extension and the host check indoor conditions through the first monitoring device; the second monitoring device is connected with the intelligent terminal through the cloud server, and the intelligent terminal checks indoor conditions through the second monitoring device;

the wearable device is used for collecting sign information of a user and uploading the sign information to the cloud server.

2. The intelligent communication system according to claim 1, further comprising:

the intelligent terminal is communicated with the cloud server;

the intelligent terminal sends an identity authentication request to a cloud server, and if the identity authentication request passes, sends a data acquisition request to the cloud server;

and the cloud server responds to the data acquisition request and sends the environmental parameters and the monitoring image to the intelligent terminal.

3. The intelligent communication system according to claim 2, wherein the intelligent terminal is further configured to:

and establishing communication connection with the monitoring device through a cloud server, and performing visual talkback with the monitoring device through the communication connection.

4. The intelligent communication system according to claim 2, further comprising:

a controller;

the controller is respectively communicated with the host, the control host, the intelligent terminal and the indoor household appliance;

the controller receives household appliance control information sent by the host, the control host or the intelligent terminal and controls the indoor household appliances.

5. The intelligent communication system according to claim 2, wherein the intelligent terminal is further configured to:

sending a monitoring device control command to a cloud server;

the cloud server sends the monitoring device control command to the host through the control host, the host sends the monitoring device control command to the corresponding indoor extension set according to the monitoring device identification information, and the indoor extension set sends the monitoring device control command to the monitoring device to control the monitoring device.

6. The intelligent communication system according to claim 2, wherein the intelligent terminal is further configured to:

and when the alarm information is detected, sending an alarm notice to a user and/or playing an alarm sound.

7. The intelligent communication system according to claim 4, wherein the intelligent terminal is further configured to:

controlling the controller;

the intelligent terminal sends a controller control command to the cloud server, the cloud server sends the controller control command to the host through the control host, the host sends the controller control command to the corresponding indoor extension set, and the indoor extension set sends the controller control command to the controller to control the controller.

8. An intelligent management system for a maintenance institution, comprising the intelligent communication system as claimed in any one of claims 1 to 7, wherein the indoor extension is disposed in a ward of the maintenance institution, the host is disposed in a duty room of the maintenance institution, the control host is disposed in a management center of the maintenance institution, the sensor acquires environmental parameters in the ward, and the monitoring device acquires monitoring images in the ward.

9. A maintenance institution intelligent management system according to claim 8, characterized in that the user authority includes control authority for sensors in one ward, control authority for all sensors in one building, and control authority for all sensors in the maintenance institution.

10. A maintenance institution intelligent management system according to claim 8, characterized in that the intelligent terminal is installed with an application program, the application program comprises:

the interactive module comprises common functions of a monitoring camera, wherein the common functions comprise previewing, video recording, monitoring, talkback, screenshot and lens control;

the monitoring module is used for checking sensors and related data in the ward;

the alarm module is used for controlling the sensor in the ward;

and the setting module is used for user-defined setting.

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