JP4718755B2 - Communication system, beacon device, communication device and method - Google Patents

Description

[0001]
The present invention relates to services provided to users of electronic devices, and in particular to users of mobile communication devices such as mobile phones and appropriately equipped personal digital assistants (PDAs). But is not limited to this.
[0002]
In recent years, there has been a dramatic increase in subscribers to the global mobile telephone network, and advances in technology and added functionality have made cellular telephones privately owned. As a result, the mobile information society has developed and personal and local services are becoming more important. Such “Context Aware” (CA) mobile telephones communicate with a base station with a narrow range of responsibility for providing information specific to a place such as a shopping mall at low power. The information includes a local map, information on nearby shops and restaurants, and the like. The user's CA terminal is configured to filter the information received according to the user preferences stored in advance and notify the user only when a data item relating to a particular preference is received.
[0003]
An example of a CA terminal is given in US Pat. No. 5,835,861, which discloses the use of a wireless telephone in connection with advertisement posting. A radiotelephone user activates his / her radiotelephone, sends a prompt signal to the actual advertising source, and receives a response signal from the advertising source that includes the advertiser's phone number, Get the phone number of the vendor. The telephone number can be used to automatically make a call to the merchant via the public switched telephone network. Alternatively, the phone number can be stored for later use. Using this system, it is possible to place a call to a merchant without storing or recording the telephone number. This signal between the bulletin board and the caller can be transmitted as a modulated infrared (IR) signal.
[0004]
In another example, Hewlett-Packard has published http://www.cooltown.hp.com/papers/webpres/WebPresence.htm on the web regarding the “Cooltown” program. The aggregation of web technologies, wireless networks and portable client devices provides room for design and development for computer / communication systems. In the Cool Town project, a location aware system uses a URL to address, a physical URL for delivery via a beacon, and a local web site for the search URL and directory. It can be formed by detecting the server. This system is provided everywhere to serve fluid users. At the top of this infrastructure, an Internet connection is made to support communication services. Bridging the world wide web and the physical world occupied by the user by the web, it provides a model that supports fluid users without central control points.
[0005]
Cooltown Art Museum and Bookstore provide Web-enhanced experiences for visitors. As a visitor navigates through the museum, a portable digital assistant (PDA) can receive a web URL over a wireless “beacon”. These beacons are small infrared transceivers placed close to a painting or sculpture; their URLs link to a web of information about the item. By using the PDA web browser, visitors can see and hear about the artist and work and related art objects in the museum. It is also possible to store URLs as bookmarks for later study, or to use them to select arts and crafts from a museum online store.
[0006]
An important requirement for CA devices is to quickly and efficiently collect data from the beacons, which requires the user to stay close to the beacon when establishing a link between the mobile device and the beacon. No special initial interaction (such as the system in US 5,835,861 mentioned above) is required. A further requirement is that the mobile device should be relatively simple as far as the relevant data collection from the beacon is concerned: in the Cooltown system, the web page specified by the broadcast URL A complete web browser (browsing) and display capability is needed to support user navigation in the world.
[0007]
Accordingly, an object of the present invention is to provide a system for distributing data using a beacon, and to reduce the amount of dedicated circuits and operation procedures.
[0008]
A communication system according to a first aspect of the present invention is a communication system having at least one beacon device capable of wireless message transmission and at least one portable device capable of receiving such message transmission. The beacon is configured to broadcast a series of inquiry messages in the form of a plurality of predetermined data fields formed in accordance with a first communication protocol, the beacon being further appended prior to transmission A data field is formed to append to each inquiry message, and the at least one portable device is configured to receive a transmitted inquiry message and read data from the additional data field, the additional data field being It is a communication system including position information. By adding additional fields (appropriate to the end of each query message), data broadcast is usually performed at the beginning of an existing query process, and such a process is usually performed prior to data transfer. The delay is avoided. Furthermore, those protocol compatible devices that are not intended to receive beacon signals by placing an additional field at the end of what was transmitted according to the communication protocol (preferably but not limited to Bluetooth). Can simply ignore the additional data without compromising the operation of the protocol.
[0009]
A beacon when the protocol is Bluetooth (or similar frequency hopping system) is configured to broadcast a series of inquiry messages in a predetermined clock sequence or sequence of frequencies, and the clock information about the beacon is Transmitted by additional data field. In one embodiment, the additional data field may carry at least 64 bits of data. As will be described in detail below through embodiments of the present invention, this improves Bluetooth system query execution and reduces time for connection probabilities for data exchange.
[0010]
The beacon can be constructed to include an indicator in one of the predetermined data fields (preferably a field that is not currently used or assigned), which indicates the presence or absence of an additional data field. A device constructed to receive beacon data is activated to read from its additional data field.
[0011]
When the first communication protocol consists of Bluetooth messages, a specific Dedicated Inquiry Access Code (DIAC) can be used to indicate the presence or absence of location information in an additional data field It is.
[0012]
The presence of location information in the additional data field can be specified by header information appearing in the additional data field.
[0013]
The communication system can execute transmission and reception of a wireless message by using a technique using frequency hopping. In this case, position data is transmitted at each frequency used in the broadcast of the inquiry message.
[0014]
The beacon can be constructed to include the first comparison data in the message, and when the portable device further matches between the storage means holding the second comparison data and the first and second comparison data And comparison means constructed to provide data read from the additional data field, or to provide no data. Such second comparison data can be predetermined and / or stored in advance, or determined as appropriate from user attributes of the mobile device user.
[0015]
That is, a means for generating the second comparison data from the user attribute of the mobile device user can be provided. The comparison means may be a programmable device operable to perform a comparison between each set of first and second comparison data, either synchronously or redundantly.
[0016]
According to the present invention, there is also provided a mobile communication device for use in the above system, which device can receive a short-range wireless inquiry message including a plurality of data fields according to a first communication protocol. And a means for determining when an additional data field including position information is added to the plurality of data fields, and a means for reading position information data from such additional data field. .
[0017]
Further, the beacon device provided by the present invention is a beacon device capable of wireless message transmission and used in a communication system, the communication system receiving such message transmission with the beacon device. A beacon device having at least one portable device capable of broadcasting a series of inquiry messages in the form of a plurality of predetermined data fields formed according to a first communication protocol Prior to transmission, configured to append an additional data field to each inquiry message, wherein the at least one portable device receives the transmitted inquiry message and reads data from the additional data field. The additional data field is formed to enable It is a beacon apparatus of the place, including location information. As generally described in connection with the system, the beacon device can be constructed to append an additional data field to the end of each query message; it is constructed to include an indicator in one of the predetermined data fields. Possible, the indication indicates the presence or absence of an additional data field; the first communication protocol may consist of a Bluetooth message; the device is for a beacon contained in the data carried by the additional data field. The clock information can be used to broadcast a series of inquiry messages using a clock sequence of a predetermined frequency.
[0018]
Furthermore, the method provided by the present invention is a method for allowing a user of a portable communication device to receive a broadcast message, wherein at least one beacon device is formed of a plurality of predetermined ones formed according to a first communication protocol. Broadcast a series of inquiry messages in the form of data fields, and prior to transmission, the beacon adds an additional data field carrying broadcast message data including location information to each inquiry message; A method in which the portable device receives a transmitted inquiry message including the location information and reads broadcast data from the additional data field.
[0019]
  A communication system according to one embodiment comprises:
A communication system having at least one beacon device capable of transmitting a message wirelessly and at least one portable device capable of receiving the message, wherein the beacon device transmits a series of inquiry messages. Each of the series of inquiry messages is formed by a plurality of predetermined data fields formed in accordance with a first communication protocol, and the beacon device is further prior to transmission. The additional data field is configured to be added to the series of inquiry messages, wherein the at least one portable device receives the inquiry message transmitted and reads data from the additional data field. The additional data field Field is the location or locations including at least one of specific information is a communication system.
  These and other aspects and advantages of the present invention will become apparent from the following description of the preferred embodiments.
[0020]
The preferred embodiments of the present invention will now be described by way of example only with reference to the drawings.
[0021]
In the following description, we will consider the use of CA in particular, which utilizes the Bluetooth protocol for communication of messages from beacons to mobile devices (phones, PDAs or other devices). It is understood that the general inventive concept of including a broadcast channel as part of an inquiry procedure is not limited to Bluetooth devices, but is particularly applicable to other communication systems such as frequency hopping systems. Will be done.
[0022]
FIG. 1 is a schematic block diagram of a CA mobile telephone 10 that utilizes one or more low power small area base stations or beacons 12, 14. As explained in detail below, as described above in detail, utilizing such a system arrangement for a shopping mall-like location, a beacon downloads an information key to the mobile device, thereby allowing local It is possible to provide specific location information such as maps, neighborhood store and restaurant information, and the like. As will be described in detail below, this system can be used to provide position information itself, such as mapping coordinates, for example. An information key is a small data object that provides a query for the complete source of information, in the form of a number of predefined data fields, one of which is a description provided to the user. May be included. Other fields are other types of pointers or addresses such as URLs or telephone numbers. Other supplemental fields control how the data is presented to the user and how the address is utilized. A beacon typically broadcasts multiple keys in a cyclic fashion, each of which is generally associated with a different service.
[0023]
Matters related to beacon configuration and construction include beacon range, which will depend on output power (typical range is 1 mW to 10 mW), local interference level and reception sensitivity.
[0024]
The user's CA terminal 10 has an antenna 16 coupled to a transceiver stage 18 for message transmission and reception. Outgoing messages originate from user input to the phone and are voice input via the microphone 20 and A / D converter 22 or other data via a keypad or other settlement means 24. These inputs are processed by the signal and data processing stage 26 into a message data format and converted to a transmission format by the encoder before being provided to the transmission stage 18.
[0025]
Messages received via the antenna 16 and the transceiver 18 are transmitted to the filter processing and signal processing stage 32 via the decoding stage 30. If the data carried by the message is to be presented on the display screen 34 of the telephone, after the selective buffer link, the driver formats the display image and the data is transmitted to the display device 36. The The display 34 is a relatively simple low-resolution device, and the conversion of received data into display data can be performed as a function of a part of the processing stage 32 without requiring a dedicated display driving stage. It will be understood.
[0026]
If the message carries data from one or the other of the beacons 12, 14, the phone has the function of filtering the information received according to the pre-stored user preferences 40, the stored data; Only when the result of the comparison with the indicator (indicator) of the target item in the message indicates that the data item related to the specific interest has been received, the user is notified (that is, the information is held in the buffer 38, And / or displayed on screen 34).
[0027]
For conventional acoustic messages, the acoustic data is output by the filter and processing stage 32 to an earphone or speaker 46 via a D / A converter 42 and an amplifier 44. Receipt of such a message from the telephone network is indicated by arrow 50: Telephone network 48 also provides a link from telephone 10 to a wide area network (WAN) server 52 (which may also be the Internet). A link is also provided via the WAN 54 to one or more remote service providers 56 that provide a data source for the telephone 10.
[0028]
Communication between a CA terminal (telephone 10) and a CA base station (beacon 12) takes two forms: 'push' and 'pull'. In the 'push' mode, information is broadcast from the beacons 12 and 14 to all mobile terminals 10 in the form of a short 'key' indicated at 60. The key can take a variety of forms depending on the application, but generally a concise description of the information to be transmitted, or a pointer to more detailed information, such as a URL specifying one of the service providers 56 including.
[0029]
The keys are received 'unconsciously' by the terminal 10, ie automatically filtered according to the user's preset preferences without direct user intervention. The filtering process is performed by the comparison function in the processing stage 32. Preferably, the processing stage is operative to apply a comparison function with multiple simultaneous or duplicate copies to process a relatively large number of received keys in parallel. Some are ignored, some are retained for further exploration, and others are immediately alerted to the user. For example, in the information that the user is interested in and therefore set in the filter 32, the store causes the terminal to pass to select to press the details of a specific guide so that those terminals are informed.
[0030]
In some cases, the user may wish to obtain more information than is contained in the key. In such a case, the 'pull' mode allows the user to set up a connection to the server 56 (the server does not necessarily have to be specially configured to use the CA) and the request information is actually sent to the terminal It is possible to be pulled out to 10.
[0031]
Base stations or beacons are generally independent of each other (in a shopping mall setting, each store provides or maintains its beacons without reference to beacons provided by neighboring stores). Beacons are networked in whole or in part, at least in cooperation with those broadcast messages.
[0032]
FIG. 2 illustrates such a system 100 for linked beacons according to the present invention, which implements an infrastructure for use in locations such as department stores, shopping malls, theme parks, and the like. The system 100 is composed of a plurality of beacons 102, 104, 106, 108 arranged over a series of locales. Each of the beacons 102-108 broadcasts one or more short range interrogation signals in a time slot format described in detail below. Beacons 102-108 are controlled by Beacon Infrastructure Server (BIS) 110 by one or more terminals 112, 114, 116, 118 connected to server 110. Terminals 112-118 are allocated service slots in the form of additional data piggybacked by the service provider, i.e., the user of the beacon 102-108, to the query assistance signal transmitted by the beacon 102-108. Makes it possible to write or edit. The service provider can borrow a beacon or borrow one of the beacon service slots from the infrastructure provider. For this reason, the server 110 prepares a simple HTML template and allows the user to enter it through one of the terminals 112-118. For example, if a template is filled in with a description of the service and other information about the data carried through the beacon broadcast, the template is returned to the server 110 and either secure HTTP (S-HTTP) or secure socket layer ( It is preferably returned through a secure link such as SSL (Secure Socket Layer). SSL forms a link between a client and a server, through which arbitrary data is transmitted securely. S-HTTP is specified to securely send individual messages. Server 110 then forms an appropriate additional data packet and adds it to the interrogation signal for the appropriate one of beacons 102-108 based on the information submitted with the template. The system 100 further comprises an application server 120 to assist in performing various functions as will be readily understood by those skilled in the art.
[0033]
Returning to FIG. 1, a very promising technology for the radio link required for at least the 'pull' mode of the CA system described above is Bluetooth, which is expected to become a component of so many mobile phones 10. Because it is done. Problems are seen in the Bluetooth protocol regarding the use of CA broadcast or 'pull' mode. In an ideal case, the terminal 10 detects the fixed beacons 12, 14 and extracts basic information therefrom, but does not require the terminal 10 to transmit at all. However, this type of broadcast operation is not supported by current Bluetooth standards.
[0034]
The frequency hopping nature of the Bluetooth beacon system has led to some incompatible properties, which are due to broadcast messages (or arbitrary messages) received by the passing terminal. , Which means that the terminal needs to be synchronized to the beacon for both time and frequency. The mobile device 10 needs to synchronize its clock with the beacon clock and infer which of several hopping sequences will be used based on the beacon identifier.
[0035]
In order to make this guess, the portable device typically needs to participate as a slave in a piconet managed by a piconet master beacon. Two procedures are used: “inquiry” and “page”. The query allows the slave to find the base station and issue a request to join the piconet. The page allows the base station to accept slaves that have decided to join the net. Analyzing these procedures reveals that the time required to join the piconet and the time to receive information from the master is tens of seconds, which is very long for CA applications. That is, the user may move out of the beacon range before the participation procedure is completed.
[0036]
At least part of the difficulty of receiving broadcast data from beacons arises due to the frequency hopping nature of Bluetooth and similar systems. In order to solve the problems posed to both master and slave, a Bluetooth query procedure is proposed: what has been found by this application is that it is possible to add a broadcast channel to the query message issued by the master It is a thing. Only CA terminals need to read broadcast channel messages, and only CA base stations or beacons transmit them. As a result, the mechanism at the air interface can be fully compatible with existing (non-CA) Bluetooth systems.
[0037]
To explain how this is accomplished, first consider how the query procedure itself works with reference to FIGS. If a Bluetooth device wishes to search for another Bluetooth device, it enters a mode called an inquiry substate. In this mode, an inquiry message including a general inquiry access code (GIAC) or a plurality of selective dedicated inquiry access codes (DIAC) is issued. The transmission of this message is repeated in several stages; first it is transmitted on 16 out of 32 frequencies that form the query hopping sequence. The message is transmitted twice on two frequencies in an even time slot, which follows the odd time slot used to listen for replies on the two corresponding query response hopping frequencies. The 16 frequencies and their corresponding responses are translated in 16 time slots or 10 ms. The chart of FIG. 3 shows a transmission sequence of 16 frequencies centered on f {k}, where f {k} represents an inquiry hopping sequence.
[0038]
The next step is to repeat the transmission sequence at least Ninquiry times. At least, this requires 256 iterations of the entire sequence consisting of the transmission sequence referred to as inquiry transmission sequence A. Next, the inquiry transmission sequence A is replaced with an inquiry transmission sequence B consisting of transmission sequences at the remaining 16 frequencies. Again, sequence B consists of 256 repetitions of the transmission sequence. The entire inquiry transmission is a transmission cycle of the sequence A and the sequence B. As shown in FIG. 4, what the standard states is that it requires at least three transitions between sequences to ensure that all responses are collected in an error-free environment. This means that an inquiry broadcast takes at least 10.24 seconds.
[0039]
One way to reduce this is to switch between query transmission sequences more frequently, ie do not wait until 2.56 seconds, which is 256 times of 10 ms to cover 16 time slots, has elapsed. It is to switch with. This can be done by setting the system to switch, for example, if no inquiry message is detected after 50 ms and it is deemed that such message will not be detected in the rest of the current sequence. It is possible to achieve.
[0040]
A mobile device that wishes to be discovered by the beacon enters an inquiry scan substate. This listens for messages containing the GIAC or DIAC of interest. This also works periodically. This is heard on a single hop frequency during the Tw_inquiry_scan query scan period. This needs to be long enough to cover the 16 inquiry frequencies used in the inquiry. The interval between the start of successive scans should be less than 1.28 seconds. The selected frequency comes from 32 lists that form the query hopping sequence.
[0041]
When listening for an inquiry that includes the appropriate IAC, the mobile device enters what is called an inquiry response substate and issues multiple inquiry response messages to the beacon. The beacon then calls the mobile device and enters the piconet.
[0042]
As described above, as shown in FIG. 5, the proposal of the present application has an external data field to which an inquiry message issued by the base station is appended, which is a user-defined payload ( CA DATA) can be transported. In the CA scenario, this payload is used to carry broadcast information or keys to the CA terminal during the inquiry procedure. Significantly, by adding a field at the end of the inquiry message, a non-CA receiver can ignore it without modification. Further, by using the DIAC specific to CA, the CA receiver can be notified of the presence or absence of the external information field.
[0043]
The presence of an external data field generally reduces the guard space allowed at the end of Bluetooth query packets. However, this space-provided to give time to the frequency synthesizer to switch to a new hop frequency-is not normally used, which means that the current frequency synthesizer will It is possible to switch at a speed that does not require expansion. A standard inquiry packet is a 68-bit long ID packet. Since this is transmitted in half the slot, the allocated guard space is (625 / 2−68) = 244.5 μs (slot duration is 625 μs and signal rate is 1 Mbit / s). . Modern synthesizers can be switched in less time than a value of 100 μs, or in a short time routine contemplated by those skilled in the art. Although the present application proposes an allocation of 100 bits as an appropriate size for a new field, it will be readily appreciated that other field sizes can be used.
[0044]
The CA handset can quickly receive broadcast data without having to go through a long-term procedure to enter the piconet. In addition, the handset does not need to transmit any information, which can save power consumption, which is particularly important in dense environments where there can be many CA base stations. However, if the handset is in mutual mode and wants to enter the piconet to get more information, it is possible to use the default query procedure as the standard state. There is no functional loss due to supporting additional data fields.
[0045]
In a typical environment, 4 out of 100 bits are lost as trailer bits for the ID field; this is due to being read by the correlator. For the remaining 96 bits, according to the preferred assignment of this application, 64 is used as data and 32 is used as the 2/3 FEC (forward error correction) checksum, but the checksum, any included Headers and other overhead reduce the number of bits available for data, in some cases 10 bits or several bits. Each query burst contains 8 bytes of broadcast data. In the very general case, with the second group of A and B sequences, the portable device finds the base station, recognizes that it is a CA beacon, and notices the broadcast data. This continues to be heard especially so that the portable device can read at least 256 data bursts twice (A and B), resulting in two sets of 2K bytes or a total of 4K bytes.
[0046]
At this stage, the portable device does not know the phase of the beacon clock because the information has not been transmitted yet. To assist the portable device, clock information is transmitted in at least some sequences in the first group A and B as shown in FIG. 6 along with some auxiliary information when the next transition between A and B occurs Is done. This clock information is transmitted where CA broadcast data occurs and provides the ability to discriminate between the two data channels. Using a separate DIAC is one approach.
[0047]
If the mobile device knows the beacon timing, the mobile device also knows how it hops, which gives the ability to track all of the transmissions for the sequence. Since one frame contains 16 transmissions, the resulting CA channel has 16 times the capacity and can carry 64 Kbytes of information.
[0048]
Since the terminal wakes up every 1.28 seconds or less, it obtains clock information, which is necessary for half the marks of the first A or B period. The transition from clock to data at these intermediate marks as shown in FIG. 7 provides many advantages. First, some data can be received within 5 seconds from the start of the inquiry procedure. Second, the terminal can respond to an important key (as long as it is the appropriate action to be taken by the terminal) by automatically issuing an inquiry response message to the base station, even if that It is possible even if the key is relatively late in the cycle. It should be noted that no increase in capacity is assumed.
[0049]
The mobile device described so far receives all additional data field packets in one of 32 inquiry channels and uses only 1/32 of the available bandwidth. If the uncertainty about when the mobile terminal (beacon slave) receives the first inquiry packet is overcome, the predetermined nature of the hopping sequence is accommodated and all bandwidth is used Will be understood. For slaves that are synchronized to the master query hopping sequence from the time the first packet is received, the slave needs to know both the master clock offset and the location of the first packet received in the master hopping sequence. There is. In the following case, the master shall follow the Bluetooth minimum query procedure, which consists of 256 iterations of a 16-channel query hopping sequence with 3 sequence switching (as in FIG. 4). Each sweep for 16 channels takes 10 ms.
[0050]
Another embodiment for slave hopping synchronization is to send clock data for each broadcast field. An additional data field (BCD; FIG. 1) carries 4 bytes containing the following information:
Master clock offset (2 bytes);
• Total sequence repetition number (1 byte) —Assume that the total sequence consists of 256 repetitions of the 10 ms sequence, and that the range of this parameter is 0-255 (before the inquiry switches to the next complete sequence). This informs the slave when the next master transitions to all series.
[0051]
How many full-sequence transitions have been completed in the current query cycle (1 byte)-this data tells the slave what the master tends to do at the end of the current full sequence, ie other It is informed whether or not the transition is made to the entire series of or whether the inquiry procedure is completed.
[0052]
If there is no channel repetition in the 10 ms sequence, no field indicating the current channel position in the hopping sequence is needed. This is because the slave can derive it based on information about the sequence.
[0053]
So far, by adding 4 bytes to each additional field packet, the slave can extract all additional field packets by the end of the query, but (within 100 bits of data 4 bytes are available to carry further broadcast data (with 64 preferred allocations).
[0054]
Considering the complete beacon signal, it will be readily appreciated that it needs to be split into multiple 4-byte packets using what is sent with each query packet. For simplicity, assume a fixed-length beacon signal and assume that the complete signal can be accommodated in a single query sequence at 16 kB (the sequence is 256 repetitions of the 16 channel hopping frequency and 256 * 16 * 4 = 16 kB.)
[0055]
Extending this, from the message indicator of the number of repetitions for the current 16-channel hopping sequence in the message header, by determining that the first packet of the beacon signal follows the first packet of the query sequence, the slave Is enabled to derive the position of the beacon packet, which is received in the complete beacon signal.
[0056]
The mobile CA device is provided with a position detection application. Such applications generally require actual position information, unlike just specific position information. Hereinafter, transfer of such information to the mobile terminal will be described.
[0057]
In principle, by utilizing a Bluetooth link, location information can be transferred via a short-range air interface that allows location sensing devices to find their location. Such devices identify their location using data obtained from a location device such as a GPS receiver or other device that provides a source of location information. Therefore, it is not always necessary to equip an on-board location system that is expensive and often unreliable. Although not preferred, the transfer mechanism is affected by the above problems because the Bluetooth link must be established before the information is transferred. The establishment of such a link requires a Bluetooth slave terminal (in this case the terminal makes a location request) and participates in a piconet managed by the Bluetooth master terminal (in this case, the terminal responds to the query) .) The procedure for joining the piconet takes several tens of seconds. When this happens, the terminal does not know its current position, and therefore the operation of the position detection device in the terminal is impaired. This approach is therefore not ideal for providing location information to the situation detector and the mobile CA device will not stay for a sufficient amount of time in the vicinity of a given beacon to establish a Bluetooth link. . Furthermore, even if the device performs the establishment of a Bluetooth link, there is no guarantee that there is location information available, and the effort done may become useless.
[0058]
Therefore, the proposal of the present application is that the concept of the present application for establishing a broadcast channel from a beacon received by a CA device by adding data to an inquiry transmission is one of the broadcast information in the channel. A procedure for including position information as a part.
[0059]
As mentioned above, the initial proposal assumes that each query burst can carry 8 bytes of broadcast data in an extended field. Some of these are used to synchronize, leaving 4 to 6 bytes. A typical location information packet takes approximately 12 to 15 bytes and carries basic service information such as latitude / mild coordinates and some other parameters. For extended service purposes, location information typically requires 15 to 300 bytes in size, allowing information transfer such as speed information, optional supplemental descriptions, and URL fields to be carried. In any case, the information needs to be distributed over several packets. Basic service location information can be broadcast more frequently than extended service information. Optionally, extended service information can be extracted as a result of basic broadcasts with a 'client-pull' type operation in a normal Bluetooth connection, which is the same for clients. That extended service information is available.
[0060]
There are two possible techniques for distinguishing location information from other types of broadcast information (eg, other situation sensitive mobile phone services or broadcast audio): The first is to use a specific DIAC. Second, a header is included somewhere in the additional data field to describe the format of information content. The described embodiment assumes that the entire basic service location information burst is distributed over four extended inquiry packets, but this should not be construed as a limitation on the present invention. .
[0061]
The order of inquiry transmission from the master has been described above by using two sets of 16 frequencies included in the “sequence” of inquiry transmission. In each sequence, all 16 frequencies in a set are covered in 10 ms, and this cycle is repeated 256 times (eg, FIG. 4 and associated description). Each series is repeated twice.
[0062]
Since the slave scans at a single frequency arbitrarily selected from a set of 32 frequencies, it is advantageous to transmit location information at all frequencies used for inquiry transmission. Assume that each frequency requires 4 extension fields, a location information burst takes 40 ms, and takes about 1.6% of the total broadcast capacity for transmission.
[0063]
For fast position acquisition, assume that the beacon needs to be continuously active. Such activity usually interferes with the traditional two-way link being set up, but this problem can be overcome by utilizing two beacons that work together. It provides high speed access to the piconet and at the same time the bidirectional throughput capacity is not limited. A reference for such a system is UK patent application number GB0015452.6, filed on June 26, 2000 and entitled “Local Data Delivery through Beacons”.
[0064]
The number of position information transmitted in the sequence affects the access time to the position information. By increasing the frequency of position information transmission within the sequence, it is possible to improve the access speed to information. Assuming that one location information burst is transmitted per sequence and the access time is in the range of 0 to 5.12 seconds (if the time becomes longer, if the slave misses location information broadcast in the sequence) , We must wait for the rest of sequence A, the entire sequence B, and the next portion of sequence A until we can extract the location information).
[0065]
What is known to the terminal receiver (slave receiver) is that the inquiry information is broadcasted at each of 16 frequencies, for example every 10 ms, monitoring those frequencies every 10 ms, for example the receiver after 50 ms Is not managed to extract inquiry transmissions, and can be switched to monitor for the other 16 inquiry transmission frequencies associated with other sequences.
[0066]
If there are no inquiry transmissions received in the inquiry transmission sequence, the receiver can jump the frequency to those in other inquiry transmission sequences, for example carried in an additional data field such as location information. The access time to information is reduced. The reduced time is, for example, on the order of 2.56 seconds. Sending a burst twice per frame has the effect of dropping to an average of up to 1.28 seconds or 640 ms, for example.
[0067]
The location information can take the number of formats in both the format format of the location information to be expressed and the format format to be broadcast. For example, the information may be expressed in mapping coordinates, global positioning system data, or other suitable form. The position information may be absolute and relative. The position information in the latter case can be expressed with reference to, for example, information on building rooms, vehicle identifiers (for example, when a person is on a bus), and other methods obvious to those skilled in the art. .
[0068]
Other variations will be apparent to those skilled in the art from the disclosure herein. Such variations include those already described in the field of designing, manufacturing and using fixed and portable communication systems, systems and components that can incorporate the present invention, and to the features described herein. Other features may be used instead or in addition. For example, although techniques have been described that utilize 4 clocks and 4 data bytes in all broadcast packets, other arrangements (systems) can be used: (4 clocks and 4 data bytes in all 16 packets A system with 2 clocks and 6 data bytes in 15 out of all 16 packets (using bytes) can improve data carrying capacity without degrading synchronization performance.
[Brief description of the drawings]
FIG. 1 is a schematic block diagram of a beacon and a portable device used in the present invention.
FIG. 2 is a schematic diagram of a series of devices linked by a beacon infrastructure.
FIG. 3 shows a portion of the transmission of a query access code sequence centered on a given frequency.
FIG. 4 shows a switch between columns of inquiry messages over the duration of an inquiry broadcast.
FIG. 5 shows the insertion of a broadcast data packet in an existing transmission slot.
FIG. 6 shows a first arrangement for transmitting beacon clock data in a series of inquiry message sequences.
FIG. 7 shows another arrangement for FIG. 6 for transmission of beacon clock data.

Claims (44)

At least one beacon device capable of sending messages by radio, a communications system comprising at least one portable device capable of receiving the message, the beacon device, a series of interrogatory messages the is formed so as to broadcast, each of the series of inquiry messages is the form of a plurality of predetermined data fields formed in accordance with the first communication protocol, further wherein the beacon device, the transmission prior to the additional data fields are formed so as to add to the series of inquiry messages, wherein at least one of the portable device receives the inquiry message sent, read data from said additional data field It is formed as the additional data Fi Field includes at least one of information specific to the location information or location, communication system. The beacon device adds the additional data field at the end of each inquiry message communication system according to claim 1, wherein. The beacon device, to one of said predetermined data fields, including the shows to indicators of the presence of said additional data field, the communication system according to claim 1 or claim 2. The first communication protocol, to a Bluetooth message communication system according to any one of claims 1 to 3. Specific dedicated inquiry access codes (DIAC) is, the additional data field is used to indicate the presence of the position information and the specific information in a communication system according to claim 4. The communication system according to the presence of the position information and the specific information, said indicated by the header information appearing in the additional data field, to any one of claims 1 to 5 in the additional data field. Perform the communication system is a frequency hopping, each frequency used in the broadcast query message, the position data is transmitted, the communication system according to any one of claims 1 to 6. A transfer Dodori communication apparatus used in a communication system according to any one of claims 1 to 7, to receive a short-range wireless inquiry message including a plurality of data fields according to the first communication protocol a receiver capable, additional data field containing at least one of information specific to the location information or location, means for determining whether the time added to the plurality of data fields from the additional data field and means for reading the data of the position information and the specific information, transfer Dodori communication apparatus. The receiver receives the message according to the Bluetooth protocol, the mobile communication apparatus according to claim 8. It is possible to send a message by radio, a beacon device for use in a communication system, said communication system, said beacon device, at least one portable device capable of receiving the message have a, the beacon device, a series of interrogatory messages are formed so as to broadcast, each of the series of inquiry messages, the plurality of predetermined data fields formed in accordance with a first communication protocol are form, the beacon device, prior to transmission, adds additional data fields to the series of inquiry messages, wherein at least one of the portable device receives the transmitted inquiry message, the additional data it possible to read the data from the field, the additional data Field includes at least one of a specific information to the location information or location beacon device. The user of the portable communication device is a method to receive a broadcast message, at least one beacon device, broadcasts a series of inquiry messages, each of the series of inquiry messages, first communication are form by a plurality of predetermined data fields formed according to the protocol, the beacon device, prior to transmission, broadcast messages that contain at least one of the specific information to the location information or location · the additional data field carrying data, added to each inquiry message, the mobile communication device receives the transmitted inquiry message containing the location information or the unique information, the from the additional data field read the broadcast data, method. 12. The method of claim 11 , wherein the beacon device appends the additional data field to the end of each inquiry message. The beacon device, to one of the predetermined data fields, said additional data field include in the shown to indication of the presence of, claim 11 or 12 A method according. The first communication protocol, to a Bluetooth message A method according to any one of claims 11 to 13. The communication system according to any one of claims 1 to 9, wherein the position information or the unique information includes advertisement data. The beacon device according to claim 10, wherein the position information or the unique information includes advertisement data. The method according to any one of claims 11 to 14, wherein the position information or the unique information includes advertisement data. The communication system according to any one of claims 1 to 9, wherein the beacon device adds information so that a slave device can synchronize with a frequency hopping pattern when communicating with the beacon device. The beacon device according to claim 10, wherein the beacon device adds information so that the slave device can synchronize with a frequency hopping pattern when communicating with the beacon device. The communication system according to any one of claims 1 to 9, wherein the beacon device adds information so that a slave device can synchronize with a frequency hopping pattern when communicating with the beacon device. A communication device,
A circuit for broadcasting a plurality of messages wirelessly according to a communication protocol, each of the plurality of messages including one or more codes for discovering other communication devices;
  A circuit for adding an additional field including data associated with a user of the communication device to at least one of the plurality of messages;
  A communication device. The communication device according to claim 21, wherein the communication protocol is a Bluetooth protocol. The communication device according to claim 21, wherein the data associated with the user is advertisement data. The communication device according to claim 21, wherein the communication device and the other communication device are portable communication devices. The communication device according to claim 21, wherein the communication device is one of a mobile phone, a PDA, or a computer. The communication device according to claim 21, further comprising at least one of a display device, a microphone, a speaker, and a storage device. The communication apparatus according to claim 21, wherein the plurality of messages are inquiry messages. 28. The communication device according to claim 21, wherein the circuit that adds the additional data adds an additional field including data associated with the communication device to each of the plurality of messages. The communication device according to any one of claims 21 to 28, wherein the data includes position information. 29. A communication device according to any one of claims 21 to 28, wherein the data associated with the user includes location specific information. The communication apparatus according to claim 29 or 30, wherein the position information or the information specific to the place further includes advertisement data. The communication device according to any one of claims 21 to 28, wherein the data associated with the user includes information for identifying the communication device. A communication device,
A circuit for receiving a plurality of messages over the air according to a communication protocol, each of the plurality of messages including one or more codes for discovering other communication devices, wherein at least one of the plurality of messages One includes a circuit including an additional field that includes data associated with a user of the communication device;
  A circuit for processing data associated with a user of the communication device;
  A communication device. 34. The communication device according to claim 33, wherein the communication protocol is a Bluetooth protocol. 34. The communication device according to claim 33, wherein the data associated with the user of the communication device is advertisement data. 34. The communication device according to claim 33, wherein the communication device and the other communication device are portable communication devices. 34. The communication device according to claim 33, wherein the communication device is one of a mobile phone, a PDA, or a computer. 34. The communication device according to claim 33, further comprising at least one of a display device, a microphone, a speaker, and a storage device. The communication device according to claim 33, wherein the plurality of messages are inquiry messages. 40. The communication device according to any one of claims 33 to 39, wherein each of the plurality of messages includes an additional field including data associated with a user of the communication device. 41. The communication device according to any one of claims 33 to 40, wherein the data associated with a user of the communication device includes location information. 42. The communication device according to any one of claims 33 to 41, wherein the data associated with a user of the communication device includes location specific information. 43. The communication device according to claim 41 or 42, wherein the position information or the information unique to the place further includes advertisement data. 44. A communication device according to any one of claims 33 to 43, wherein the data associated with a user of the communication device includes information identifying the communication device.

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