WO2013177897A1 - Method for achieving end-to-end message push using geographical signal feature cluster - Google Patents

Method for achieving end-to-end message push using geographical signal feature cluster Download PDF

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Publication number
WO2013177897A1
WO2013177897A1 PCT/CN2012/083808 CN2012083808W WO2013177897A1 WO 2013177897 A1 WO2013177897 A1 WO 2013177897A1 CN 2012083808 W CN2012083808 W CN 2012083808W WO 2013177897 A1 WO2013177897 A1 WO 2013177897A1
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WO
WIPO (PCT)
Prior art keywords
push
message
signal feature
data
geographical
Prior art date
Application number
PCT/CN2012/083808
Other languages
French (fr)
Chinese (zh)
Inventor
刘柏池
Original Assignee
胜义科技股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from CN201210178842.7A external-priority patent/CN102843642B/en
Application filed by 胜义科技股份有限公司 filed Critical 胜义科技股份有限公司
Priority to US14/404,227 priority Critical patent/US9667579B2/en
Publication of WO2013177897A1 publication Critical patent/WO2013177897A1/en

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W4/00Services specially adapted for wireless communication networks; Facilities therefor
    • H04W4/02Services making use of location information
    • H04W4/029Location-based management or tracking services
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W4/00Services specially adapted for wireless communication networks; Facilities therefor
    • H04W4/02Services making use of location information
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L12/00Data switching networks
    • H04L12/02Details
    • H04L12/16Arrangements for providing special services to substations
    • H04L12/18Arrangements for providing special services to substations for broadcast or conference, e.g. multicast
    • H04L12/1859Arrangements for providing special services to substations for broadcast or conference, e.g. multicast adapted to provide push services, e.g. data channels
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W4/00Services specially adapted for wireless communication networks; Facilities therefor
    • H04W4/12Messaging; Mailboxes; Announcements
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L12/00Data switching networks
    • H04L12/02Details
    • H04L12/16Arrangements for providing special services to substations
    • H04L12/18Arrangements for providing special services to substations for broadcast or conference, e.g. multicast
    • H04L12/1845Arrangements for providing special services to substations for broadcast or conference, e.g. multicast broadcast or multicast in a specific location, e.g. geocast

Definitions

  • the present invention relates to active push technology, and more particularly to a method for implementing message push based on a cluster of cellular or WiFi wireless network signal features within a range of landmark location coordinates.
  • SMS Short Message Service
  • the methods can be divided into: Database Mining (Data Mining SMS) and Regions. Newsletter.
  • the database newsletter sends the newsletter through conditional settings such as gender, age, region, and then at a specified time, and the regional newsletter uses the switch in the designated area to detect the specified time to enter the area and send the newsletter.
  • the SMS method has the advantage of being simple and easy to implement.
  • the main disadvantage is that it requires the database support of the telecom operator, which will lead to a long message push planning process.
  • this method can meet the real-time demand of the mobile user to receive the service message, it is less accurate in grasping the precise and appropriate requirements for receiving the service message.
  • the structure of the WAP Push mainly includes: Push Initiator (PI).
  • the content type of the message push includes service notification and service loading. The following describes the working method of the service notification type: PI is the message provider, and pushes the access protocol (Push Access Protocol) to the PPG. Requesting a push notification of a message notification, PPG converts the notification of the service into binary form After that, it is transmitted to the mobile client through the OTA protocol (Over-the-Air Protocol). When the mobile client receives the notification, it can choose whether to link immediately or later.
  • OTA protocol Over-the-Air Protocol
  • the mobile client connects to the URL of the service provided by PPG in a normal PULL manner, and then obtains the content of the message.
  • the message is sent to the mobile client and displays the latest message. If you choose to link later, it will be stored in the mobile client for a period of time. Once the time limit is exceeded, the notification of the service will be automatically cleared.
  • the wireless push broadcast protocol can respond to different requests from each mobile user and respond to the action user within a certain time period to achieve active notification of real-time information, but to meet the precise and appropriate location of the mobile user in receiving the service message. In terms of demand, it is still a technical bottleneck for problems and breakthroughs that need to be overcome.
  • the active push broadcast based on the Bluetooth signal is also used. Although it has the best geographical conditions to receive service messages, its main drawback is that the device must be turned on and set to be detectable. In addition, the narrow definition of additional hardware cost and geographic conditions is also main problem. Summary of the invention
  • the active push method of the message proposed by the present invention is applicable to cellular and WiFi wireless networks.
  • a first device can be regarded as a message provider, and a user interface (UI) of the device side is used to set a landmark, and the message data related to the landmark is established, and then the message is pushed according to the message data.
  • UI user interface
  • a plurality of geographic signal feature clusters can be obtained from a signal feature database, and a message push table is established based on the acquired plurality of geographic signal feature clusters and the message data.
  • the message active push method of the present invention actively pushes the message by means of the signal characteristics detected by a second device.
  • the second device can be regarded as a message receiver, and the program actively propagating the message can be divided into a message notification and a message push.
  • the message notification program includes the following steps: According to the message push table, the message push server actively establishes a notification connection, and notifies the second device to extract the push condition; after receiving the notification, the second device detects the service cell base
  • the signal characteristics of the station or service AP are provided to the message push server from a plurality of geographic signal feature clusters in the message push list, a cluster of geographic signal features is selected to establish a push condition, and the push condition is returned to The second device.
  • the message pushing program includes the following steps: after receiving the push condition, the second device detects a signal characteristic of the serving cell base station or the serving AP, if the detected signal feature and the geographic in the push condition If a signal characteristic in the signal feature cluster is the same, the second device provides the detected signal feature to a positioning operation Calculating a server to calculate a location of the second device; if the calculated location is within a range of coordinates of the landmark location, the message push server actively pushes a message to the second device.
  • the above method of the present invention is a pure software architecture, which can be deployed in a physical machine through program code. When the machine loads the program code and executes it, the machine becomes the means for practicing the invention.
  • the invention has the advantages of enabling the mobile user to obtain the latest service information in real time, and to actively push the appropriate service message to the mobile user at an appropriate time and at the appropriate place, and to improve the value and practicality of the service message.
  • the implementation of the active push for pure software services mobile users have no additional hard equipment costs, the receiving area is also larger; another pusher can control the push content and time points, the operation can skip the telecommunication operators Restrictions make the business model of the push more flexible, and the content of the push is not limited to the use of text, but also the way of displaying pictures and multimedia.
  • FIG. 1 is a schematic diagram of a message push network according to an embodiment of the present invention.
  • FIG. 2 is a schematic structural diagram of a message push establishment mechanism according to an embodiment of the present invention.
  • FIG. 3 is a schematic flow chart of obtaining a cluster of geographic signal features from a cellular sub-database according to an embodiment of the present invention
  • FIG. 4 is a schematic flow chart of obtaining a cluster of geographic signal features from a hybrid secondary database according to an embodiment of the present invention
  • FIG. 5 is a schematic structural diagram of a message push execution mechanism according to an embodiment of the present invention.
  • FIG. 6 is a schematic diagram of a process for actively propagating a message according to a detected CGI code parameter according to an embodiment of the present invention
  • FIG. 7 is a schematic diagram of a process for actively propagating a message according to a detected MAC address parameter according to an embodiment of the present invention.
  • FIG. 1 is a schematic diagram of a message push network according to an embodiment of the present invention, including a plurality of GPS satellites 101, 102, 103, a plurality of cellular base stations 104, 105, 106, and a plurality of WiFi APs 107, 108, 109, 110.
  • the plurality of GPS satellites transmit positioning signals to the ground all the time, and the plurality of cell base stations
  • Each cell base station has a common control channel (CCH) that can continuously broadcast its signals in a cellular network to provide a unique Cell Global Identity (CGI) code.
  • CGI Cell Global Identity
  • Each WiFi AP in the AP has a CCH that can continuously broadcast its signals in the WiFi network to provide a unique Medium Access Control (MAC) address.
  • MAC Medium Access Control
  • the message pushing server 114, the data computing server 115, the positioning operation server 116, and the signal feature database 117 are installed in the cloud, and the first device 111, the second device 112, and the like by a cellular or WiFi wireless network.
  • the third device 113 performs transmission and reception of data.
  • the first device 111 is a message provider and the second device 112 is a message recipient.
  • the first device 111 and the second device 112 may include, but are not limited to, a smart phone, a personal digital assistant (PDA), a tablet computer, or a notebook computer.
  • the third device 113 is a signal feature data provider and may include, but is not limited to, a smart phone and a personal digital assistant (PDA).
  • the third device 113 is configured to collect signal feature data to provide the signal feature database 117 for updating data, by: using the device-side application from the plurality of GPS satellites, the plurality of cell base stations, and The plurality of WiFi APs acquire signal characteristic data, including a GPS location coordinate, a CGI code parameter and a signal strength value of the plurality of cell base stations, a MAC address parameter and a signal strength value of the plurality of WiFi APs, wherein the GPS location coordinates
  • the obtained working principle is roughly as follows: A presence state of at least 4 GPS satellite signals is detected, and the ToA value is measured according to the signal from the satellite to calculate the position coordinates.
  • the third device 113 transmits the plurality of signal feature data to the data computing server 115 via the API via the connection of a cellular or WiFi wireless network (e.g., 104 or 108 in Fig. 1).
  • the data operation server 115 After receiving the plurality of signal feature data, replying the received confirmation signal to the third device 113, and the data operation server 115 searches the signal feature database 117 to acquire signal characteristic data of the corresponding database, and performs data fusion ( Fusion) and the location estimate, which refers to the location of the cell base station and the WiFi AP.
  • the signal feature database 117 updates or stores the data and records the location information status.
  • FIG. 2 it is a schematic diagram of the architecture of the establishment mechanism.
  • the first device 111 sets a landmark using the UI of the device side, and establishes push message data related to the landmark, and a landmark can be regarded as an independent event.
  • the landmark location coordinates may be obtained from a third party service provider such as Google, and the message data may include, but is not limited to, at least one message recipient, a landmark location coordinate, a push distance, a push start and a deadline date and time.
  • a message content which may include, but is not limited to, text, cards, images, sounds, and images.
  • a data encryption unit 201 is responsible for performing compression and encryption on the message data, and transmitting the encrypted message data to a backup database 202 for storage.
  • the first device 111 transmits the encrypted message data to the message push server 114 via the API, due to the transmission characteristics of the wireless network, if If the encrypted message data transmission fails, a data resending unit 203 will be activated and retrieved from the backup database 202 to perform the resend operation.
  • the message push server 114 is provided with a data decryption unit 204, a data queue unit 205, a feature cluster unit 206, and an event generation unit 207. After the message push server 114 receives the encrypted message data, it replies to the received confirmation signal to the first device 111, and the decryption unit 204 is responsible for performing decompression and decryption on the message data. Generally, the message pushing server 114 may process multiple push events simultaneously, and the data queue unit 205 is configured to assign an event priority value according to the date and time of the push start in the decrypted message data, based on the priority. The weights are arranged from high to low to the plurality of decrypted message data.
  • the feature clustering unit 206 can acquire a plurality of clusters of geographic signal features from the signal feature database 117.
  • the signal feature database 117 includes a cellular sub-database 208 and a hybrid secondary database 209.
  • the cellular secondary database 208 stores a plurality of cellular base station data, and each cell base station data records a unique CGI code parameter and location information.
  • the database 209 stores a plurality of WiFi AP data, and each WiFi AP data records at least one CGI code parameter, a unique MAC address parameter, and location information, where the CGI code parameter includes a Mobile Country Code (MCC), a mobile network.
  • MNC Mobile Network Code
  • LAC Location Area Code
  • CID Cell Identity
  • the feature clustering unit 206 may determine an MCC according to the landmark location coordinates in the decrypted message data (step 301), and use the MCC as a key to perform the search of the cellular sub-database 208 to obtain a corresponding database.
  • Multiple cell base station data step 302
  • Step 303 is performed to calculate the MCC based on the acquired plurality of cell base station data.
  • the number of MNCs, and the number of clusters is determined according to the number of MNCs.
  • the plurality of cell base station data of the same MCC is divided into a plurality of clusters according to the MNC.
  • the cluster is divided into:
  • the cell base station data with the same MNC is divided into the same cluster for the plurality of cell base station data.
  • multiple push representative points are obtained from each of the plurality of clusters.
  • the implementation manner is as follows: a cluster Ck, including n point data, each data point has a position coordinate and a unique CGI code, and calculates a distance value of each data point and a coordinate position coordinate in the decrypted message data, if the distance value If the distance is less than the push distance, the data point becomes a push representative point, and the CGI code of the data point is stored.
  • the set Pk is a cluster of geographic signal features of a message push according to an embodiment of the present invention, and the geographic signal feature is a CGI code.
  • the feature clustering unit 206 can determine an MCC according to the landmark location coordinates in the decrypted message data (step 401), and use the MCC as a key to perform the search of the hybrid secondary database 209 to obtain a corresponding database.
  • Multiple WiFi AP data step 402).
  • a plurality of push representative points are obtained from the cluster.
  • the implementation manner is as follows: each data point of the cluster has a position coordinate and a unique MAC address, and calculates a distance value of each data point and a coordinate position coordinate in the decrypted message data. If the distance value is smaller than the push distance, Then the data point becomes a push representative point and stores the MAC address of the data point.
  • the set Q is a cluster of geographic signal features of a message push according to an embodiment of the present invention, and the geographic signal feature is a MAC address.
  • the feature clustering unit 206 can acquire a cluster of k+1 geographic signal features from a unicase landmark, without departing from the spirit of the present invention.
  • the attribute of the landmark data content is provided according to the first device 111, allowing A plurality of landmarks exist simultaneously, that is, a plurality of landmarks.
  • the feature clustering unit 206 can acquire a cluster of LX (k+1) geographic signal features from the group of landmarks, where L is the number of landmarks.
  • the feature clustering unit 206 passes the acquired cluster of the plurality of geographic signal features to the event generating unit 207, the event generating unit 207 assigns a message pushing ID, and establishes a message pushing table, wherein the message is pushed.
  • the table records the message push ID, the message recipient in the decrypted message data, the date and time of the push start and end, the message content, and the received cluster of multiple geographic signal features (ie, sets Pk and Q). .
  • the message push server 114 is further provided with an event notification unit 501, an event database 502, an event service unit 503, and an event resending unit 504.
  • the event generating unit 207 after establishing a message push table, passes to the event notifying unit 501.
  • the event notification unit 501 is responsible for actively establishing the notification connection, notifying the second device 112 (ie, the message receiver) to extract the push condition, and simultaneously pushing the message in the message push table.
  • the ID and the message content are passed to the event database 502 for storage.
  • the event notification unit 501 After the second device 112 receives the notification, a signal characteristic is detected, and the event notification unit 501 is established to obtain the push condition, and the detected signal feature includes a CGI code parameter or a MAC address parameter. It should be noted that, in an embodiment of the invention, the event notification unit 501 can provide different push conditions according to the signal characteristics detected by the second device 112. Based on the obtained push condition, the second device 112 performs an event check on the device side. If the push condition is a presence status, the second device 112 establishes a connection, and the event service unit 503 performs a message content push. .
  • the flow diagram of the active push of the message is based on the detected CGI code parameters.
  • the program that the message is actively pushed can be divided into message notification and message promotion.
  • the message notification procedure the following steps are included: after the second device 112 receives the notification, if the CGI code parameter of a serving cell base station (such as 106 in FIG. 1) is detected as a presence status (step 601), then Transmitting the MCC, the MNC, and the LAC in the detected CGI code to the event notification unit 501 by using an API (step 602), if detecting that the CGI code parameter of a serving cell base station is an non-existent state, Indicates that the second device 112 actively pushes the message using the MAC address parameter (step 603).
  • a cluster of the plurality of geographic signal features (ie, the set Pk) in the table may be pushed from the message to select a cluster.
  • the implementation manner is as follows: the event notification unit 501 associates the received MCC, the MNC, and the LAC with the multiple locations. The MCC, the MNC, and the LAC of each cluster in the cluster of the signal characteristics are compared. If the MCC, the MNC, and the LAC are in a presence state, the same cluster is selected, if the MCC, the MNC, And if the LAC is in an unexistent state, the MCC and the MNC are further compared according to the MCC, and the same cluster is selected.
  • a push condition is established based on the selected cluster of geographic signal features and transmitted to the second device 112.
  • the push condition includes at least one LAC and at least one CID in the selected cluster of geographic signal features, the message push ID in the message push list, and the time and time of the push start and end.
  • step 606 an event check is performed within the date and time of the start and end of the push using the detected CGI code and signal strength value of the serving cell base station.
  • the implementation manner is: if the LAC and the CID in the CGI code detected by the second device 112 are the same as the LAC and CID in the cluster of the geographic signal feature in the push condition (step 607), the message is transmitted.
  • the broadcast ID and the CGI code and signal strength values of the serving cell base station are sent to the event service unit 503 (step 608), otherwise, step 606 is continued.
  • step 609 the event service unit 503 transmits the received CGI code and signal strength value of the serving cell base station to the positioning operation server 116, and calculates the location of the second device 112, if the calculated location is located in the push broadcast.
  • the process proceeds to step 611, otherwise, the active push message is terminated (step 612).
  • the push circle refers to a circle defined by the coordinates of the landmark position, and the push distance is a radius.
  • the event service unit 503 can obtain the content of the message from the event database 502 according to the received push ID, and perform active push of the message content to the second device 112.
  • the program that the message is actively pushed can be divided into message notification and message promotion.
  • the message notifying program includes the following steps: the second device 112 detects a MAC address parameter of a serving AP (such as 110 in FIG. 1) (step 701), and transmits the MAC address using the API to the event notifying unit 501 ( Step 702).
  • Step 703 according to the received MAC address, the event notification unit 501 can directly select a cluster (ie, set Q) from the plurality of geographic signal feature clusters in the message push table.
  • a cluster ie, set Q
  • Step 704 is performed to establish a push condition according to the selected geographic signal feature cluster and transmit to the second device 112.
  • the push condition includes the selected cluster of geographic signal features The MAC address parameter, the message push ID in the message push list, and the date and time of the push start and end.
  • step 705 an event check is performed using the detected MAC address and signal strength value of the serving AP within the date and time of the start and end of the push.
  • the implementation manner is: if the MAC address detected by the second device 112 is the same as the MAC address in the cluster of the geographic signal features in the push condition (step 706), transmitting the message push ID and the service AP The MAC address and signal strength values are passed to the event service unit 503 (step 707), otherwise, step 705 is continued.
  • Step 708 is performed, the event service unit 503 transmits the received MAC address and signal strength value of the service AP to the positioning operation server 116, and calculates the location of the second device 112, if the calculated location is located in the push circle. (Step 709), then go to step 710, otherwise, the active push message is ended (step 711).
  • step 710 based on the received push advertisement ID, the event service unit 503 can obtain the message content from the event database 502 and perform active push message content to the second device 112.
  • the second device 112 after receiving the notification of the push condition, the second device 112, such as a smart phone or a tablet computer, may simultaneously detect a CGI code parameter and a service of a serving cell base station.
  • the MAC address parameter of the AP At this time, the method of actively propagating the message is performed, and the steps are as described above (steps 602 to 612).
  • the push event may fail due to the transmission characteristics of the wireless network.
  • the event service unit 503 transmits the received message push ID. Go to the event resending unit 504.
  • the event resending unit 504 can obtain the message content from the event database 503 and is responsible for performing the re-pushing of the message content.
  • the method of the present invention is a pure software architecture, and can be disposed in a physical medium by using a program code, such as a hard disk, a CD, or any electronic device (such as a smart phone or a computer).
  • a program code such as a hard disk, a CD, or any electronic device (such as a smart phone or a computer).
  • the read storage medium when the machine loads the program code and executes (eg, the smart phone is loaded and executed), the machine becomes the device for practicing the present invention.
  • the above method and apparatus of the present invention can also be transmitted by a transmission medium such as a cable, an optical fiber, or any transmission type, when the program code is received, loaded, and executed by a machine (such as a smart phone). It becomes a device for carrying out the invention.

Abstract

Proposed is a method for achieving end-to-end message push using a geographical signal feature cluster. The method comprises: a message provider using a device to establish message data relevant to a landmark; according to the message data, a message push server obtaining from a signal feature database a plurality of geographical signal feature clusters to establish a message push table; according to the record in the message push table, the message push server actively establishing an online notification to notify a message receiver to extract a push condition; the message receiver using a device to detect a signal feature from a honeycomb or WiFi wireless network and provide same to the message push server to establish the push condition; and after receiving the push condition, the message receiver using a device to detect a signal feature from the honeycomb or WiFi wireless network, and if it is detected that the signal feature is the same as a signal feature in the geographical signal feature cluster in the push condition, the message push server actively pushing a message to the message receiver.

Description

使用地理信号特征群集实现端到端讯息推播的方法  Method for implementing end-to-end message push using geographic signal feature clustering
技术领域 Technical field
本发明关于主动推播技术, 且特别有关于一种可依据地标位置坐标的一 范围内的蜂巢式或 WiFi无线网络信号特征群集来实现讯息推播的方法。 背景技术  The present invention relates to active push technology, and more particularly to a method for implementing message push based on a cluster of cellular or WiFi wireless network signal features within a range of landmark location coordinates. Background technique
随着行动上网用户快速成长, 多样化类型的以位置信息为基础的加值应用 服务亦呈现高度性发展。 该服务讯息的取得, 目前大多数仍沿用传统的技术, 主要是利用 PULL 同步互动模式, 其方法为: 当行动用户在有服务需求的情况 下, 由行动客户端主动要求建立联机至服务器端拉取服务讯息。 针对某些要求 实时性的加值应用服务而言, 该模式很有可能会因为时间、 地点因素的关系而 直接影响到服务讯息的价值性和实用性。 为因应行动用户能实时、 即地取得最 新的服务讯息, 发展 PUSH异步互动模式技术, 在适当的时间且适当的地点主 动推播合适的服务讯息给行动用户已经形成相关以位置信息为基础的加值应用 服务领域的关注与重视。  With the rapid growth of mobile Internet users, the diversified types of location-based value-added application services have also developed at a high level. Most of the service information is still used in the traditional technology, mainly using the PULL synchronous interaction mode. The method is as follows: When the mobile user has the service demand, the mobile client actively requests to establish the connection to the server. Take the service message. For some value-added application services that require real-time, this model is likely to directly affect the value and practicability of service messages due to time and location factors. In order to respond to mobile users, they can obtain the latest service information in real time, and develop PUSH asynchronous interactive mode technology. Actively push appropriate service messages at appropriate time and in appropriate locations for mobile users to form related information based on location information. Value application and attention in the field of application services.
在蜂巢无线网络环境下, 现阶段主动推播 (active push) 服务讯息, 大多数 是通过简讯 (Short Message Service, SMS )来达成, 其方法可概分为: 数据库简 讯 (Data Mining SMS ) 和区域简讯。 数据库简讯通过条件设定如性别、 年龄、 地区, 然后在指定的时间发送简讯, 而区域简讯利用指定区域的交换机侦测于 指定时间进入该区域后发送简讯。 在技术面上, 简讯方法具有简单、 容易执行 的优点, 其主要的缺点是, 需要电信营运商的数据库支持, 如此将导致拢长的 讯息推播规划程序。 尽管该方法可以满足行动用户在接收服务讯息的实时性需 求, 但在提供接收服务讯息的精准适地性需求上, 较无法准确性的掌握。 另一 个主动推播技术, 是通过无线应用协议论坛 (WAP Forum) 所制定的无线推播 协议 (WAP Push Protocol) 来提供讯息推播。 该 WAP Push的架构, 主要包括: Push Initiator (PI). Push Proxy Gateway (PPG) 以及 WAP Client三个部分。 讯 息推播的内容型态包括服务通知与服务加载, 其中, 针对服务通知型态的工作 方法做一简单的如下说明: PI 是讯息提供者, 以推播存取协议 (Push Access Protocol)向 PPG提出讯息通知的推播要求, PPG将服务的通知转成二进制形式 后, 再通过 OTA协议 (Over-the- Air Protocol) 传送至行动客户端。 当行动客户 端收到通知后, 可以选择是否立即连结或稍后连结, 如果选择立即连结, 行动 客户端通过 PPG以一般的 PULL方式连结到提供服务的 URL地址取得讯息内 容, 接着以 XML的型态将讯息内容传送至行动客户端, 并显示最新的讯息, 如 果选择稍后连结, 则会先储存在行动客户端一段时间, 一旦超过时限将会自动 清除该服务的通知。 无线推播协议可以依据每个行动用户所提出的不同要求, 并在特定时间内将通知讯息响应给行动用户, 达成实时信息的主动通知, 但对 满足行动用户在接收服务讯息的精准适地性需求上, 仍是需要克服的问题与突 破的技术瓶颈。 In the cellular wireless network environment, active push service messages are mostly achieved through Short Message Service (SMS). The methods can be divided into: Database Mining (Data Mining SMS) and Regions. Newsletter. The database newsletter sends the newsletter through conditional settings such as gender, age, region, and then at a specified time, and the regional newsletter uses the switch in the designated area to detect the specified time to enter the area and send the newsletter. On the technical side, the SMS method has the advantage of being simple and easy to implement. The main disadvantage is that it requires the database support of the telecom operator, which will lead to a long message push planning process. Although this method can meet the real-time demand of the mobile user to receive the service message, it is less accurate in grasping the precise and appropriate requirements for receiving the service message. Another active push technology is to provide message push through the WAP Push Protocol developed by the WAP Forum. The structure of the WAP Push mainly includes: Push Initiator (PI). Push Proxy Gateway (PPG) and WAP Client. The content type of the message push includes service notification and service loading. The following describes the working method of the service notification type: PI is the message provider, and pushes the access protocol (Push Access Protocol) to the PPG. Requesting a push notification of a message notification, PPG converts the notification of the service into binary form After that, it is transmitted to the mobile client through the OTA protocol (Over-the-Air Protocol). When the mobile client receives the notification, it can choose whether to link immediately or later. If you choose to link immediately, the mobile client connects to the URL of the service provided by PPG in a normal PULL manner, and then obtains the content of the message. The message is sent to the mobile client and displays the latest message. If you choose to link later, it will be stored in the mobile client for a period of time. Once the time limit is exceeded, the notification of the service will be automatically cleared. The wireless push broadcast protocol can respond to different requests from each mobile user and respond to the action user within a certain time period to achieve active notification of real-time information, but to meet the precise and appropriate location of the mobile user in receiving the service message. In terms of demand, it is still a technical bottleneck for problems and breakthroughs that need to be overcome.
于主动推播技术上, 除了前述的方法外, 以蓝牙讯号为基础的主动推播亦 为使用的方法。 虽然拥有较佳的地理条件设定以接收服务讯息, 其最主要的缺 点, 装置是必需开启蓝牙, 并且设定为可被侦测, 此外, 额外的硬设备成本和 地理条件的狭义性定义也是主要问题。 发明内容  In addition to the aforementioned methods, the active push broadcast based on the Bluetooth signal is also used. Although it has the best geographical conditions to receive service messages, its main drawback is that the device must be turned on and set to be detectable. In addition, the narrow definition of additional hardware cost and geographic conditions is also main problem. Summary of the invention
本发明提出的讯息主动推播方法适用于蜂巢式和 WiFi无线网络。一第一装 置可视为一讯息提供者, 借助装置端的使用者接口 (user interface, UI)设定一地 标, 并建立相关于该地标的讯息数据, 接着, 依据该讯息数据一讯息推播服务 器能从一信号特征数据库获取多个地理信号特征群集, 基于该获取到的多个地 理信号特征群集和该讯息数据建立一讯息推播表。  The active push method of the message proposed by the present invention is applicable to cellular and WiFi wireless networks. A first device can be regarded as a message provider, and a user interface (UI) of the device side is used to set a landmark, and the message data related to the landmark is established, and then the message is pushed according to the message data. A plurality of geographic signal feature clusters can be obtained from a signal feature database, and a message push table is established based on the acquired plurality of geographic signal feature clusters and the message data.
本发明的讯息主动推播方法借助一第二装置检测到的信号特征, 进行讯息 的主动推播。 该第二装置可视为一讯息接收者, 讯息主动推播的程序可分为讯 息通知与讯息推播。 于讯息通知程序, 包括下列步骤: 依据讯息推播表, 该讯 息推播服务器主动建立通知联机, 通知该第二装置提取推播条件; 当接收到该 通知之后, 该第二装置检测服务细胞基地台或服务 AP 的信号特征并提供给该 讯息推播服务器自讯息推播表中的多个地理信号特征群集中, 选择一地理信号 特征群集以建立推播条件, 且回传该推播条件到该第二装置。 于讯息推播程序, 包括下列步骤: 当接收到该推播条件之后, 该第二装置检测服务细胞基地台或 服务 AP 的信号特征, 若检测到的该信号特征与该推播条件中的地理信号特征 群集中的一信号特征相同, 则该第二装置提供该检测到的信号特征给一定位运 算服务器以计算该第二装置的位置; 如果该计算到的位置位于该地标位置坐标 的一范围内, 则该讯息推播服务器主动推播讯息至该第二装置。 The message active push method of the present invention actively pushes the message by means of the signal characteristics detected by a second device. The second device can be regarded as a message receiver, and the program actively propagating the message can be divided into a message notification and a message push. The message notification program includes the following steps: According to the message push table, the message push server actively establishes a notification connection, and notifies the second device to extract the push condition; after receiving the notification, the second device detects the service cell base The signal characteristics of the station or service AP are provided to the message push server from a plurality of geographic signal feature clusters in the message push list, a cluster of geographic signal features is selected to establish a push condition, and the push condition is returned to The second device. The message pushing program includes the following steps: after receiving the push condition, the second device detects a signal characteristic of the serving cell base station or the serving AP, if the detected signal feature and the geographic in the push condition If a signal characteristic in the signal feature cluster is the same, the second device provides the detected signal feature to a positioning operation Calculating a server to calculate a location of the second device; if the calculated location is within a range of coordinates of the landmark location, the message push server actively pushes a message to the second device.
本发明上述的方法是纯软件架构, 可以通过程序代码布设于实体机器中。 当机器加载程序代码且执行时, 机器成为用以实行本发明的装置。  The above method of the present invention is a pure software architecture, which can be deployed in a physical machine through program code. When the machine loads the program code and executes it, the machine becomes the means for practicing the invention.
本发明具有的优点在于使行动用户能实时、 即地取得最新的服务讯息, 在 适当的时间且适当的地点主动推播合适的服务讯息给行动用户、 提高服务讯息 的价值性和实用性。 且实施上主动推播为纯软件服务, 行动用户没有额外的硬 设备成本, 接收区域范围也更大; 另推播者可自己操控推播内容及时间点, 操 作上可跳过电信营运商的限制, 使推播的商业模式更灵活, 且推播内容不限于 使用文字, 亦可展现图片及多媒体等方式。 附图说明  The invention has the advantages of enabling the mobile user to obtain the latest service information in real time, and to actively push the appropriate service message to the mobile user at an appropriate time and at the appropriate place, and to improve the value and practicality of the service message. And the implementation of the active push for pure software services, mobile users have no additional hard equipment costs, the receiving area is also larger; another pusher can control the push content and time points, the operation can skip the telecommunication operators Restrictions make the business model of the push more flexible, and the content of the push is not limited to the use of text, but also the way of displaying pictures and multimedia. DRAWINGS
图 1为本发明实施例的讯息推播网络的示意图;  1 is a schematic diagram of a message push network according to an embodiment of the present invention;
图 2为本发明实施例的讯息推播建立机制的架构示意图;  2 is a schematic structural diagram of a message push establishment mechanism according to an embodiment of the present invention;
图 3 为本发明实施例中自蜂巢次数据库获取地理信号特征群集的流程示意 图;  3 is a schematic flow chart of obtaining a cluster of geographic signal features from a cellular sub-database according to an embodiment of the present invention;
图 4为本发明实施例中自混合次数据库获取地理信号特征群集的流程示意 图;  4 is a schematic flow chart of obtaining a cluster of geographic signal features from a hybrid secondary database according to an embodiment of the present invention;
图 5为本发明实施例的讯息推播执行机制的架构示意图;  FIG. 5 is a schematic structural diagram of a message push execution mechanism according to an embodiment of the present invention;
图 6为本发明实施例中依据检测到的 CGI码参数进行讯息主动推播的流程 示意图;  6 is a schematic diagram of a process for actively propagating a message according to a detected CGI code parameter according to an embodiment of the present invention;
图 7为本发明实施例中依据检测到的 MAC地址参数进行讯息主动推播的流 程示意图。  FIG. 7 is a schematic diagram of a process for actively propagating a message according to a detected MAC address parameter according to an embodiment of the present invention.
图中:  In the picture:
101、 102、 103 -GPS卫星;  101, 102, 103 - GPS satellites;
104、 105、 106-细胞基地台;  104, 105, 106-cell base station;
107、 108、 109、 110- WiFi AP;  107, 108, 109, 110-WiFi AP;
111-第一装置;  111-first device;
112-第二装置;  112-second device;
113-第三装置; 117-信号特征数据库 113-third device; 117-Signal Feature Database
201-数据加密单元;  201-data encryption unit;
202-备份数据库;  202-Back up the database;
203-数据重送单元;  203-data resending unit;
204-数据解密单元;  204-data decryption unit;
205-数据队列单元;  205-data queue unit;
206-特征群集单元;  206-feature cluster unit;
207-事件产生单元;  207-event generating unit;
208-蜂巢次数据库;  208 - Honeycomb sub-database;
209-混合次数据库;  209-mixed secondary database;
301~306-步骤;  301~306-steps;
401~405-步骤;  401~405-steps;
501-事件通知单元  501-event notification unit
502-事件数据库  502-Event Database
503-事件服务单元;  503-event service unit;
504-事件重送单元;  504-event retransmission unit;
具体实施方式 detailed description
下面结合附图和具体实施例对本发明作进一步说明, 以使本领域的技术人 员可以更好的理解本发明并能予以实施, 但所举实施例不作为对本发明的限定。  The present invention will be further described in conjunction with the accompanying drawings and specific embodiments, which are to be understood by those skilled in the art.
图 1 为依据本发明实施例的讯息推播网络的示意图, 包括多个 GPS 卫星 101、 102、 103 、 多个蜂巢细胞基地台 104、 105、 106、 多个 WiFi AP 107、 108、 109、 110、 一第一装置 111、 一第二装置 112、 一第三装置 113、 一讯息推播服 务器 114、 一数据运算服务器 115、 一定位运算服务器 116, 以及一信号特征数 据库 117。 该多个 GPS卫星全天候向地面传送定位信号, 该多个细胞基地台中 的每一细胞基地台具有一公共控制频道 (common control channel, CCH), 其可以 持续在蜂巢式网络中广播其信号来提供一唯一细胞全局识别 (Cell Global Identity, CGI)码, 该多个 WiFi AP中的每一 WiFi AP具有一 CCH, 其可以持续在 WiFi 网络中广播其讯号来提供一唯一媒介访问控制 (Medium Access Control, MAC)地 址。 需注意的是, 该 GPS卫星、 该细胞基地台和该 WiFi AP的数目并不限于图 1所示的数目, 在不悖离本发明精神的前提下, 在不同实施例中该数目可以有所 变化。 1 is a schematic diagram of a message push network according to an embodiment of the present invention, including a plurality of GPS satellites 101, 102, 103, a plurality of cellular base stations 104, 105, 106, and a plurality of WiFi APs 107, 108, 109, 110. A first device 111, a second device 112, a third device 113, a message push server 114, a data operation server 115, a location calculation server 116, and a signal feature database 117. The plurality of GPS satellites transmit positioning signals to the ground all the time, and the plurality of cell base stations Each cell base station has a common control channel (CCH) that can continuously broadcast its signals in a cellular network to provide a unique Cell Global Identity (CGI) code. Each WiFi AP in the AP has a CCH that can continuously broadcast its signals in the WiFi network to provide a unique Medium Access Control (MAC) address. It should be noted that the number of the GPS satellites, the cell base station, and the WiFi AP is not limited to the number shown in FIG. 1. Without departing from the spirit of the present invention, the number may be different in different embodiments. Variety.
该讯息推播服务器 114、 该数据运算服务器 115、 该定位运算服务器 116, 以及该信号特征数据库 117架设于云端, 通过蜂巢式或 WiFi无线网络与该第一 装置 111、 该第二装置 112, 以及该第三装置 113进行数据的传送与接收。 该第 一装置 111 是讯息提供者, 而该第二装置 112是讯息接收者。 该第一装置 111 和该第二装置 112可以包括但不限于智能型手机、 个人数字助理 (PDA)、 平板计 算机或笔记型计算机。 该第三装置 113 是信号特征数据提供者, 可以包括但不 限于智能型手机和个人数字助理 (PDA) 。 值得注意的是, 该第一装置 111 和该 第二装置 112可视为各自独立的客户端, 在不悖离本发明精神的前提下, 在不 同实施例中亦可视为同一客户端。 该第三装置 113 用于收集信号特征数据, 以 提供该信号特征数据库 117进行数据的更新, 其实施方式为: 通过该装置端的 应用程序自该多个 GPS卫星、 该多个细胞基地台, 以及该多个 WiFi AP获取信 号特征数据, 包括一 GPS位置坐标、 该多个细胞基地台的 CGI码参数和信号强 度值、 该多个 WiFi AP的 MAC地址参数和信号强度值, 其中, GPS位置坐标的 取得的工作原理大致如下: 检测到至少 4个 GPS卫星讯号的一存在状态, 依据 来自卫星的讯号测量 ToA值以计算出位置坐标。接着, 借助蜂巢式或 WiFi无线 网络 (如图 1中的 104或 108)的联机, 该第三装置 113将该多个信号特征数据通 过 API传送到该数据运算服务器 115。于接收到该多个信号特征数据之后, 回复 已接收的确认讯号至该第三装置 113, 同时该数据运算服务器 115搜寻该信号特 征数据库 117 以获取相应的数据库的信号特征数据, 执行数据融合 (fusion)以及 位置的估算, 该位置指细胞基地台和 WiFi AP的位置。 依据该数据运算服务器 115的融和数据, 该信号特征数据库 117进行数据的更新或储存, 且记录位置信 息状态。  The message pushing server 114, the data computing server 115, the positioning operation server 116, and the signal feature database 117 are installed in the cloud, and the first device 111, the second device 112, and the like by a cellular or WiFi wireless network. The third device 113 performs transmission and reception of data. The first device 111 is a message provider and the second device 112 is a message recipient. The first device 111 and the second device 112 may include, but are not limited to, a smart phone, a personal digital assistant (PDA), a tablet computer, or a notebook computer. The third device 113 is a signal feature data provider and may include, but is not limited to, a smart phone and a personal digital assistant (PDA). It should be noted that the first device 111 and the second device 112 can be regarded as separate clients, and can be regarded as the same client in different embodiments without departing from the spirit of the present invention. The third device 113 is configured to collect signal feature data to provide the signal feature database 117 for updating data, by: using the device-side application from the plurality of GPS satellites, the plurality of cell base stations, and The plurality of WiFi APs acquire signal characteristic data, including a GPS location coordinate, a CGI code parameter and a signal strength value of the plurality of cell base stations, a MAC address parameter and a signal strength value of the plurality of WiFi APs, wherein the GPS location coordinates The obtained working principle is roughly as follows: A presence state of at least 4 GPS satellite signals is detected, and the ToA value is measured according to the signal from the satellite to calculate the position coordinates. Next, the third device 113 transmits the plurality of signal feature data to the data computing server 115 via the API via the connection of a cellular or WiFi wireless network (e.g., 104 or 108 in Fig. 1). After receiving the plurality of signal feature data, replying the received confirmation signal to the third device 113, and the data operation server 115 searches the signal feature database 117 to acquire signal characteristic data of the corresponding database, and performs data fusion ( Fusion) and the location estimate, which refers to the location of the cell base station and the WiFi AP. Based on the fusion data of the data computing server 115, the signal feature database 117 updates or stores the data and records the location information status.
如图 2、 图 3和图 4所示, 主要依据本发明的一实施例描述如何建立讯息 推播。 如图 2所示, 为一建立机制的架构示意图。 该第一装置 111使用装置端 的 UI设定一地标, 并建立相关于该地标的推播讯息数据, 一地标可视为一独立 事件。 该地标位置坐标可自第三方服务商如 Google取得, 该讯息数据可以包括 但不限于至少一讯息接收者、 一地标位置坐标、 一推播距离、 一推播起始和截 止的日期与时间, 以及一讯息内容, 该讯息内容可以包括但不限于文字、 卡片、 图像、 声音和影像。 接着, 一数据加密单元 201 负责对该讯息数据执行压缩和 加密, 并传递该加密讯息数据至一备份数据库 202储存。 借助蜂巢式或 WiFi无 线网络 (如图 1中的 105或 109)的联机, 该第一装置 111将该加密讯息数据借助 API传送至该讯息推播服务器 114, 由于无线网络的传输特性, 如果该加密讯息 数据传送失败, 则一数据重送单元 203将被启动并从该备份数据库 202取得该 加密讯息数据来进行重送的动作。 As shown in FIG. 2, FIG. 3 and FIG. 4, how to create a message is mainly described according to an embodiment of the present invention. Push. As shown in Figure 2, it is a schematic diagram of the architecture of the establishment mechanism. The first device 111 sets a landmark using the UI of the device side, and establishes push message data related to the landmark, and a landmark can be regarded as an independent event. The landmark location coordinates may be obtained from a third party service provider such as Google, and the message data may include, but is not limited to, at least one message recipient, a landmark location coordinate, a push distance, a push start and a deadline date and time. And a message content, which may include, but is not limited to, text, cards, images, sounds, and images. Next, a data encryption unit 201 is responsible for performing compression and encryption on the message data, and transmitting the encrypted message data to a backup database 202 for storage. With the connection of a cellular or WiFi wireless network (such as 105 or 109 in FIG. 1), the first device 111 transmits the encrypted message data to the message push server 114 via the API, due to the transmission characteristics of the wireless network, if If the encrypted message data transmission fails, a data resending unit 203 will be activated and retrieved from the backup database 202 to perform the resend operation.
该讯息推播服务器 114配备一数据解密单元 204、 一数据队列单元 205、 一 特征群集单元 206和一事件产生单元 207。当该讯息推播服务器 114接收到该加 密讯息数据之后, 回复已接收的确认讯号至该第一装置 111, 同时该解密单元 204负责对该讯息数据执行解压缩和解密。通常, 该讯息推播服务器 114可能同 时处理多个推播事件, 该数据队列单元 205 用于可依据该解密讯息数据中的该 推播起始的日期与时间赋予一事件优先权值, 基于优先权值由高至低排列该多 个解密讯息数据。 根据该解密讯息数据, 该特征群集单元 206 能从该信号特征 数据库 117获取多个地理信号特征群集。 该信号特征数据库 117包括一蜂巢次 数据库 208和一混合次数据库 209,该蜂巢次数据库 208储存多个细胞基地台数 据, 每一细胞基地台数据记录一唯一 CGI码参数和位置信息, 该混合次数据库 209储存多个 WiFi AP数据, 每一 WiFi AP数据记录至少一 CGI码参数、 一唯 一 MAC地址参数和位置信息,该 CGI码参数包括一行动国家码 (Mobile Country Code, MCC)、 一行动网络码 (Mobile Network Code, MNC)、 一位置区域码 (Location Area Code, LAC) , 以及一细胞识别码 (Cell Identity, CID)。  The message push server 114 is provided with a data decryption unit 204, a data queue unit 205, a feature cluster unit 206, and an event generation unit 207. After the message push server 114 receives the encrypted message data, it replies to the received confirmation signal to the first device 111, and the decryption unit 204 is responsible for performing decompression and decryption on the message data. Generally, the message pushing server 114 may process multiple push events simultaneously, and the data queue unit 205 is configured to assign an event priority value according to the date and time of the push start in the decrypted message data, based on the priority. The weights are arranged from high to low to the plurality of decrypted message data. Based on the decrypted message data, the feature clustering unit 206 can acquire a plurality of clusters of geographic signal features from the signal feature database 117. The signal feature database 117 includes a cellular sub-database 208 and a hybrid secondary database 209. The cellular secondary database 208 stores a plurality of cellular base station data, and each cell base station data records a unique CGI code parameter and location information. The database 209 stores a plurality of WiFi AP data, and each WiFi AP data records at least one CGI code parameter, a unique MAC address parameter, and location information, where the CGI code parameter includes a Mobile Country Code (MCC), a mobile network. Mobile Network Code (MNC), a Location Area Code (LAC), and a Cell Identity (CID).
如图 3所示, 为自蜂巢次数据库中获取地理信号特征群集的流程示意图。 该特征群集单元 206可依据该解密讯息数据中的地标位置坐标,决定一 MCC (步 骤 301), 使用该 MCC为一键值 (key), 执行该蜂巢次数据库 208的搜寻, 以获取 相应的数据库的多个细胞基地台数据 (步骤 302)。  As shown in FIG. 3, a schematic diagram of a process for acquiring a cluster of geographic signal features from a cellular secondary database. The feature clustering unit 206 may determine an MCC according to the landmark location coordinates in the decrypted message data (step 301), and use the MCC as a key to perform the search of the cellular sub-database 208 to obtain a corresponding database. Multiple cell base station data (step 302).
接续执行步骤 303, 基于该获取到的多个细胞基地台数据统计该 MCC 的 MNC数目, 且依据该 MNC数目决定群集数目。 Step 303 is performed to calculate the MCC based on the acquired plurality of cell base station data. The number of MNCs, and the number of clusters is determined according to the number of MNCs.
接续执行步骤 304, 依据该 MNC将同一 MCC的该多个细胞基地台数据划 分多个群集 (cl ter)。 该群集划分的方式为: 针对该多个细胞基地台数据, 将具 有同一 MNC的细胞基地台数据划分为同一群集。在此实施例中, 每一群集的该 多个细胞基地台数据可以定义为一 n 点数据群, 用集合 Ck 来表示为 Ck={cl,-,cn} , 其中 k为群集数目。  Following the step 304, the plurality of cell base station data of the same MCC is divided into a plurality of clusters according to the MNC. The cluster is divided into: The cell base station data with the same MNC is divided into the same cluster for the plurality of cell base station data. In this embodiment, the plurality of cell base station data for each cluster may be defined as an n-point data group, represented by a set Ck as Ck = {cl, -, cn}, where k is the number of clusters.
接续执行步骤 305, 自该多个群集中的每一群集获取多个推播代表点。其实 施方式为: 一群集 Ck, 包含 n点数据, 每一数据点有一位置坐标和一唯一 CGI 码, 计算每一资料点和该解密讯息数据中的地标位置坐标的距离值, 如果该距 离值小于该推播距离, 则该数据点成为推播代表点, 且储存该数据点的 CGI码。  Following step 305, multiple push representative points are obtained from each of the plurality of clusters. The implementation manner is as follows: a cluster Ck, including n point data, each data point has a position coordinate and a unique CGI code, and calculates a distance value of each data point and a coordinate position coordinate in the decrypted message data, if the distance value If the distance is less than the push distance, the data point becomes a push representative point, and the CGI code of the data point is stored.
接续执行步骤 306, 定义每一群集的该多个推播代表点为一 i点数据群, 用 集合 Pk来表示为 Pk ={ρ1,···,ρί}, 其中 i小于 η且 k为群集数目。 该集合 Pk 为本发明一实施例的讯息推播的地理信号特征群集, 而该地理信号特征为 CGI 码。  Next, in step 306, the plurality of push representative points of each cluster are defined as an i-point data group, and the set Pk is represented as Pk={ρ1,···, ρί}, where i is smaller than η and k is a cluster. number. The set Pk is a cluster of geographic signal features of a message push according to an embodiment of the present invention, and the geographic signal feature is a CGI code.
如图 4所示, 为自混合次数据库中获取地理信号特征群集的流程示意图。 该特征群集单元 206可依据该解密讯息数据中的地标位置坐标,决定一 MCC (步 骤 401), 使用该 MCC为一键值 (key), 执行该混合次数据库 209的搜寻, 以获取 相应的数据库的多个 WiFi AP数据 (步骤 402)。  As shown in FIG. 4, a schematic diagram of a process for acquiring a cluster of geographic signal features in a self-mixing secondary database. The feature clustering unit 206 can determine an MCC according to the landmark location coordinates in the decrypted message data (step 401), and use the MCC as a key to perform the search of the hybrid secondary database 209 to obtain a corresponding database. Multiple WiFi AP data (step 402).
接续执行步骤 403, 定义该多个 WiFi AP数据为一 m点群集, 用集合 W来 表不为 W={wl,'",wm}。  In the following step 403, the plurality of WiFi AP data is defined as a m-point cluster, and the set W is used to represent W={wl, '", wm}.
于步骤 404, 自该群集获取多个推播代表点。 其实施方式为: 该群集的每一 数据点有一位置坐标和一唯一 MAC地址,计算每一数据点和该解密讯息数据中 的地标位置坐标的距离值, 如果该距离值小于该推播距离, 则该数据点成为推 播代表点, 且储存该数据点的 MAC地址。  At step 404, a plurality of push representative points are obtained from the cluster. The implementation manner is as follows: each data point of the cluster has a position coordinate and a unique MAC address, and calculates a distance value of each data point and a coordinate position coordinate in the decrypted message data. If the distance value is smaller than the push distance, Then the data point becomes a push representative point and stores the MAC address of the data point.
接续执行步骤 405, 定义该多个推播代表点为一 j点数据群, 用集合 Q来表 示为 Q={ql, ,qj }, 其中 j小于 m。该集合 Q为本发明一实施例的讯息推播的地 理信号特征群集, 而该地理信号特征为 MAC地址。  Next, in step 405, the plurality of push representative points are defined as a j-point data group, and the set Q is represented as Q={ql, , qj }, where j is less than m. The set Q is a cluster of geographic signal features of a message push according to an embodiment of the present invention, and the geographic signal feature is a MAC address.
值得注意的是, 在本发明的一实施例中, 该特征群集单元 206可从单一地 标 (unicase landmark)获取到 k+1地理信号特征群集,在不悖离本发明精神的前提 下, 于不同实施例中, 根据该第一装置 111 提供地标数据内容的属性, 可允许 多个地标同时存在, 即一群地标 (multicase landmarks), 此时, 该特征群集单元 206可从该群地标获取到 LX (k+l)地理信号特征群集, 其中 L为地标数目。 It should be noted that, in an embodiment of the present invention, the feature clustering unit 206 can acquire a cluster of k+1 geographic signal features from a unicase landmark, without departing from the spirit of the present invention. In an embodiment, the attribute of the landmark data content is provided according to the first device 111, allowing A plurality of landmarks exist simultaneously, that is, a plurality of landmarks. At this time, the feature clustering unit 206 can acquire a cluster of LX (k+1) geographic signal features from the group of landmarks, where L is the number of landmarks.
该特征群集单元 206将获取到的该多个地理信号特征群集传递到该事件产 生单元 207, 该事件产生单元 207指派一讯息推播 ID, 且建立一讯息推播表, 其中, 该讯息推播表记录该讯息推播 ID、 该解密讯息数据中的讯息接收者、 推 播起始和截止的日期与时间、 讯息内容, 以及接收到的该多个地理信号特征群 集 (即集合 Pk和 Q)。  The feature clustering unit 206 passes the acquired cluster of the plurality of geographic signal features to the event generating unit 207, the event generating unit 207 assigns a message pushing ID, and establishes a message pushing table, wherein the message is pushed. The table records the message push ID, the message recipient in the decrypted message data, the date and time of the push start and end, the message content, and the received cluster of multiple geographic signal features (ie, sets Pk and Q). .
如图 5至图 7所示,主要依据本发明的一实施例描述执行讯息推播的方法。 如图 5所示, 为一执行机制的架构示意图。 该讯息推播服务器 114又配备一事 件通知单元 501、一事件数据库 502、一事件服务单元 503和一事件重送单元 504。 该事件产生单元 207建立一讯息推播表之后, 传递到该事件通知单元 501。根据 该讯息推播表的记录, 该事件通知单元 501 负责主动建立通知联机, 通知该第 二装置 112 (即讯息接收者)提取推播条件, 同时将该讯息推播表中的该讯息推播 ID和该讯息内容传递到该事件数据库 502储存。 当该第二装置 112接收到该通 知之后, 检测一信号特征, 并建立联机到该事件通知单元 501取得该推播条件, 该检测到的信号特征包括 CGI码参数或 MAC地址参数。 需注意的是, 于本发 明的一实施例中, 该事件通知单元 501可依据该第二装置 112检测到的信号特 征提供不同的推播条件。 基于获取到的该推播条件, 该第二装置 112进行装置 端的事件检查, 如果该推播条件为一存在状态, 则该第二装置 112建立联机, 由该事件服务单元 503执行讯息内容推播。  As shown in FIG. 5 to FIG. 7, a method of performing message push is mainly described according to an embodiment of the present invention. As shown in Figure 5, it is an architectural diagram of an execution mechanism. The message push server 114 is further provided with an event notification unit 501, an event database 502, an event service unit 503, and an event resending unit 504. The event generating unit 207, after establishing a message push table, passes to the event notifying unit 501. According to the record of the message push table, the event notification unit 501 is responsible for actively establishing the notification connection, notifying the second device 112 (ie, the message receiver) to extract the push condition, and simultaneously pushing the message in the message push table. The ID and the message content are passed to the event database 502 for storage. After the second device 112 receives the notification, a signal characteristic is detected, and the event notification unit 501 is established to obtain the push condition, and the detected signal feature includes a CGI code parameter or a MAC address parameter. It should be noted that, in an embodiment of the invention, the event notification unit 501 can provide different push conditions according to the signal characteristics detected by the second device 112. Based on the obtained push condition, the second device 112 performs an event check on the device side. If the push condition is a presence status, the second device 112 establishes a connection, and the event service unit 503 performs a message content push. .
如图 6所示, 为依据检测到的 CGI码参数, 进行讯息主动推播的流程示意 图。 该讯息主动推播的程序可分为讯息通知与讯息推播。 于讯息通知程序, 包 括下列步骤: 当该第二装置 112接收到该通知之后, 如果检测一服务细胞基地 台 (如图 1中的 106)的 CGI码参数为一存在状态 (步骤 601),则将该检测到的 CGI 码中的该 MCC、 该 MNC, 以及该 LAC借助 API传送到该事件通知单元 501(步 骤 602) , 如果检测一服务细胞基地台的 CGI码参数为一未存在状态, 则表示该 第二装置 112使用 MAC地址参数进行讯息主动推播 (步骤 603)。  As shown in FIG. 6, the flow diagram of the active push of the message is based on the detected CGI code parameters. The program that the message is actively pushed can be divided into message notification and message promotion. In the message notification procedure, the following steps are included: after the second device 112 receives the notification, if the CGI code parameter of a serving cell base station (such as 106 in FIG. 1) is detected as a presence status (step 601), then Transmitting the MCC, the MNC, and the LAC in the detected CGI code to the event notification unit 501 by using an API (step 602), if detecting that the CGI code parameter of a serving cell base station is an non-existent state, Indicates that the second device 112 actively pushes the message using the MAC address parameter (step 603).
接续执行步骤 604, 根据接收到的该 MCC、 该 MNC, 以及该 LAC, 可从 该讯息推播表中的该多个地理信号特征群集 (即集合 Pk), 选择一群集。 其实施 方式为: 该事件通知单元 501将该接收到的 MCC、 MNC以及 LAC与该多个地 理信号特征群集中的每一群集的 MCC、MNC以及 LAC进行比对,如果该 MCC、 该 MNC, 以及该 LAC为一存在状态, 则选择比对相同的该群集, 如果该 MCC、 该 MNC, 以及该 LAC为一未存在状态,则根据该 MCC和该 MNC再进行比对, 并选择比对相同的该群集。 Then, in step 604, according to the received MCC, the MNC, and the LAC, a cluster of the plurality of geographic signal features (ie, the set Pk) in the table may be pushed from the message to select a cluster. The implementation manner is as follows: the event notification unit 501 associates the received MCC, the MNC, and the LAC with the multiple locations. The MCC, the MNC, and the LAC of each cluster in the cluster of the signal characteristics are compared. If the MCC, the MNC, and the LAC are in a presence state, the same cluster is selected, if the MCC, the MNC, And if the LAC is in an unexistent state, the MCC and the MNC are further compared according to the MCC, and the same cluster is selected.
接续执行步骤 605, 基于该选择到的地理信号特征群集建立一推播条件, 并 传送到该第二装置 112。该推播条件包括选择到的该地理信号特征群集中的至少 一 LAC和至少一 CID、 该讯息推播表中的该讯息推播 ID和该推播起始和截止 的曰期与时间。  Following the step 605, a push condition is established based on the selected cluster of geographic signal features and transmitted to the second device 112. The push condition includes at least one LAC and at least one CID in the selected cluster of geographic signal features, the message push ID in the message push list, and the time and time of the push start and end.
于讯息推播程序, 包括下列步骤:  In the message delivery program, the following steps are included:
接续执行步骤 606, 使用检测到的该服务细胞基地台的 CGI码和信号强度 值, 于该推播起始和截止的日期与时间之内, 进行事件检查。 其实施方式为: 如果该第二装置 112检测到的该 CGI码中的 LAC和 CID与该推播条件中的该地 理信号特征群集中的 LAC和 CID相同 (步骤 607),则传送该讯息推播 ID以及该 服务细胞基地台的 CGI码和信号强度值到该事件服务单元 503(步骤 608),反之, 则继续执行步骤 606。  Next, in step 606, an event check is performed within the date and time of the start and end of the push using the detected CGI code and signal strength value of the serving cell base station. The implementation manner is: if the LAC and the CID in the CGI code detected by the second device 112 are the same as the LAC and CID in the cluster of the geographic signal feature in the push condition (step 607), the message is transmitted. The broadcast ID and the CGI code and signal strength values of the serving cell base station are sent to the event service unit 503 (step 608), otherwise, step 606 is continued.
接续执行步骤 609,该事件服务单元 503传送接收到的该服务细胞基地台的 CGI码和信号强度值到该定位运算服务器 116, 计算该第二装置 112位置, 如果 计算到的位置位于该推播圆内 (步骤 610), 则进至步骤 611, 反之, 则结束主动 推播讯息 (步骤 612)。 于本发明的一实施例中, 该推播圆指以地标位置坐标为圆 心, 推播距离为半径, 所定义的一圆。  Next, in step 609, the event service unit 503 transmits the received CGI code and signal strength value of the serving cell base station to the positioning operation server 116, and calculates the location of the second device 112, if the calculated location is located in the push broadcast. Within the circle (step 610), the process proceeds to step 611, otherwise, the active push message is terminated (step 612). In an embodiment of the invention, the push circle refers to a circle defined by the coordinates of the landmark position, and the push distance is a radius.
于步骤 611, 该事件服务单元 503根据接收到的该讯息推播 ID可从该事件 数据库 502获取该讯息内容, 并执行主动推播讯息内容至该第二装置 112。  In step 611, the event service unit 503 can obtain the content of the message from the event database 502 according to the received push ID, and perform active push of the message content to the second device 112.
如图 7所示,为依据检测到的 MAC地址参数进行讯息主动推播的流程示意 图。 该讯息主动推播的程序可分为讯息通知与讯息推播。 于讯息通知程序, 包 括下列步骤:该第二装置 112检测一服务 AP (如图 1中的 110)的 MAC地址参数 (步骤 701), 并将该 MAC地址使用 API传送到该事件通知单元 501(步骤 702)。  As shown in Figure 7, a schematic diagram of the process of actively propagating messages based on the detected MAC address parameters. The program that the message is actively pushed can be divided into message notification and message promotion. The message notifying program includes the following steps: the second device 112 detects a MAC address parameter of a serving AP (such as 110 in FIG. 1) (step 701), and transmits the MAC address using the API to the event notifying unit 501 ( Step 702).
接续执行步骤 703, 根据接收到的该 MAC地址, 该事件通知单元 501可从 该讯息推播表中的该多个地理信号特征群集, 直接选择一群集 (即集合 Q)。  Step 703, according to the received MAC address, the event notification unit 501 can directly select a cluster (ie, set Q) from the plurality of geographic signal feature clusters in the message push table.
接续执行步骤 704, 依据该选择到的地理信号特征群集建立一推播条件, 并 传送到该第二装置 112。 该推播条件包括选择到的该地理信号特征群集中的 MAC地址参数、 该讯息推播表中的该讯息推播 ID和该推播起始和截止的日期 与时间。 Step 704 is performed to establish a push condition according to the selected geographic signal feature cluster and transmit to the second device 112. The push condition includes the selected cluster of geographic signal features The MAC address parameter, the message push ID in the message push list, and the date and time of the push start and end.
于讯息推播程序, 包括下列步骤:  In the message delivery program, the following steps are included:
于步骤 705, 使用该检测到的服务 AP的 MAC地址和信号强度值, 于该推 播起始和截止的日期与时间之内, 进行事件检查。 其实施方式为: 如果该第二 装置 112检测到的该 MAC 地址与该推播条件中的该地理信号特征群集中的 MAC地址相同 (步骤 706), 则传送该讯息推播 ID以及该服务 AP的 MAC地址 和信号强度值到该事件服务单元 503 (步骤 707), 反之, 则继续执行步骤 705。  In step 705, an event check is performed using the detected MAC address and signal strength value of the serving AP within the date and time of the start and end of the push. The implementation manner is: if the MAC address detected by the second device 112 is the same as the MAC address in the cluster of the geographic signal features in the push condition (step 706), transmitting the message push ID and the service AP The MAC address and signal strength values are passed to the event service unit 503 (step 707), otherwise, step 705 is continued.
接续执行步骤 708, 该事件服务单元 503传送接收到的该服务 AP的 MAC 地址和信号强度值到该定位运算服务器 116, 计算该第二装置 112位置, 如果计 算到的位置位于该推播圆内 (步骤 709), 则进至步骤 710, 反之, 则结束主动推 播讯息 (步骤 711)。  Step 708 is performed, the event service unit 503 transmits the received MAC address and signal strength value of the service AP to the positioning operation server 116, and calculates the location of the second device 112, if the calculated location is located in the push circle. (Step 709), then go to step 710, otherwise, the active push message is ended (step 711).
于步骤 710, 根据接收到的该讯息推播 ID, 该事件服务单元 503可从该事 件数据库 502获取该讯息内容, 并执行主动推播讯息内容至该第二装置 112。  In step 710, based on the received push advertisement ID, the event service unit 503 can obtain the message content from the event database 502 and perform active push message content to the second device 112.
值得注意的是, 于本发明的一实施例, 该第二装置 112如智能型手机或平 板计算机接收到该推播条件通知之后,可能同时检测到一服务细胞基地台的 CGI 码参数和一服务 AP 的 MAC地址参数, 此时, 执行讯息主动推播的方法, 其步 骤如前所述 (步骤 602至 612)。  It should be noted that, in an embodiment of the present invention, after receiving the notification of the push condition, the second device 112, such as a smart phone or a tablet computer, may simultaneously detect a CGI code parameter and a service of a serving cell base station. The MAC address parameter of the AP. At this time, the method of actively propagating the message is performed, and the steps are as described above (steps 602 to 612).
当该事件服务单元 503执行推播讯息内容至第二装置 112时, 由于无线网 络的传输特性, 该推播事件可能失败, 此时, 该事件服务单元 503 将接收到的 该讯息推播 ID传递到该事件重送单元 504。于接收到该讯息推播 ID之后,该事 件重送单元 504可从该事件数据库 503获取该讯息内容, 并负责进行讯息内容 重新推播的动作。  When the event service unit 503 performs the push message content to the second device 112, the push event may fail due to the transmission characteristics of the wireless network. At this time, the event service unit 503 transmits the received message push ID. Go to the event resending unit 504. After receiving the message push ID, the event resending unit 504 can obtain the message content from the event database 503 and is responsible for performing the re-pushing of the message content.
上述本发明的方法, 或特定系统单元、 或其部份单元, 为纯软件架构, 可 以通过程序代码布设于实体媒体, 如硬盘、 光盘片、 或是任何电子装置 (如智能 型手机、 计算机可读取的储存媒体), 当机器加载程序代码且执行 (如智能型手 机加载且执行), 机器成为用以实行本发明的装置。 上述本发明的方法与装置亦 可以程序代码型态通过一些传送媒体, 如电缆、 光纤、 或是任何传输型态进行 传送, 当程序代码被机器 (如智能型手机) 接收、 加载且执行, 机器成为用以 实行本发明的装置。 以上所述实施例仅是为充分说明本发明而所举的较佳的实施例, 本发明的 保护范围不限于此。 本技术领域的技术人员在本发明基础上所作的等同替代或 变换, 均在本发明的保护范围之内。 本发明的保护范围以权利要求书为准。 The method of the present invention, or a specific system unit, or a part thereof, is a pure software architecture, and can be disposed in a physical medium by using a program code, such as a hard disk, a CD, or any electronic device (such as a smart phone or a computer). The read storage medium), when the machine loads the program code and executes (eg, the smart phone is loaded and executed), the machine becomes the device for practicing the present invention. The above method and apparatus of the present invention can also be transmitted by a transmission medium such as a cable, an optical fiber, or any transmission type, when the program code is received, loaded, and executed by a machine (such as a smart phone). It becomes a device for carrying out the invention. The above-described embodiments are merely preferred embodiments for the purpose of fully illustrating the present invention, and the scope of the present invention is not limited thereto. Equivalent substitutions or modifications made by those skilled in the art based on the present invention are within the scope of the present invention. The scope of the invention is defined by the claims.

Claims

权利要求书 claims
1、 一种使用地理信号特征群集实现端到端讯息推播的方法, 适用于蜂巢式 和 WiFi无线网络, 其特征在于, 包括下列步骤: 一第一装置视为一讯息提供者, 借助装置端设定一地标, 并建立相关于该 地标的讯息数据; 依据该讯息数据一讯息推播服务器能从一信号特征数据库获取多个地理信 号特征群集, 基于该获取到的多个地理信号特征群集和该讯息数据建立一讯息 推播表; 依据该讯息推播表, 该讯息推播服务器主动建立联机通知一第二装置提取 推播条件, 该第二装置视为一讯息接收者; 当接收到该通知之后, 该第二装置检测服务细胞基地台或服务 AP 的信号 特征并提供给该讯息推播服务器自讯息推播表中的多个地理信号特征群集中, 选择一地理信号特征群集以建立推播条件, 且传送给该第二装置; 当接收到该推播条件之后, 该第二装置检测服务细胞基地台或服务 AP 的 信号特征; 若检测到的该信号特征与该推播条件中的地理信号特征群集中的一信号特 征相同, 则该第二装置提供该检测到的信号特征给一定位运算服务器以计算该 第二装置的位置; 若该计算到的位置位于该地标位置坐标的一范围内, 则该讯息推播服务器 主动推播讯息至该第二装置。 1. A method for implementing end-to-end message push using geographic signal feature clustering, suitable for cellular and WiFi wireless networks, which is characterized by including the following steps: A first device is regarded as a message provider, with the help of the device end Set a landmark and create information data related to the landmark; based on the information data, a message push server can obtain multiple geographical signal feature clusters from a signal feature database, and based on the obtained multiple geographical signal feature clusters and The message data creates a message push table; based on the message push table, the message push server actively establishes a connection to notify a second device to extract push conditions, and the second device is regarded as a message recipient; when receiving the message After the notification, the second device detects the signal characteristics of the serving cell base station or the serving AP and provides the message push server to select a geographical signal feature cluster from a plurality of geographical signal feature clusters in the message push table to establish a push. broadcast condition and transmit it to the second device; after receiving the push condition, the second device detects the signal characteristics of the serving cell base station or serving AP; if the detected signal characteristics are consistent with the push condition If a signal characteristic in the geographical signal characteristic cluster is the same, the second device provides the detected signal characteristic to a positioning calculation server to calculate the position of the second device; if the calculated position is located at one of the landmark position coordinates within the range, the message push server actively pushes the message to the second device.
2、 根据权利要求 1所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 该第一装置为智能型手机、 个人数字助理、 平板计算机或笔 记型计算机。 2. The method according to claim 1, wherein the first device is a smart phone, a personal digital assistant, a tablet computer or a notebook computer.
3、 根据权利要求 1所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 该讯息数据包括至少一讯息接收者、 一地标位置坐标、 一推 播距离、 一推播起始和截止的日期与时间、 以及一讯息内容。 3. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that the message data includes at least one message receiver, a landmark location coordinate, a push distance, a push The broadcast start and end date and time, as well as a message content.
4、 根据权利要求 3所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 该讯息内容还包括文字、 卡片、 图像、 声音和影像。 4. The method of using geographic signal feature clusters to implement end-to-end message push according to claim 3 The method is characterized in that the message content also includes text, cards, images, sounds and images.
5、 根据权利要求 1所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 该信号特征数据库包括一蜂巢次数据库和一混合次数据库, 其中该蜂巢次数据库储存多个细胞基地台数据, 每一细胞基地台数据记录一唯 一 CGI码参数和位置信息, 其中该混合次数据库储存多个 WiFi AP数据, 每一 WiFi AP数据记录至少一 CGI码参数、 一唯一 MAC地址以及位置信息。 5. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, wherein the signal feature database includes a cellular secondary database and a hybrid secondary database, wherein the cellular secondary database stores multiple Cell base station data, each cell base station data records a unique CGI code parameter and location information, wherein the hybrid secondary database stores multiple WiFi AP data, and each WiFi AP data records at least one CGI code parameter and a unique MAC address and location information.
6、 根据权利要求 1所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 该讯息推播服务器自蜂巢次数据库中获取地理信号特征群集, 包括下列步骤: 依据该讯息数据中的地标位置坐标决定一行动国家码; 使用该行动国家码为一键值, 执行该蜂巢次数据库的搜寻, 以获取相应的 数据库的多个细胞基地台数据; 基于该获取到的多个细胞基地台数据统计该行动国家码的行动网络码数 目, 并依据该行动网络码数目决定群集数目; 依据该行动网络码将同一行动国家码的该多个细胞基地台数据划分多个群 6. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that the message push server obtains the geographical signal feature cluster from the cellular secondary database, including the following steps: According to the The landmark position coordinates in the message data determine a mobile country code; use the mobile country code as a key value to perform a search of the cellular sub-database to obtain multiple cell base station data of the corresponding database; based on the obtained multiple cell base station data The cell base station data counts the number of mobile network codes of the mobile country code, and determines the number of clusters based on the number of mobile network codes; divides the multiple cell base station data of the same mobile country code into multiple groups based on the mobile network code
自该多个群集中的每一群集获取多个推播代表点; 以及 定义每一群集的该多个推播代表点为一地理信号特征群集, 其中该地理信 号特征为 CGI码。 Obtaining a plurality of push representative points from each of the plurality of clusters; and defining the plurality of push representative points of each cluster as a geographical signal feature cluster, wherein the geographical signal feature is a CGI code.
7、 根据权利要求 6所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 还包括依据该讯息数据中的地标位置坐标对该多个群集中的 每一群集的每一数据点计算一距离值, 若该距离值小于该推播距离, 则该数据 点成为推播代表点, 并储存该数据点的 CGI码。 7. The method of using geographic signal feature clusters to implement end-to-end message push according to claim 6, further comprising: determining each cluster in the plurality of clusters based on the landmark location coordinates in the message data. A distance value is calculated for each data point. If the distance value is smaller than the push distance, the data point becomes a push representative point and the CGI code of the data point is stored.
8、 根据权利要求 1所述的使用地理信号特征群集实现端到端讯息推播的方 法, 其特征在于, 该讯息推播服务器自混合次数据库中获取地理信号特征群集, 包括下列步骤: 依据该讯息数据中的地标位置坐标, 决定一行动国家码; 使用该行动国家码为一键值, 执行该混合次数据库的搜寻, 以获取相应的 数据库的多个 WiFi AP数据; 定义该多个 WiFi AP数据为一群集; 自该群集获取多个推播代表点; 以及 定义该多个推播代表点为一地理信号特征群集, 其中该地理信号特征为 MAC地址。 8. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that the message push server obtains the geographical signal feature cluster from the hybrid secondary database, including the following steps: According to the The landmark location coordinates in the message data determine a mobile country code; Use the mobile country code as a key value to perform a search in the hybrid database to obtain multiple WiFi AP data of the corresponding database; define the multiple WiFi AP data as a cluster; obtain multiple push representatives from the cluster points; and defining the plurality of push representative points as a geographical signal feature cluster, where the geographical signal feature is a MAC address.
9、 根据权利要求 8项所述的使用地理信号特征群集实现端到端讯息推播的 方法, 其特征在于, 还包括依据该讯息数据中的地标位置坐标对该群集中的每 一数据点计算一距离值, 若该距离值小于该推播距离, 则该数据点成为推播代 表点, 并储存该数据点的 MAC地址。 9. The method of using geographic signal feature clusters to implement end-to-end message push according to claim 8, further comprising calculating each data point in the cluster based on the landmark position coordinates in the message data. A distance value. If the distance value is smaller than the push distance, the data point becomes the push representative point and the MAC address of the data point is stored.
10、 根据权利要求 1 项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 该讯息推播表记录该讯息推播 ID、 该讯息数据中的讯息 接收者、 推播起始和截止的日期与时间、 讯息内容、 以及接收到的该多个地理 信号特征群集。 10. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that the message push table records the message push ID, the message recipient in the message data, The start and end date and time of push broadcast, the content of the message, and the feature clusters of the multiple geographical signals received.
11、 根据权利要求 1 项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 该第二装置为智能型手机、 个人数字助理、 平板计算机 或笔记型计算机。 11. The method according to claim 1, wherein the second device is a smart phone, a personal digital assistant, a tablet computer or a notebook computer.
12、 根据权利要求 11项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 该第二装置检测到的信号特征包括一服务细胞基地台的 CGI码参数和信号强度以及一服务 AP的 MAC地址参数和信号强度。 12. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 11, wherein the signal features detected by the second device include CGI code parameters and signals of a serving cell base station Strength as well as the MAC address parameters and signal strength of a serving AP.
13、 根据权利要求 1 项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 基于该第二装置检测到的 CGI码参数建立推播条件, 包 括下列步骤: 将检测到的 CGI码中的该 MCC、 该 MNC以及该 LAC传送到该讯息推播 服务器; 依据接收到的该 MCC、 该 MNC以及该 LAC, 该讯息推播服务器自该多个 地理信号特征群集, 选择一群集; 以及 依据该选择到的地理信号特征群集, 该讯息推播服务器建立一推播条件, 并传送到该第二装置。 13. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that establishing push conditions based on the CGI code parameters detected by the second device includes the following steps: The MCC, the MNC and the LAC in the detected CGI code are sent to the message push server; based on the received MCC, the MNC and the LAC, the message push server selects from the multiple geographic signal feature clusters, select a cluster; and According to the selected geographic signal feature cluster, the message push server establishes a push condition and sends it to the second device.
14、 根据权利要求 13项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 该推播条件包括选择到的该地理信号特征群集中的至少 一 LAC和至少一 CID、 该讯息推播表中的该讯息推播 ID和该推播起始和截止 的曰期与时间。 14. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 13, characterized in that the push conditions include at least one LAC and at least one selected in the geographical signal feature cluster. CID, the message push ID in the message push table, and the start and end date and time of the push.
15、 根据权利要求 1 项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 基于该第二装置检测到的 MAC地址参数建立推播条件, 包括下列步骤: 15. The method of using geographic signal feature clusters to implement end-to-end message push according to claim 1, characterized in that establishing push conditions based on the MAC address parameters detected by the second device includes the following steps:
将该 MAC地址传送到该讯息推播服务器; 依据接收到的该 MAC 地址, 该讯息推播服务器自该多个地理信号特征群 集, 直接选择一群集; 以及 依据该选择到的地理信号特征群集, 该讯息推播服务器建立一推播条件, 并传送到该第二装置。 Transmitting the MAC address to the message push server; based on the received MAC address, the message push server directly selects a cluster from the plurality of geographical signal feature clusters; and based on the selected geographical signal feature cluster, The message push server establishes a push condition and sends it to the second device.
16、 根据权利要求 15项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 该推播条件包括选择到的该地理信号特征群集中的 MAC 地址参数、该讯息推播表中的该讯息推播 ID和该推播起始和截止的日期与时间。 16. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 15, characterized in that the push conditions include the MAC address parameters in the selected geographical signal feature cluster, the message The push ID of the message in the push table and the start and end dates and times of the push.
17、 根据权利要求 1 项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 使用该第二装置检测到的 CGI码参数和信号强度, 执行 主动推播, 包括下列步骤: 当接收到该推播条件之后, 于该推播起始和截止的日期与时间之内, 进行 事件检查; 17. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that using the CGI code parameters and signal strength detected by the second device to perform active push, including The following steps: After receiving the push condition, perform event checking within the start and end dates and times of the push;
若检测到的该 CGI码中的 LAC和 CID与该推播条件中的该地理信号特征 群集中的 LAC和 CID相同, 则传送该讯息推播 ID以及该 CGI码和信号强度值 到该讯息推播服务器, 反之, 则继续执行该步骤; If the detected LAC and CID in the CGI code are the same as the LAC and CID in the geographical signal feature cluster in the push condition, then send the message push ID, the CGI code and the signal strength value to the message push broadcast server, otherwise, continue to perform this step;
将接收到的该 CGI码和信号强度值传送到该定位运算服务器, 计算该第二 装置位置; 若计算到的位置位于该推播圆内, 则该讯息推播服务器可执行主动推播讯 息内容至该第二装置, 反之, 则结束主动推播讯息。 Send the received CGI code and signal strength value to the positioning calculation server to calculate the position of the second device; If the calculated position is within the push circle, the message push server can actively push the message content to the second device; otherwise, the message push server will terminate the active push of the message.
18、 根据权利要求 1 项所述的使用地理信号特征群集实现端到端讯息推播 的方法, 其特征在于, 使用该第二装置检测到的 MAC地址参数和信号强度, 执 行主动推播, 包括下列步骤: 当接收到该推播条件之后, 于该推播起始和截止的日期与时间之内, 进行 事件检查; 18. The method of using geographical signal feature clusters to implement end-to-end message push according to claim 1, characterized in that using the MAC address parameters and signal strength detected by the second device to perform active push, including The following steps: After receiving the push condition, perform event checking within the start and end dates and times of the push;
若检测到的该 MAC地址与该推播条件中的该地理信号特征群集中的 MAC 地址相同, 则传送该讯息推播 ID以及该 MAC地址和信号强度值到该讯息推播 服务器, 反之, 则继续执行该步骤; If the detected MAC address is the same as the MAC address in the geographical signal feature cluster in the push condition, then the message push ID, the MAC address and the signal strength value are sent to the message push server, otherwise, then Continue with this step;
将接收到的该 MAC地址和信号强度值传送到该定位运算服务器,计算该第 二装置位置; 若计算到的位置位于该推播圆内, 则该讯息推播服务器可执行主动推播讯 息内容至该第二装置, 反之, 则结束主动推播讯息。 Send the received MAC address and signal strength value to the positioning calculation server to calculate the location of the second device; if the calculated location is within the push circle, the message push server can actively push the message content to the second device, otherwise, the active push message ends.
PCT/CN2012/083808 2011-06-21 2012-10-31 Method for achieving end-to-end message push using geographical signal feature cluster WO2013177897A1 (en)

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