KR102005361B1 - Cloud-Based Terminal Integrating Management System Using OTA Technique of IoT Terminal Over LPWA Network - Google Patents

Abstract

[0001] The present invention relates to a cloud-based terminal integrated management system using an ATE technology of an iOuti terminal supporting a low power / broadband network, and more particularly to a cloud-based terminal integrated management system that includes at least one object Internet (IoT) device, an IoT gateway, (LWM2M) that supports OTA (Over The Air) and requests update execution for an Iot device when an update is executed, and a cloud-based terminal integrated management system using the OTIA technology of an iOuti- A low power (LWM2M) client for receiving a firmware update command via a firmware update command reception unit for an update execution request from the low power module and then calling a download agent (DL) Download disk from A download package checking unit for checking the received download descriptor, a delta package downloading unit for downloading the package from the download server, and then calling the update agent (UA) And a firmware installation portion of an update agent for installing the firmware according to the firmware.

Description

[0001] The present invention relates to an integrated management system for a cloud-based terminal using OTi technology of an iOuti terminal supporting a low-power / broadband network,

[0001] The present invention relates to a cloud-based terminal integrated management system using an OTOS technology of an IOT terminal supporting a low-power / broadband network, more specifically, it is capable of updating firmware for an IOT device and minimizing data integrity and memory usage Provides an update agent for low power / low-power IoT devices, provides configuration setting, diagnostic and monitoring technology, provides device lock / data deletion, S / W installation management technology, It can be provided by applying security service. It enables firmware download and firmware split loading to shorten the loading time of large capacity files. It improves the capacity of receiving large concurrent access requests through application of asynchronous communication method, When the demand occurs, It relates to a cloud-based integrated terminal management system using this technology ot ot the child terminal that supports low-power / broadband networks that allow hwahal.

Currently, a number of Low Power Wide Area (LPWA) technology standards for Internet of Things (IoT) services that support low-power broadband networks have been adopted and are in commercial service.

Internet Of Things (IoT) communication wirelessly exchanges information between a plurality of user terminals operating with battery power only as the auxiliary power source without main power. In this way, it is essential to establish a low power wide area (LPWA) network in the Internet of things because various user terminals communicate with each other based on low power.

The Ultra Narrow Band (UNB) technology, which improves receiver sensitivity by reducing signal bandwidth usage for broadening the communication radius in a low power wide area network (LPWAN), is a low power wide area (LPWA ) Corresponds to a core part of a physical layer in establishing a communication system. In this case, when the Ultra Narrow Band (UNB) is applied to the low power wide area network, the throughput can be reduced due to the bandwidth reduction according to the ultra wide bandwidth technology.

LPWA technology can be divided into LTE-M, LoRa, and Sigfox technologies. LTE-M technology uses frequencies of 800MHz, 1.8GHz and 2.1GHz, which are the existing LTE bands, transmission rate is 200kbps, and leads the standardization in 3GPP. Its main features are suitable for low power long distance communication and use existing LTE network do.

The LoRa technology uses a frequency of 900MHz, which is a license-exempt band, transmission speed of 300bps ~ 5kbps, Laura Alliance is leading standardization, and more than 170 companies such as Cisco, IBM and Skt are involved. The main features are low power long distance communication It is suitable to use separate communication network.

The Sigfox technology also uses a license-exempt band of 900 MHz, a transmission rate of 100 bps, and promotes standardization based on Sigfox technology at ESTI. Its main features are suitable for low-power long distance communication and uses a separate communication network.

In addition, the CoAP protocol is a special web transport protocol that can be used for low power networks and small capacity small nodes. The Constrained RESTful Environment (CoRE) organization within the IETF acquired the international standard in 2014 as the upper application layer protocol of the 6LoWPAN (Low-power Wireless Personal Area Network). In addition, one standardization group such as oneM2M and OMA adopts CoAP and standardization is under way. CoAP follows the RESTful (Representational State Transfer) philosophy and is easily converted and interoperable with existing HTTP Web protocols.

The structure of the CoAP is basically a transport layer of the lower protocol stack and supports unicast and multicast using the UDP protocol. Because it operates asynchronously, it optionally includes REST Message and timer management for reliable delivery. The upper part is divided into a Request / Response layer and a message layer.

On the other hand, LWM2M (Light Weight M2M), a terminal management standard suitable for providing IoT service in low power broadband networks, has been established.

The LWM2M technology supports CoAP (Constrained Application Protocol) / UDP and application data. The device type is sensor node. Payload is Binary or JSON (Java Script Object Notation) REST is a technology that is applicable to low-power, low-power IoT terminals and provides security for device management, security lifecycle management, data format, data definition, and compatible system interface. Therefore, various systems using LWM2M, which is an international standard standard, are required to be developed.

In addition, standardization of terminal remote control technology for activation of IoT industry is needed. Manufacturers are costly in developing various terminal management standards for operators. IoT operators may experience a delay in applying the application of different terminal management technologies to their business.

In addition, there is a need for a technique for simultaneously processing a plurality of IoT data in real time. Globally, more than 50 billion sensor devices are expected to be introduced by 2020. There is a need to provide concurrent data processing and stable services through the cloud.

[Prior Art Literature]

Korean Patent Registration No. 10-1785858 (registered on September 29, 2017)

It is an object of the present invention to provide an IOT integrated terminal management service platform based on LWM2M, which is an international standard, to solve the above problems. And a method for effectively updating the firmware of an i-th device in a low-power broadband communication network in a cloud-based terminal integrated management system.

It is still another object of the present invention to provide a method for effectively downloading firmware using the LWM2M protocol.

It is still another object of the present invention to provide a method of generating an update package by extracting differences between firmware of an old version and firmware of a new version.

According to an exemplary embodiment of the present invention, there is provided a method of managing a low-power / broadband network including at least one or more object Internet (IoT) devices, an IoT gateway and an IoT terminal integrated management system, A cloud-based terminal integrated management system using the technology,

A low-power (LWM2M) module that supports OTA (Over The Air) and requests update execution for the Iot device when the update is executed,

A low power (LWM2M) client for receiving a firmware update command via a firmware update command receiver for a update execution request from the low power module and then calling a download agent (DL)

A download descriptor receiving unit of a download agent for receiving a download descriptor from a download server in response to a call signal from the low-

A download package check unit for checking the received download descriptor

A delta package downloading unit for downloading the package from the download server and subsequently calling the update agent (UA)

There is provided a cloud-based terminal integrated management system using an OTOS technology of an i-th terminal supporting a low power / broadband network including a firmware installation portion of an update agent installing firmware according to the paging signal.

According to another aspect of the present invention, there is provided a cloud-based terminal integrated management system using at least one object Internet (IoT) device, an IoT gateway, and an IoT terminal integrated management system, In this case,

The update agent of IoT installs the firmware through the IoT terminal integrated management system,

The update agent of the IoT communicates with the SHA1 algorithm in the delta package to perform the digest function from the deep image, then compares the digest of the delta package header with the valid packet to check the integrity,

A magic key and a rev.number are compared with each other and a magic key and a change number of a terminal key of the terminal are compared with each other, , Performs a reboot after replacing the firmware,

The method of claim 1 or 2, wherein the update of the deep image is performed by dividing the deep image into 10 KB through the delta headers 1 to N and the delta images 1 to N, thereby minimizing memory use of the terminal in the update operation of the agent. There is provided a cloud-based terminal integrated management system using OT technology of an OT terminal.

According to another aspect of the present invention, there is provided a cloud-based terminal integrated management system using at least one object Internet (IoT) device, an IoT gateway, and an IoT terminal integrated management system, In this case,

 The terminal integrated management server of the IoT terminal integrated management system responds to the inquiry of the config information of the system operator server and, in response to the reset, requests inquiry / reset to the IoT gateway,

The IoT device processes the inquiry of the terminal setting information at the request of the IoT gateway and processes the reset,

A cloud-based terminal integrated management system using the OTI technology of an i-thi terminal supporting a low power / broadband network is provided, characterized in that an environment setting value of a device is confirmed and reset through a wireless network.

According to another aspect of the present invention, there is provided a cloud-based terminal integrated management system using at least one object Internet (IoT) device, an IoT gateway, and an IoT terminal integrated management system, In this case,

The system operator server sends a diagnosis request signal to the operation management server, and the operation management server sends a signal to the LWM2M module unit to request the distribution of the diagnostic policy,

The LWM2M module performs diagnostic policy deployment and execution, collects diagnostic logs when events occur from LWM2M clients,

The collected logs are transmitted to the operation management server, and the diagnosis results are transmitted to the system operator server,

A system for collecting and providing status information of a terminal as a service for diagnosing and monitoring a problem of a terminal remotely is provided, and a cloud-based terminal integrated management system using the OTI technology of a low power / do.

According to another aspect of the present invention, there is provided a cloud-based terminal integrated management system using at least one object Internet (IoT) device, an IoT gateway, and an IoT terminal integrated management system, In this case,

The service provider server transmits a signal requesting terminal lock / data deletion to the terminal integrated management server,

The terminal integrated management server sends a lock / data deletion request signal to the IoT gateway,

The IoT gateway receives a lock / data deletion request signal from the IoT device and performs a lock / data deletion process when the terminal integrated management server requests the lock / data deletion process. A cloud-based terminal integrated management system using OTOS technology is provided.

According to another aspect of the present invention, there is provided a cloud-based terminal integrated management system using at least one object Internet (IoT) device, an IoT gateway, and an IoT terminal integrated management system, In this case,

In response to the S / W package registration request from the service provider server A, the terminal integrated management server requests the package registration approval from the system operator server and accepts the package registration,

In response to the S / W installation / change request from the service provider server B, the terminal integrated management server transmits an install / change request signal to the IoT gateway, and the IoT gateway then transmits an install / change request signal to the IoT device, The integrated management server of the cloud-based terminal using the OTI technology of the IT terminal supporting the low-power / broadband network is provided, wherein the integrated management server processes the S / W installation / change when requested.

Preferably, DTLS security function is applied to the IoT gateway (G / W) -server section, and PSK-DTLS or simple AES security technology is applied to the low-level IoT device and the G / W section. Is applied.

According to another aspect of the present invention, there is provided a cloud-based terminal integrated management system using at least one object Internet (IoT) device, an IoT gateway, and an IoT terminal integrated management system, In this case,

Provides firmware download and firmware split loading for the most heavily loaded firmware download service during firmware update,

The IoT device requests a firmware package from the download server,

The media manager of the download server then inquires the firmware,

The media manager then performs loading through the package multi-loader,

It then starts loading into the Delta Package Server (NAS)

The delta package server divides and loads large packages and sends them to the media manager through the package multi-loader,

The media manager starts buffering and starts distributing the firmware through the distribution device of the download server. A cloud-based terminal integrated management system using the OTI technology of the low-power / broadband network supporting i-th terminal is provided .

Preferably, when the IoT device fails to download the distributed package, the content range start (ContentRangeStart) of the IoT device is activated to perform firmware re-

The large capacity firmware follow-up process supports a function of receiving an error in the event of an error during downloading, and performs a firmware package cache process in case of download failure in order to efficiently receive the download.

Preferably, for large-capacity firmware division loading, a package multi-loader performs a firmware package division loading process at the time of requesting a large-capacity firmware, and a large-capacity file loading time is shortened through firmware division loading.

As described above, according to the cloud-based terminal integrated management system using the OTIA technology of the iOuti terminal supporting the low power / broadband network according to the present invention, it is possible to update the firmware of the IOT device and minimize data integrity and memory usage Can provide an update agent for low power / low-power IoT devices, can provide configuration setting, diagnosis and monitoring technology, can provide device lock / data deletion, S / W installation management technology, And it is possible to reduce the loading time of large files by enabling firmware download and firmware split loading, and it is possible to improve the capacity of receiving a large amount of concurrent access requests by applying the asynchronous communication method When there is a demand for massive concurrent access, It is capable of connecting to minimize latency effects.

FIG. 1 is a conceptual diagram schematically illustrating a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low power / broadband network according to the present invention.
FIG. 2 is a system configuration diagram of a cloud-based terminal integrated management system using OTOS technology of an ITO terminal supporting a low power / broadband network according to the present invention.
FIG. 3 is an explanatory diagram illustrating a core technology in a cloud-based terminal integrated management system using OTOS technology of an iO terminal that supports a low power / broadband network according to the present invention.
4 is an exemplary diagram of a device control protocol between the LWM2M server and the client in the cloud-based terminal integrated management system using the OT technology of the i-th terminal supporting the low power / broadband network according to the present invention.
FIG. 5 is a diagram illustrating a firmware update management technique in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low-power / broadband network according to the present invention.
FIG. 6 is a diagram illustrating a Diff package generator and an update agent technique in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low power / broadband network according to the present invention.
FIG. 7 is a diagram illustrating a configuration setting technique in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low-power / broadband network according to the present invention.
FIG. 8 is a diagram for explaining a device diagnosis and monitoring technology in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low-power / broadband network according to the present invention.
FIG. 9 is a diagram illustrating a device lock / data deletion technique in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low power / broadband network according to the present invention.
10 is a diagram illustrating a S / W installation technique in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low power / broadband network according to the present invention.
FIG. 11 is a diagram for explaining a security technique of IoT service in an integrated management system of a cloud-based terminal using the OTIA technology of an iO terminal which supports a low power / broadband network according to the present invention.
FIG. 12 is a diagram for explaining firmware re-acquisition and firmware division loading in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low-power / broadband network according to the present invention.
FIG. 13 is a diagram illustrating a performance enhancement technique using an asynchronous communication model and a memory cache in a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low power / broadband network according to the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

FIG. 1 is a conceptual diagram schematically illustrating a cloud-based terminal integrated management system using OT technology of an i-th terminal supporting a low-power / broadband network according to the present invention. FIG. 3 is a diagram illustrating a system configuration of a cloud-based terminal integrated management system using the OTI technology of the i-iT terminal, and FIG. 3 is a diagram illustrating a cloud-based terminal integrated management system using the OTI technology of the i- FIG. 4 is a schematic diagram illustrating a device control protocol between the LWM2M server and the client in the cloud-based terminal integrated management system using the OTI technology of the iOuti terminal supporting the low power / broadband network according to the present invention. Fig. 5 is an exemplary view of the present invention FIG. 6 is a diagram illustrating a firmware update management technique in a cloud-based terminal integrated management system using the OTI technology of an i-thi terminal supporting a power / broadband network, and Fig. 6 is a diagram illustrating a firmware update management technique of the i- FIG. 7 is a diagram for explaining a Diff package generator and an update agent technology in a cloud-based terminal integrated management system using OT technology, and FIG. 7 is a diagram illustrating a Diff package generator and an update agent technology in a cloud- FIG. 8 is a view for explaining a configuration setting technique in a cloud-based terminal integrated management system using a device according to the present invention. FIG. 8 is a diagram for explaining a configuration setting technique in a cloud-based terminal integrated management system using the AI- Establish monitoring technology And FIG. 9 is a diagram illustrating a device lock / data deletion technique in a cloud-based terminal integrated management system using the OTIA technology of the iOuti terminal supporting the low power / broadband network according to the present invention. FIG. 11 is a diagram illustrating a S / W installation technique in a cloud-based terminal integrated management system using the OTIA technology of an iOuti terminal supporting a low power / broadband network according to an embodiment of the present invention. FIG. 12 is a diagram for explaining a security technique of the entire IoT service in the cloud-based terminal integrated management system using the OTo technology of the OT terminal, and FIG. 12 is a diagram for explaining the security technology of the IoT terminal supporting the low power / In the cloud-based terminal integrated management system, FIG. 13 is a view for explaining a firmware split loading technique, and FIG. 13 is a diagram for explaining the firmware split loading technique, and FIG. 13 is a diagram for explaining a firmware split loading technique. FIG.

Hereinafter, a cloud-based terminal integrated management system using the ATE technology of the iOuti terminal supporting the low power / broadband network according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, an LWM2M protocol supporting OTA is applied to a low-power, low-power IoT terminal, and a cloud-based IoT integrated management system is provided to provide an integrated management service of IoT terminals.

That is, a plurality of IoT devices can access the service portal site by accessing the IoT integrated terminal management system through the wireless communication network.

Referring to FIG. 2, the IoT integrated terminal management system includes a proxy module, an LWM2M module, a download module, an open API module, and an operation management module.

The Proxy Module contains Health Check, Load Balancing, TCP and UDP and is Linux based.

The LWM2M module includes a workflow engine for FOTA / Config, Services, Device Mgmt, Reporting, Bootstrap, and Register for configuration, Processor, a management engine, an OTA adapter, and a cache handler.

The download module includes IP Filtering, DD State Management / Distribution, Notify Collection, Media Object Distribution / Management, WSI Manager, Media Manager, Service Manager, and Session Manager.

The open API module unit is responsible for firmware update, status monitoring, environment setting, and service request, and includes a response handler, a request handler, a session manager, and an authentication manager.

The Operations Management Module is responsible for terminal management, model management, configuration, status monitoring, firmware update, service management, statistics, and system management.

The framework module is based on Linux (Linux), WAS (Tomcast 7), CoAP, DTLS, JSON, TLV, Security, MyBatis, Spring, Logging, Configuration, .

IoT gateways include applications, which include LWM2M clients, update agents, download agents, and networks (modules).

The LWM2M client includes bootstrap, register (REGISTER), Observe / Notify, and has a service enablement with device information, server, security, and Fota as a device management unit.

The network (module) includes CoAP, DTLS / UDP, WAN (LTE-M, LoRA), PAN (6LoWPAN, WiFi, BLE).

The IoT device has almost the same configuration as the gateway as the application, but the network (module) includes PAN (6LoWPAN, WiFi, BLE).

The present invention is a cloud-based terminal integrated management system using OTI technology of an iOuti terminal supporting a low power / broadband network. It is an OTA-based terminal management technology that conforms to CoAP-based LWM2M standard technology, Provides configuration setting, diagnosis and monitoring technology, and provides device lock value data deletion technology and remote S / W installation management technology.

In addition, as IoT security service technology, PKI-based DTLS technology is applied to the gateway and the server section, and PSK-DTLS technology is applied to the device and the gateway section to support low power / low- Apply AES encryption technology.

We apply low power / broadband communication modem technology (LTE-M, LoRA) technology, low power PAN communication technology (BLE, Zigbee, WiFi) and embedded based firmware level software technology as IoT gateway / device technology, Respectively.

As a large capacity / parallel data processing technology, firmware reuse and firmware partition loading technology were applied, processing performance was improved by applying asynchronous communication model and memory cache technology, and cloud infrastructure capable of auto - scaling for mass traffic processing was utilized.

Referring to FIG. 4, a device control protocol between an LWM2M server and a client will be described as an example.

The IoT integrated management system 30 can query the Iot device 10 for the manufacturer name of the IoT device. IoT device 10 sends a response to it.

The IoT integrated management system 30 may send an instruction to the Iot device 10 to change the current time of the IoT device. IoT device 10 sends a response to it.

The IoT integrated management system 30 may send an instruction to the Iot device 10 to restart the IoT device. IoT device 10 sends a response to it.

The IoT integrated management system 30 may send a control command to the Iot device 10 to change the "3/0/9" Attibute. IoT device 10 sends a response to it. "3/0/9" Changing the Attibute is a control command to report to the server when the remaining battery level is less than 5%.

5, in the cloud-based terminal integrated management system using the OTI technology of the i-th terminal supporting the low-power / wide-band network according to the present invention, when a bug is corrected or a function is added to the i- And the like.

The firmware update management technology through the IoT terminal integrated management system 30 will be described. Key features include a firmware update service that conforms to the LWM2M module specification, manages the lifecycle of firmware packages, and manages firmware package downloads and traffic. Features and benefits include managing the firmware service through the management console (CONSOLE). And implements the OMA-DL OTA-based download process. Check the delta package dictionary validity through the download descriptor. It also prevents duplicate transmission and supports large capacity resume. And when the memory and battery capacity are low, download stops, and pause and resume are applied to minimize network traffic.

Upon execution of the update, the LWM2M module 310 may perform updates to the IOT gateway 20 and the device 10. The LWM2M client 110 receives the firmware update command via the firmware update command receiver and then calls the download agent (DL) 130. [

The download descriptor receiving unit 132 of the download agent 130 receives the download descriptor from the download server 320. [

Thereafter, the download descriptor received by the download package check unit 134 is checked. The delta package downloading unit 136 downloads the package from the download server 320 and then calls the update agent UA 120 and installs the firmware through the firmware install unit of the update agent 120 .

Referring to FIG. 6, the OTA-based terminal management technology includes a diff package generator for low power / low-power IoT devices by minimizing data integrity and memory use through the IOT terminal integrated management system 30, Update agent function can be performed.

The IoT terminal integrated management system 30 checks the integrity of the network transmission data through the SHA1 digest algorithm. That is, the delta package communicates with the SHA1 algorithm to perform the digest function from the deep image, and then compares the digest of the delta package header with the valid packet. This checks the integrity.

 It is confirmed whether or not it is a correct update target terminal through the unique key value of the package header of the IoT terminal integrated management system 30. That is, the package header has a magic key and a rev.number, and compares the magic key with the change number of the terminal's buyer.

By dividing the deep image into 10 KB through the delta headers 1 to N and delta images 1 to N of the IoT terminal integrated management system 30, the memory use of the terminal is minimized in the update operation of the update agent. That is, when the update agent desires to install the firmware, it checks the integrity of the data, minimizes the memory usage by applying the deep image, and reboots after replacing the firmware.

6 and 7, a plurality of IoT devices are conveniently and stably managed through configuration setting and diagnosis and monitoring functions for the IoT device.

Let's look at the configuration setting technique.

6, the terminal integrated management server 310 of the integrated IoT terminal management system 30 responds to the inquiry of the config information of the system operator server 400 and, in response to the reset, . The IoT device 10 processes the inquiry of the terminal setting information according to the request of the IOT gateway 20 and processes the resetting.

Meanwhile, the service provider server 500 may access the terminal integrated management server 310 as well.

The above procedure provides a function to check and reset the configuration values of the device through the wireless network.

In addition, device diagnosis and monitoring technology will be discussed.

Referring to FIG. 7, the system operator server 400 sends a diagnostic request signal to the operation management server 410, and the operation management server 410 sends a signal requesting the LWM2M module 310 to request the diagnostic policy distribution. The LWM2M module 310 performs diagnostic policy distribution and execution, and collects a diagnostic log when an event is generated from the LWM2M clients. The collected votes are transmitted to the operation management server 410, and the diagnosis results are transmitted to the system operator server 400.

The above function is a service for diagnosing and monitoring a problem of a terminal remotely, and collects and provides status information of the terminal.

OTA-based terminal management technology, discloses a technology for conveniently and stably managing a plurality of IoT devices through device lock / data deletion and S / W installation management function for IoT devices.

Referring to FIG. 9, the service provider server 510 transmits a signal requesting terminal lock / data deletion to the terminal integrated management server 310. Then, the terminal integrated management server 310 sends a lock / data deletion request signal to the IoT gateway 20. The IOT gateway 20 receives a lock / data deletion request signal from the IoT device 10 and performs lock / data deletion processing when the terminal integrated management server 310 requests the lock / data deletion process.

10, when the service provider server A 520 requests the S / W package registration as the S / W installation management technology, the terminal integrated management server 310 receives the package registration approval from the system operator server 400 And accepts the package registration after accepting the request.

When the service provider server B 530 requests the S / W installation / change, the terminal integrated management server 310 transmits an installation / change request signal to the IoT gateway 20. Then, the IoT gateway 20 transmits an installation / change request signal to the IoT device 10. [ The IoT device 10 processes the S / W installation / change when the terminal integrated management server 310 requests it.

In addition, IOT service security technology will be discussed.

11, a DTLS security function is applied to the I / O gateway (G / W) -server section, and a PSK-DTLS or simple AES security technology is applied to the low-level IoT device and the G / Security technologies applied.

PSK-DTLS or simple AES security technology is applied between the IoT device 10 and the IoT gateway 20. DTLS is applied between the IoT gateway 20 and the IoT terminal integrated management system 30.

On the other hand, a large capacity / parallel data processing technique will be described.

Referring to FIG. 12, a firmware download and a firmware split loading function are provided for a firmware download service in which the load is concentrated at the time of firmware update.

The IoT device 10 requests the download server 320 for a firmware package. Then, the media manager of the download server 320 inquires the firmware. The media manager then performs loading via the package multi-loader. It will then start loading on the Delta Package Server. The delta package server divides and loads large packages and sends them to the media manager through the package multi-loader. The media manager will begin buffering and begin distribution via the MO (distribution device). If the IoT device fails to download the distributed package, the content range start of the IoT device 10 is activated to perform the firmware re-acquisition.

The large-volume firmware re-acquisition process supports a function to continue the download when an error occurs during downloading, and performs a firmware package cache process in case of a download failure in order to efficiently receive the download.

For large-capacity firmware split loading, a package multi-loader performs a firmware package split loading process at the time of a large-capacity firmware request, and a large-capacity file loading time is shortened through firmware split loading.

Referring to FIG. 13, an asynchronous communication model and a memory cache technology are applied for a system configuration for effectively processing a large capacity service request of the IoT device.

The IoT device 10 includes an IoT terminal integrated management system 30 having an asynchronous communication model connection unit for performing simultaneous connection of IoT devices. By adopting asynchronous communication method, we improved the performance by accepting large concurrent access request. Minimizing waiting time for terminal connection when demand for massive concurrent access is required.

The cache server 330 of the memory cache method is used to improve the processing speed to load the session information and transmit the information to the management engine 340. The management engine 340 operates the workflow engine to process the session.

As described above, an optimal embodiment has been disclosed in the drawings and specification. While specific terms have been employed herein, they are used for the purpose of describing the invention only and are not used to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: Iot devices
20: Iot Gateway
30: IoT terminal integrated management system

Claims (10)

1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
A low-power (LWM2M) module that supports OTA (Over The Air) and requests update execution for the Iot device when the update is executed,
A low power (LWM2M) client for receiving a firmware update command via a firmware update command receiver for a update execution request from the low power module and then calling a download agent (DL)
A download descriptor receiving unit of a download agent for receiving a download descriptor from a download server in response to a call signal from the low-
A download package check unit for checking the received download descriptor
A delta package downloading unit for downloading the package from the download server and subsequently calling the update agent (UA)
And a firmware installation unit of an update agent that installs the firmware according to the paging signal. The cloud-based terminal integrated management system of claim 1, 1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
The update agent of IoT installs the firmware through the IoT terminal integrated management system,
The update agent of the IoT communicates with the SHA1 algorithm in the delta package to perform the digest function from the deep image, then compares the digest of the delta package header with the valid packet to check the integrity,
A magic key and a rev.number are compared with each other and a magic key and a change number of a terminal key of the terminal are compared with each other, , Performs a reboot after replacing the firmware,
The method of claim 1 or 2, wherein the update of the deep image is performed by dividing the deep image into 10 KB through the delta headers 1 to N and the delta images 1 to N, thereby minimizing memory use of the terminal in the update operation of the agent. A cloud - based terminal integrated management system using oti 's technology of oti terminal. 1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
The terminal integrated management server of the IoT terminal integrated management system responds to the inquiry of the config information of the system operator server and, in response to the reset, requests inquiry / reset to the IoT gateway,
The IoT device processes the inquiry of the terminal setting information at the request of the IoT gateway and processes the reset,
Wherein the environment setting value of the device is confirmed and reset through the wireless network, and the cloud based terminal integrated management system using the OTI technology of the iOuti terminal supporting the low power / broadband network. 1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
The system operator server sends a diagnosis request signal to the operation management server, and the operation management server sends a signal to the LWM2M module unit to request the distribution of the diagnostic policy,
The LWM2M module performs diagnostic policy deployment and execution, collects diagnostic logs when events occur from LWM2M clients,
The collected logs are transmitted to the operation management server, and the diagnosis results are transmitted to the system operator server,
And collecting and providing the status information of the terminal as a service for diagnosing and monitoring the problem of the terminal remotely. The cloud-based terminal integrated management system using the OTIA technology of the iOuti terminal supporting the low power / broadband network. 1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
The service provider server transmits a signal requesting terminal lock / data deletion to the terminal integrated management server,
The terminal integrated management server sends a lock / data deletion request signal to the IoT gateway,
The IoT gateway receives a lock / data deletion request signal from the IoT device and performs a lock / data deletion process when the terminal integrated management server requests the lock / data deletion process. Cloud - based terminal integrated management system using OTOS technology. 1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
In response to the S / W package registration request from the service provider server A, the terminal integrated management server requests the package registration approval from the system operator server and accepts the package registration,
In response to the S / W installation / change request from the service provider server B, the terminal integrated management server transmits an install / change request signal to the IoT gateway, and the IoT gateway then transmits an install / change request signal to the IoT device, Wherein the terminal integrated management server processes the S / W installation / change when the terminal integrated management server requests the integrated terminal management server of the cloud based terminal using the OTI technology of the iOuti terminal supporting the low power / broadband network. 7. The method as claimed in claim 6, wherein the IOT gateway (G / W) -server section is DTLS security function and the low-level IoT device and G / W section are PSK-DTLS or simple AES security technology. Based integrated management system using the OTI technology of the iOuti terminal supporting the low power / broadband network. 1. A cloud-based terminal integrated management system using OTo technology for supporting low power / broadband networks including at least one Internet (IoT) device, IoT gateway, and IoT terminal integrated management system,
Provides firmware download and firmware split loading for the most heavily loaded firmware download service during firmware update,
The IoT device requests a firmware package from the download server,
The media manager of the download server then inquires the firmware,
The media manager then performs loading through the package multi-loader,
It then starts loading into the Delta Package Server (NAS)
The delta package server divides and loads large packages and sends them to the media manager through the package multi-loader,
Wherein the media manager starts buffering and starts distributing the firmware through the distribution device of the download server, wherein the media manager starts buffering and starts distributing the firmware through the distribution device of the download server. 9. The method of claim 8,
If the IoT device fails to download the distributed package, the content range start of the IoT device (ContentRangeStart) is activated to perform the firmware re-
Wherein the large capacity firmware re-download process supports a function of resuming when an error occurs during download and performs a firmware package cache process in case of a download failure in order to efficiently resume the download. A Cloud - based Terminal Integrated Management System Using AIS Technology. 9. The method of claim 8,
In the large-capacity firmware division loading, the package multi-loader performs the firmware package division loading processing at the time of requesting the large-capacity firmware, and the loading time of the large-capacity file is shortened through the firmware division loading. Cloud - based terminal integrated management system using OTOS technology.

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