• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:

    公开号:SE536544C2
    申请号:SE1350227
    申请日:2013-02-28
    公开日:2014-02-11
    发明作者:Thomas Malm;Adrian Jakobsson
    申请人:
    IPC主号:
    专利说明:

    OBJECT OF THE INVENTION An object of the present invention is therefore to provide a method and system for locating objects in wireless spontaneous networks which makes it possible to simplify and cheapen the technology. Above all, a system is sought that makes it possible to efficiently search for objects in formed wireless spontaneous networks with the help of cheap card-holding technology, in particular Bluetooth, Low Energy Bluetooth and Wi-Fi, and subscriptions from a third-party operator. In this way, not only could the investment costs be kept down, but also a system that is both energy-efficient and has a long operating time.
    SUMMARY OF THE INVENTION These two objects of the invention are solved by a method and a system which exhibit the features and characteristics set forth in claim 1 and claim 9, respectively.
    According to one aspect of the present invention, there is provided a method of locating objects in wireless spontaneous networks wherein said object carries a target unit PSTR. The spontaneous network is formed using at least one search unit LAASR for contact PSTR through wireless short-range communication and subsequent mobile radio communication to a server unit SAS both with the target unit designed to administer search assignments to and from the spontaneous network via short-range communication or other mobile communication. Each target unit PSTR is assigned so that it is and remains in "detectable mode" according to the current radio communication protocol such as Bluetooth, Wi-Fi or other predefined radio protocol which offers this function.
    Within the framework of this function, a unique registrable identity is made available, such as a MAC address, a Radio Node ID address, RNID address or the like. Upon contact with one of the search units, this identification is registered spontaneously and one-way without explicit request from the search unit. In the search unit LAASR, a message is generated with information about its geographical position and the unique identity of the identified target unit. This collected data is transported backwards via the mobile telephone network to the SAS server unit via LAASR.
    Thanks to the fact that the communication between target unit PSTR and search unit LAASR takes place through unidirectional short-distance data communication without data exchange between said units, a very cheap, efficient and secure system can be obtained.
    BRIEF DESCRIPTION OF THE ROUTES 10 15 20 25 30 35 536 544 Fig. 1 schematically shows the units included in a system for locating objects according to the present invention.
    Fig. 2 shows a typical search process with included units according to the invention.
    Fig. 3 shows a block diagram of a target unit PSTR, included in the system according to the invention.
    Fig. 4 shows a function diagram of the target unit PSTR according to Fig. 3.
    Fig. 5 shows a block diagram of a proprietary search unit LAASR, included in the system according to the invention.
    Fig. 6 shows a block diagram of a mobile telephone as search unit LAASR, included in the system according to the invention.
    Fig. 7 shows a model of how generated messages are transported in the system.
    Fig. 8 shows a definition of the messages generated in the system.
    Fig. 9 shows an example scenario of how the invention works. DETAILED DESCRIPTION OF THE INVENTION The following describes a system that uses a suitable radio protocol such as Bluetooth, Wi-Fi or wireless short distance data communication and obtaining a spontaneous wireless one-way communication Low Energy Bluetooth, similar protocol for identify the unique identity of a target device. One-way communication refers to such information transmission that is one-way, ie. a receiving unit "sniffs" the necessary information about a transmitter unit or node without performing any, by selected radio protocol, specified login / pairing procedure. Thus, no connected data communication ever takes place between the units. Thanks to the fact that the contact between the search and target unit takes place without data exchange and that only a limited amount of information data is transmitted unidirectionally from the digitally active radio units or so-called the nodes obtain a system that is simple, energy-efficient and cheap. The system is described based on the use of known radio protocols but can also be applied in proprietary radio protocols as long as the basic identification method is provided. The system can be used in a number of different environments and areas where vehicles, mobile devices, people or other objects are in different types of contexts. The target units or nodes are completely autonomous and are activated during manufacture. The nodes communicate by periodically notifying the environment of their discoverability by sending a radio signal, a discoverable message, with their unique identification. This identification message is generated by a defined security algorithm and is unique to the node.
    The identification message is protected by a code that can be loaded during the manufacture of the transmitter. The receiving unit or paging unit, may comprise a communication unit in the form of a mobile telephone, a computer or PC containing an application such as an "app" for identifying and interpreting spontaneously transmitted "discoverability messages" from the measuring units. modern mobile phone has the great advantage that it is already in standard version usually equipped with software that includes message handling and contact software.
    The application in the search unit also for sensitively sensing the "detectability message" associates a geographical position to the detected target unit.The geographical position is acquired via the receiver's available positioning mechanism such as via GPS, AGPS or other type of positioning technology.
    The search unit is also responsible for further transport of the target unit's unique session data via a mobile telecommunication network to the server unit which performs the necessary authentication of the target unit's identity and stores, processes, makes this information available for further processing, use and visualization on a digital map. The search device receives data from the target device via the appropriate radio protocol for short distance data such as Bluetooth, Low Energy Bluetooth, Wi-Fi, different generations of mobile telephony or other standardized or proprietary radio protocol. The system's overhead communication protocol is made up of a limited amount of data to avoid excessive communication and thereby limit the energy consumption of the target unit.
    Referring to Fig. 1, the system consists essentially of three types of units.
    - Target unit 10, "passive sending target radio", PSTR - Search unit 20 "Location Aware Active Search Radio", LAASR - Server unit 40, "Search Application Server", SAS Fig. 3 shows the target unit PSTR 10 in more detail. The target unit PSTR 10 is used for marking objects. The target unit PSTR 10 has low power consumption and is operational for at least 1 year and has a range for radio communication of at least 10 meters. In order to function as intended, the target unit PSTR 10 comprises the following parts: Radio transceiver module 11 (radio module) with associated CPU and protocol stack 12 Battery with associated power electronics 14 The target unit's PSTR 10 radio module 11 is programmed to periodically send a security-coded detectability message and therefore means for wirelessly transmitting short distance data, for example via a Bluetooth transmitter or the like for unlicensed RF communication frequency. The security code and the periodicity of transmission of the detectability message are defined during fabrication by unique identification data that includes a secret algorithm which is fixed and can not be changed, unless the device is physically connected to a special preparation application for calibration. The security coding enables a unique identification that can be authenticated in the associated server unit SAS 40 which includes verification means 40A for this purpose, since the corresponding code with the unique identification data as the target unit PSTR 10, is stored in advance in the server unit SAS.
    The target unit PSTR is a passive unit that for security reasons cannot be contacted by search units LAASR 20, ie. the communication between said units is one-way. A distinctive feature of the present invention is thus that there is no bidirectional or inter-one-way communication ensuring that the target unit PSTR can not be manipulated during in operation pairing authentication target unit and paging unit. in order to put the system out of action.
    The security coding of the detectability message ensures that "pirated" devices could not be inserted into the system in order to confuse the identification of unique genuine target devices PSTR 10. The target device PSTR 10 is designed so that it can be easily used for marking various objects by application to the object. Depending on the intended application area, the design of the target unit's PSTR 10 can be varied, in particular in terms of format and service life. In some contexts, it is appropriate to attach the target unit PSTR 10 to the object already during its manufacture, which may be relevant in the manufacture of more theft-prone objects such as bicycles, laptops, machines, motor vehicles, etc. Common to all sold target units PSTR 10 is that the owner receives a object number (obj number) in the form of a registration certificate on its unit which is intended to be used in searching for or locating the target unit PSTR 10.
    Fig. 5 shows a proprietary variant of the search unit LAASR 20 in more detail and as can be seen it mainly comprises the following parts: - Radio transceiver modules 21 (radio modules) with associated protocol stack 22 - GPS module 23 or other positioning mechanism for position determination - CPU unit 24 with unit for Internet connection 25 and reporting back to the server unit SAS 40 either wired or via a mobile communication system - Power supply electronics 26 Fig. 6 shows a mobile phone or corresponding portable computer-based client unit as a variant of the search unit LAASR 20 with the following basic requirements for included functions to can be used as a LAASR: - Applied generation of mobile technology that allows data transfer via mobile internet - GPS module 23 or other positioning mechanism for position determination - Radio technology for short distance data communication with peripherals or networks such as Wi-Fi, Bluetooth, Low Energy Bluetooth or other.
    Ability to carry and execute an application for search, search application. illustrated in Fig. 7, the LAASR 20 listens for "detectability messages" from target units PSTR 10. The search unit LAASR 20 primarily listens for any "detectability messages" from target units within range. "from a target unit PSTR 10 a data packet 3 is generated in which the search unit LAASR 20, by means of its GPS module (or other positioning mechanism) 23, adds information about its own position and the target unit PSTR 10 identification code (hardware ID; MAC, IMEI etc.).
    Fig. 8 shows an example of such a message, a position packet 3.
    The position packet 3 is either sent directly backwards via mobile internet or other suitable communication such as an SMS message ("Short Message Service"), MMS message.
    ("Multimedia Messaging Service") or an e-mail to the parent system's server unit SAS 40. Alternatively, suitable collection packages can be stored and sent on fewer occasions. The server unit SAS 40 receives information that the searched target unit PSTR 10 is roughly located and an identification on the specific search unit LAASR 20 as registered current target unit PSTR 10. The search application can suitably be arranged in a plurality of search units, whereby a continuous stream of position packets 3 regarding geographically dispersed PSTR 10 will be available in the server unit SAS 40. In addition, the search unit LAASR 20 is designed for remote updating (app update) as well as permissible "anchoring" of target units PSTR 10, ie monitoring and control of one or more specific target units so that they do not disappear out of reach of radio contact. a message that is carried backwards t to the server unit 40.
    The proprietary variant of the search unit LAASR 20, ie. Search units with predetermined restrictions on use, modification, etc., can be conveniently distributed to vehicles with periodic routes to form an infrastructure by searching for target units PSTR 10. The mobile phone-based variant of the search unit is made possible by a search application, an app. loaded into a phone by a user for the purpose of explicitly indirectly participating in reward systems when a target device is found. The reward systems will be based on participating in a security system or activities based on the collected information in the server unit SAS 40 about the associated information about the search unit LAASR 20 in each position packet 3 about the detected target unit PSTR 10.
    Fig. 2 illustrates the search process in more detail and, as can be seen, target units PSTR 10 (PSTR #x) periodically send the detectability message via the appropriate short-distance data communication (radio communication). These messages are detected by search units LAASR 20 when they are in range.
    Referring to Fig. 9, an example is shown in which a target unit PSTR 10 is detected by two separate first and second search units LAASR 20: 1 and 20: 2 and how spontaneous contact information between the units generates location information which is transmitted via radio communication and stored in the server unit SAS 40. A target unit PSTR 10 with identification number 1234 is attached to an object that has been stolen and moves along 10 15 20 25 30 35 536 544 the dotted line that goes from the unit of measure and ends with an arrow. During the journey, the target unit PSTR 10 first comes within reach of the first search unit LAASR 20: 1, this occurs when PSTR 10 comes inside the radio bubble illustrated by the dashed circle around the two search units LAASR 20: 1 resp. 20: 2. At this time, the target unit's PSTR 10 radio signals will be within range of the first search unit LAASR 20: 1. This spontaneous contact is illustrated by X1.
    At said contact the measuring unit PSTR 10 sends a message which for example contains the following data 1234,000012FE, FE12ABBB, 112A5CEFE12F982FA2 and where 1234 stands for the target unit PSTR 10 identification number, 0OO012FE is the index number for a counter which continuously counts upwards with 1 sec interval P predetermined lifetime, FE12ABBB is a randomly generated data sequence, 112A5CEFE12F982FA2 is a so-called hash value calculated on all previous values together with the secret code, identification data which is stored in the current target unit PSTR 10, 1234, and on the server unit SAS 40. The first search unit LAASR 20: 2 receives the message described above, adds information about their own identity, time and date when the meeting X1 took place as well as information that includes geographical data (latitude and longitude) for the meeting. All this information is compiled into a message which is sent via mobile internet WWW to the server unit SAS 40 for storage in the database DB 60. For this purpose, the target unit PSTR 10 comprises a generating means 10A which, based on a counter built into the unit, generates a data object attached to the discoverable message received by the search unit LAASR 20.
    The target unit PSTR 10 continues to move along the dashed line and finally comes into contact with the other search unit LAASR 20: 2. At point X2, the target unit PSTR 10 is so close that its radio signal with detectable message reaches the second paging unit LAASR 20: 2.
    Here, the measurement unit PSTR 10 sends a message that may contain the following data 1234,00001302,4398F1AD, 315B52AF342FOC11F3. As described above, said data contains the following information; the target unit's PSTR 10 identification number, an index number (note that the value this time is higher than the previous message), a randomly generated data sequence and a hash value based on message data and the secret code, identification data stored in the target unit PSTR 10 and in the server unit SAS 40 The second target unit LAASR 20: 2 receives the data described above, adds information about its own identity, time, date and geographical location for the meeting, and sends this message via mobile internet to the server unit SAS 40 for further storage in the database DB 60.
    All data regarding any subsequent meeting places, X1-Xn, is verified by the server unit SAS 40 by calculating a hash value here in the same way as short-distance data communication. That is, for the point marked X1, the server unit SAS 40 takes the values 1234, 000012FE, FE12ABBB and the secret code for the target unit PSTR 10 which is stored in the server unit SAS 40. Then the calculated value is compared with the value sent by the target unit PSTR 10 (ie. .112A5CEFE12F982FA2), if the value calculated by the server unit 40 corresponds to the value sent by the target unit the target unit made before sending its message via PSTR 10, it is considered verified that the message is valid, if the two values being compared do not match.
    The validity of meeting place X2, and the following meeting places Xn not shown in the figure, are linked to the meeting place X1 by assigning an index number higher than X1 to be counted as valid messages. The purpose of this is to avoid so-called "replay attacks", where a counterfeit target unit PSTR 10 plays radio messages that have been intercepted during previous sessions. The SAS 40 server unit continuously keeps track of all index numbers for each individual PSTR 10 target unit contained in the system to guarantee this function.
    All meeting places can then be used to build different types of services, for example it would be conceivable to show a series of meeting places "X" on a digital map image as described in Fig. 9 where each meeting place "X" is marked with the measuring unit's PSTR 10 identification number and time / date of the meeting place. It is also possible to derive each unique meeting place with the unique search unit (s) LAASR 20 that were involved in the meeting. the information can be presented to the user in any suitable way that suits the positioning data. If positioning data consists of, for example, postcodes, data can be presented graphically in the form of a local area map.
    The present invention is not limited to what is described above and that shown in the drawings, but can be changed and modified in a number of different ways within the scope of the inventive concept stated in the appended claims.
    权利要求:
    Claims (14)
    [1]
    A method for locating objects in a wireless spontaneous network wherein each object carries a passive target unit PSTR (10) with a unique electronically recordable identity and which method comprises the following steps; a search unit LAASR (20) is arranged; - that the search unit LAASR (20) and the target unit PSTR (10) are designed for mutual contact and formation of spontaneous networks through wireless communication; - the search unit LAASR (20) is equipped with means for generating an electronic message and determining its geographical position; - that a server unit SAS (40) with assigned database DB (60) is arranged; - that the search unit LAASR (20) is arranged for wireless communication with the server unit (40): - in the event of spontaneous contact between the search unit LAASR (20) and the passive target unit PSTR (10), a message (3) is generated by the contacting search unit; - based on the unique identity of the current target unit PSTR (10), associated data from the contacting search unit is attached to the message (3) including the geographical position of the search unit LAASR (20) (X1, X2) at the time of contact; - that the message (3) generated at the contact is addressed and sent from the search unit LAASR (20) to the server unit SAS (40), characterized in that the spontaneous contact between the search unit LAASR (20) and the passive target unit PSTR (10) takes place via wireless one-way short-distance data communication, whereby the target unit PSTR (10) unique identity and detectable message is registered by the search unit LAASR (20) without feedback data exchange with the target unit PSTR (10), and that the message (3) from the search unit LAASR (20) to the server unit SAS (40) is forwarded a mobile telecommunications network.
    [2]
    A method according to claim 1, wherein the spontaneous contact between the search unit LAASR (20) and the passive target unit PSTR (10) takes place in the absence of a handshake or pairing method depending on the selected communication protocol.
    [3]
    A method according to any one of claims 1 to 2, wherein the message (3) generated at the contact is addressed and sent from the paging unit LAASR (20) to then be registered in the server unit (40) together with the paging unit's LAASR (20) unique identity to obtain traceability and information in which paging unit (20) the message was generated. 10 15 20 25 30 35 536 544
    [4]
    Method according to one of claims 1 to 3, wherein identification and control of target unit PSTR (10) is performed by comparing the unique identity of the target unit, which is forwarded in the message (3), in the server unit SAS (40) with a register of in advance in database DB (60) stored identities.
    [5]
    A method according to any one of claims 1 to 4, wherein the target unit PSTR (10) provides supplementary identity data based on an index number set based on the target unit PSTR (10) predetermined lifetime and which index number, for identification and control of contacted target unit, in the server unit SAS (40) is compared with the corresponding index number stored in advance in the database DB (60).
    [6]
    A method according to any one of claims 1 - 5, wherein the search unit LAASR (20) is arranged for "anchoring" of one or more specific target units PSTR (10) and that, in case of lost radio contact with a target unit PSTR (10) with specified identity, a message is generated in the search unit LAASR (20) which is addressed and sent to the server unit (40).
    [7]
    A method according to any one of claims 1 to 6, wherein the search unit LAASR (20) is arranged on any moving object such as a human, a vehicle with periodic recurring routes, a rental car, mail van or similar distribution vehicle, alternatively a bus, a tram or a train to form an infrastructure that can search for target units PSTR (10).
    [8]
    A method according to claim 7, wherein one of the following communication units is used as search unit LAASR (20); a mobile phone, a computer or PC containing an interpreter I! u app for “discovery messages” from a target device PSTR (10). application such as one to identify and spontaneously broadcast
    [9]
    Systems for locating objects in wireless spontaneous networks comprising; one or more passive target units PSTR (10) each having a unique electronically recordable identity and intended to be arranged to a respective object; a passive search unit LAASR (20) which includes a CPU unit (34) for generating a message (3) and a GPS module (33) for generating information about the geographical position of the search unit, - a server unit SAS (40) with assigned database DB (60) and which server unit is designed for wireless communication with the search unit LAASR (20); that each passive target unit PSTR (10) and each paging unit LAASR (20) comprise a radio module (11, 21, 31) which allows spontaneous short-range communication between the units; 10 10 15 20 25 30 35 536 544 and that in the event of spontaneous contact between paging unit LAASR (20) and target unit PSTR (10), a message (3) is generated by the contacting paging unit in which, based on the unique identity of the target unit PSTR (10), associated data from the contacting search unit LAASR (20) to the message including the geographical position of the search unit (X1; X2) at the time of contact; where the message (3) generated at the contact is addressed and sent from the search unit LAASR (20) to the server unit SAS (40), characterized in that the search unit LAASR (20) and the passive target unit PSTR (10) comprise means for unidirectional short-distance data communication from target unit PSTR (10) to search unit LAASR (20), the unique identity and detectable message of the target unit being registered by the search unit LAASR (20) in the absence of feedback data exchange with the target unit, that the search unit LAASR (20) comprises a radio module (11, 21, 31) communication between the units via a mobile telecommunication network and that said message (3) stating the unique identity of the target unit is forwarded from the search unit LAASR (20) to the server unit SAS (40) via a mobile telecommunication network.
    [10]
    The system of claim 9, wherein the server unit SAS (40) comprises an authentication means (40A) for checking that the unique identity of the target unit PSTR (10), which is forwarded in the message (3), corresponds to an identity previously stored in the server unit SAS (40) assigned database DB (60).
    [11]
    A system according to any one of claims 9 to 10, wherein the target unit PSTR (10) comprises a generating means (10A) for generating a data object attached to the message sent from the search unit LAASR (20), which data object is assigned data set from the target unit PSTR (10) predetermined lifetime, and that the server unit SAS (40) includes verification means for checking the target unit PSTR (10) by the generating means set data objects, which are forwarded in the message correspond to pre-stored database values of the server unit SAS (40).
    [12]
    A system according to any one of claims 9 to 11, wherein the search unit LAASR (20) comprises means for both short-range wireless data communication and means for wireless data transmission of message via mobile telecommunication network.
    [13]
    13. Use of a mobile phone with software in the form of an application, an "app" to, with wireless one-way short-distance data communication and lack of feedback data exchange from the mobile phone back to a target device, identify and interpret spontaneously sent "discoverability messages" from target devices. 11 10 536 544
    [14]
    14. Application program comprising software in the form of a so-called "App" intended for use in a mobile telephone (20), which program has the ability - to, with one-way short-distance data communication and lack of feedback data exchange from the mobile telephone back to a target unit PSTR (10), identify and interpret spontaneously sent "discoverability messages" from the target unit, and - that based on the unique identity of the target device PSTR (10), associated data from the mobile telephone (20) is attached to a message (3) including the geographical position of the mobile telephone (X1; X2) at the time of contact, where the message (3) generated at the contact is addressed and transmitted from the mobile telephone (20) to a server unit SAS (40) via a mobile telecommunication network.
    类似技术:
    公开号 | 公开日 | 专利标题
    US10771945B2|2020-09-08|Tracking and theft-recovery system for mobile assets
    Hamida et al.2015|Security of cooperative intelligent transport systems: Standards, threats analysis and cryptographic countermeasures
    Sampigethaya et al.2005|CARAVAN: Providing location privacy for VANET
    BR112012002103B1|2021-05-04|asset tracking system, mobile base station module and asset tracking method
    JP3994999B2|2007-10-24|Ad hoc communication system, mobile terminal, center, ad hoc communication method, ad hoc communication program
    JP2009045956A|2009-03-05|Traffic safety system
    CN103370950A|2013-10-23|System, servers, methods and computer programs for machine-to-machine equipment management
    US20160330534A1|2016-11-10|Sensor data broker for directed collection of sensor data between mobile collector device and sensor consumer
    JP2019013045A|2019-01-24|Method and platform for sending message to communication device associated with moving object
    Agadakos et al.2017|Techu: Open and privacy-preserving crowdsourced GPS for the masses
    CN103002059B|2015-11-11|gateway cloud server system
    JP6238446B2|2017-11-29|Method for locating a wireless device in an environment with a wireless network having at least one access point
    CN106060773B|2019-07-19|Object positioning system, method and device
    CN107682819A|2018-02-09|A kind of caution system for detecting bluetooth equipment displacement
    SE536544C2|2014-02-11|Procedure and system for locating objects in wireless spontaneous networks.
    Zuo et al.2017|Cost-effective privacy-preserving vehicular urban sensing system
    WO2021098028A1|2021-05-27|Progressive global positioning system and method
    US20150126233A1|2015-05-07|Method and apparatus for locating a low-power wireless device using a smartphone
    JP2015139011A|2015-07-30|Radio communication device, and radio communication method
    Li et al.2015|A reputation-based secure scheme in vehicular ad hoc networks
    Goswami et al.2015|Development of a prototype to detect speed limit violation for better traffic management
    Jeon et al.2018|A crowd-assisted architecture for securing BLE beacon-based IoT infrastructure
    Dharani et al.2015|An Unidentified Location-Based Efficient Routing Protocol in VANET
    KR100827166B1|2008-05-02|Method for providing anonymity of source sensor node's id
    JP2021064315A|2021-04-22|Individual identification device, individual identification system, and individual identification method
    同族专利:
    公开号 | 公开日
    EP2962128A1|2016-01-06|
    EP2962128A4|2017-01-18|
    WO2014133443A1|2014-09-04|
    SE1350227A1|2014-02-11|
    US20160007163A1|2016-01-07|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    GB0007942D0|2000-04-01|2000-05-17|Hewlett Packard Co|Distributed search method|
    JP4653078B2|2003-03-13|2011-03-16|メッシュネットワークスインコーポレーティッド|Real-time system and method for improving location accuracy of mobile subscribers in a wireless ad hoc network using a low-speed central processing unit|
    JP4251018B2|2003-05-27|2009-04-08|株式会社日立製作所|Node position display method|
    EP1821116B1|2006-02-15|2013-08-14|Sony Deutschland Gmbh|Relative 3D positioning in an ad-hoc network based on distances|
    SE0702265L|2007-10-09|2009-02-10|Thomas Malm|Procedure and system for locating objects in wireless networks|
    FR2924818A1|2007-12-06|2009-06-12|Commissariat Energie Atomique|Remote localization system for e.g. military operation, has master node determining difference between free node and master node, and free node and reference node to deduce relative position of free node|
    NO334170B1|2011-05-16|2013-12-30|Radionor Comm As|Method and system for long distance, adaptive, mobile, beamforming adhoc communication system with integrated positioning|
    KR20120132934A|2011-05-30|2012-12-10|삼성전자주식회사|Apparatus and method for obtaining information on location of accessory in wireless communication system|EP3432553B1|2014-06-13|2020-06-03|9Solutions Oy|Method and system for positioning a beacon device|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    SE1350227A|SE1350227A1|2013-02-28|2013-02-28|Procedure and system for locating objects in wireless spontaneous networks.|SE1350227A| SE1350227A1|2013-02-28|2013-02-28|Procedure and system for locating objects in wireless spontaneous networks.|
    PCT/SE2014/050235| WO2014133443A1|2013-02-28|2014-02-26|Method and system for localization of objects in wireless spontaneous network|
    US14/771,423| US20160007163A1|2013-02-28|2014-02-26|Method and system for localization of objets in wireless spontaneous network|
    EP14756647.5A| EP2962128A4|2013-02-28|2014-02-26|Method and system for localization of objects in wireless spontaneous network|
    [返回顶部]