Patent Application
20210250729
The present invention generally relates to use of a mobile device for causing some kind of activity depending on a proximity of the mobile device to a physical location. More specifically, the invention relates to a method of causing proximity-dependent activity by a mobile device. The invention also relates to a mobile computing device for implementing the functionality of the mobile device in the method, and to a server computing device for implementing the functionality of a remote server function in the method. In addition, the invention relates to an associated communication system.
Along with the overwhelming market penetration of mobile devices such as smartphones and tablets during the last decade, it has become generally desirable to be able to use mobile devices not only as means for telecommunication, but also as tools for facilitating the everyday life of their users. Nowadays, mobile devices are used as miniaturized personal computing devices and also for different services in electronic or physical commerce, consumption of digital content, gaming, social networking, etc.
In various situations, it may be desirable to perform an action when a person is close to a physical location.
For instance, in a retail premise (e.g. shop, supermarket or mall), it may be desired to provide the person with information involving the articles offered at a particular spot in the premises, for instance test reports, fact sheets, culinary recipes, nutritional information, discount coupons, etc.
In an office premise, it may for instance be desired for a person to control office equipment when being in proximity thereof, or to cause placing of an order for a goods which needs to be replenished in the office, or for a service which is required for some office equipment.
In a residential premise, it may for instance be desired for a person to control home equipment when being in proximity thereof, or to cause placing of an order for a goods which needs to be replenished in the household, or for a service which is required for some equipment in the home.
In an industrial premise, it may for instance be desired for a worker to control industrial equipment when being in proximity thereof, or to order spare parts as needed. It may also be desired for an inspector, guard or manager to log checkpoints during a tour in the premise.
In an exhibition premise, it may for instance be desired for a visitor to retrieve information related to different exhibition objects when being near their respective spot of presentation.
In an outdoor scenery, it may for instance be desired for a tourist strolling around the scenery to get information or assistance when passing different attractions.
As a general inventive understanding behind this invention, the present inventors have realized that mobile devices may also be used as tools for causing some activity to be performed depending on a proximity of the mobile device to a physical location in a more flexible and convenient way than in the prior art. The present inventors have realized that there may be several key factors for success in this regard.
Reference is made to
In
Only once the user U has moved the mobile device MD much closer to the physical location PL, i.e. at only a small distance D″, activity shall be caused. This is seen at 2 in
One important factor is locational accuracy; the activity shall preferably only be performed when the user U and the mobile device MD are quite close to the physical location PL. This means that the activity 2 shall not be caused already in the situations shown in
At the same time, speed is of essence. Once the user U and the mobile device MD are proximate to the physical location PL, i.e. have arrived at the situation shown in
Moreover, only a minimum of manual intervention by the user U on the mobile device shall preferably be required in order for the activity 2 to be performed.
As is clear from the above description, the present inventors have identified problems and shortcomings with the prior art. In line with the observations above, the present inventors have identified both the need for and the benefits of causing proximity-dependent activity by a mobile device.
It is accordingly an object of the invention to solve, eliminate, alleviate, mitigate or reduce at least some of the problems and shortcomings referred to above.
A first aspect of the present invention is a method of causing proximity-dependent activity by a mobile device. The method comprises the following steps.
The mobile device receives a first short-range wireless communication signal from a first transmitter function at or near a physical location when being located within a first distance or distance range from the physical location or first transmitter function.
The mobile device reacts to the received first short-range wireless communication signal by scanning for a second transmitter function at or near the physical location.
The mobile device then receives a second short-range wireless communication signal from the second transmitter function when being located within a second distance or distance range from the physical location or second transmitter function, the second distance or distance range being shorter than the first distance or distance range.
The mobile device then causes registration of information contained in the second short-range wireless communication signal.
The mobile device then causes resolving of the registered information to determine an associated activity.
The mobile device finally causes performance of the determined activity.
The first and second transmitter functions may, advantageously, be compliant with Bluetooth Low Energy, BLE, or alternatively with other short-range wireless communication technology. By using such short-range wireless communication technology, only a minimum of manual intervention will be required from the user of the mobile device.
Also, the combined use of the first and second transmitter functions will be advantageous in terms of speed. The first signal from the first transmitter function will serve to prepare the mobile device for things to come, by starting to scan for the second transmitter function. The mobile device will receive the first signal while still being at some distance from the physical location, and when the mobile device moves closer to the physical location, the mobile device will already be scanning for the second transmitter function and therefore be able to react on it quickly.
Moreover, the combined use of the first and second transmitter functions will be advantageous also in terms of locational accuracy. Since the first signal from the first transmitter function will enable the mobile device to react quickly to the second signal from the second transmitter function, this also means that will be possible to have a shorter range for the second transmitter function than what would otherwise be needed. Without the first transmitter function to cause scanning for the second transmitter function, the second transmitter function (in effect then being the only transmitter function) would need a longer range to cut down on the reaction speed by allowing the mobile device to receive the signal sooner (i.e., when still being longer from the physical location).
As will be clear from the following description of different exemplifying embodiments, the inventive approach will also be very flexible and useful for many different kinds of activity to be caused, and in many different situations.
A second aspect of the present invention is a mobile computing device comprising a controller, a short-range wireless communication interface, and a long-range broadband communication interface. The controller is configured for performing the functionality defined for the mobile device in the method according to the first aspect of the invention.
A third aspect of the present invention is a server computing device configured for performing the functionality defined for the remote server function in the method according to the first aspect of the invention.
A fourth aspect of the present invention is a communication system comprising one or more mobile computing devices according to the second aspect of the invention, the first transmitter function as defined in the method according to the first aspect of the invention, and the second transmitter function as defined in the method according to the first aspect of the invention. Advantageously, the communication system may furthermore comprise one or more server computing devices according to the third aspect of the invention.
Other aspects, objectives, features and advantages of the disclosed embodiments will appear from the following detailed disclosure, from the attached dependent claims as well as from the drawings. Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein.
All references to “a/an/the [element, device, component, means, step, etc]” are to be interpreted openly as referring to at least one instance of the element, device, component, means, step, etc., unless explicitly stated otherwise. The steps of any method disclosed herein do not have to be performed in the exact order disclosed, unless explicitly stated.
The disclosed embodiments will now be described more fully hereinafter with reference to the accompanying drawings, in which certain embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided by way of example so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
Reference is first made to
The physical location PL may, for instance and without limitation, be a retail premise (like a shop, supermarket or mall), an office premise, a residential premise (like a private home or a hotel), an industrial premise (like a factory or plant), an exhibition premise (like a fair, gallery or museum), or an outdoor scenery.
The communication system 100 comprises a first transmitter function TX1 and a second transmitter function TX2, both being provided at or near a physical location PL. In the disclosed embodiment, however without limitation, the first and second transmitter functions TX1, TX2 are compliant with Bluetooth Low Energy, BLE.
The first transmitter function TX1 is configured for sending a first short-range wireless communication signal S1 to cause a first reaction R1 when it is received by the mobile device MD when being located within a first distance D1 or distance range DR1 from the physical location PL or first transmitter function TX1.
The second transmitter function TX2 is configured for sending a second short-range wireless communication signal S2 to cause a second reaction R2 when it is received by the mobile device MD when being located within a second distance D2 or distance range DR2 from the physical location PL or second transmitter function TX2. The second distance D2 or distance range DR2 is shorter than the first distance D1 or distance range DR1. For instance, and subject to the needs and constraints of an actual implementation, the first distance range DR1 may be 1-50 m, or more preferably 2-10 m, without limitation, and the first distance D1 may be a distance within the first distance range DR1. Likewise, the second distance range DR2 may be 5-50 cm, or more preferably 10-30 cm, without limitation, and the second distance D2 may be a distance within the second distance range DR2.
As is illustrated in
The mobile device MD is configured for reacting R1 to the receiving of the first short-range wireless communication signal S1 by scanning for the second transmitter function TX2. This is seen in step 310 in
As is illustrated in
The mobile device MD is configured for reacting R2 to the receiving of the second short-range wireless communication signal S2 by causing registration of information WCSINFO contained in the second short-range wireless communication signal S2. This is seen in step 330 in
The mobile device MD is also configured to cause resolving of the registered information WCSINFO to determine an associated activity ACT. This is seen in step 340 in
Finally, the mobile device MD is configured to cause performance of the determined activity ACT. This is seen in step 350 in
The activities in steps 330-350 in
In one or more embodiments, the communication system 100 comprises a remote server function RSF. The remote server function has access to an associated storage RSFDB, as seen at 114 in
An exemplary content of the data structure 103 is shown in
As can be understood from the above, in addition to causing registration of first information WCSINFO1 when the mobile device MD is near a first physical location PL1, the mobile device MD may also cause registration of second information WCSINFO2 when the mobile device MD is near a second physical location PL2, different from the first physical location PL1. After having caused registration of the second information WCSINFO2, the mobile device MD may cause resolving of the registered first information WCSINFO1 as well as of the registered second information WCSINFO2 to determine an associated first activity (ACT1) and an associated second activity (ACT2), respectively.
In alternative embodiments, the mobile device MD may instead be configured to cause the registration of the information WCSINFO contained in the second short-range wireless communication signal S2 (i.e., step 330 in
In embodiments comprising the remote server function RSF, the mobile device MD may be configured to cause the resolving of the registered information WCSINFO (i.e., step 340 in
An exemplary content of the lookup table 104 is shown in
The mobile device MD is also configured for receiving 124, over the broad-band communication network 110, result information RESULT about a resulting match in the lookup-table 104, and for determining the associated activity ACT from the received result information RESULT.
In alternative embodiments, the mobile device MD may instead be configured to cause the resolving of the registered information WCSINFO (i.e., step 340 in
In some embodiments, the determined activity ACT pertains to retrieval 126, over the broadband communication network 110, of digital content DIGCONT from a remote server function RSF to the mobile device MD. This can be seen in
Advantageously, the retrieved digital content DIGCONT may be presented in a user interface 151 of the mobile device MD, see
Alternatively or additionally, the retrieved digital content DIGCONT may be transmitted 128 by short-range wireless communication to a service terminal ST. As seen in
In some embodiments, the determined activity ACT pertains to retrieval, over the broadband communication network 110, of digital content DIGCONT from the remote source RS to the remote server function RSF. The remote server function RSF will store the retrieved digital content DIGCONT in a data structure 105 in the storage RSFDB associated with the remote server function (RSF), together with information 106 linking the stored digital content DIGCONT to the mobile device MD or the user U thereof. As can be seen in the example of
In this way, the user U may build a collection of digital content, which has been retrieved in accordance with the functionality described above with reference to
In some embodiments, the mobile device MD causes performance of the determined activity ACT by requesting, over the broadband communication network 110, the remote server function RSF to execute a predefined function. One example of such a predefined function is the placing of an order for a goods or service.
In alternative embodiments, the mobile device MD causes performance of the determined activity ACT by executing a predefined function in the mobile device MD. One example of such a function is the execution of a protected software application (or protected functionality therein), normally not accessible to the user U. Another example is the playback of prestored digital content in the mobile device MD which has hitherto not been accessible or known to the user U.
In one advantageous embodiment, the physical location PL is in or at a residential premise. A television device, such as a set-up box, cable TV receiver, Internet TV or smart TV, is provided at the physical location PL, in addition to the first and second transmitter functions TX1, TX2. The mobile device MD is configured for receiving current television channel information from the television device. The mobile device MD is moreover configured for registering a current time of day. The mobile device MD causes the registration of the information WCSINFO contained in the second short-range wireless communication signal S2 by communicating said information WCSINFO together with the received current television channel information and the registered current time of day over the broadband communication network 110 to the remote server function RSF. As result, the user U may receive product offerings tailored to the TV contents of the registered current television channel as shown exactly at the registered current time of day. Alternatively or additionally, a TV operator may use the registered information for statistical purposes.
In some embodiments, at least one of the first short-range wireless communication signal S1 and second short-range wireless communication signal S2 is a Bluetooth Low Energy signal. In some embodiments, at least one of the first short-range wireless communication signal S1 and second short-range wireless communication signal S2 is a beacon advertisement signal, as referred to at the end of the detailed description section of this document.
Particularly in such embodiments, the first reaction R1 may comprise switching from a first mode in which the mobile device MD performs monitoring of short-range wireless communication signals to a second mode in which the mobile device MD performs ranging of short-range wireless communication signals. For a brief description of monitoring and ranging, reference is made to the end of the detailed description section of this document.
When in the second mode of performing ranging, the mobile device MD may be configured to determine from the received second short-range wireless communication signal S2 that the mobile device MD is located within the second distance D2 or distance range DR2 from the physical location PL or second transmitter function TX2, and accordingly react R2. In some embodiments, the mobile device MD may start receiving the second short-range wireless communication signal S2 already before the mobile device MD is within the second distance D2 or distance range DR2, then establish communication with the second transmitter function TX2 and range on the second short-range wireless communication signal S2 to decide when the mobile device MD has come within the second distance D2 or distance range DR2.
An improvement in reaction speed is obtained by using the first short-range wireless communication signal S1 (having a longer range) to cause the mobile device MD to enter the ranging mode as preparation of the receipt of and reaction to the second short-range wireless communication signal S2 (having a shorter range).
The remote server function RSF may, for instance, be a server computer, a cluster of such computer devices, or a cloud computing resource or service. It has a processing unit in the form of, for instance, one or more CPUs and/or DSPs, and is programmed to perform its functionality as described in this document by the processing unit executing program instructions of a computer program. The storage RSFDB may, for instance, be a database included in or external to the server computing device. The broadband communication network 110 may, for instance, be a mobile communications network compliant with, for instance, WCDMA, HSPA, GSM, UTRAN, UMTS, LTE or LTE, and the broadband data communication may, for instance, be TCP/IP traffic, possibly encrypted or otherwise secured.
The mobile computing device 150 may, for instance, be a mobile phone, tablet computer, personal digital assistant, smart glasses, smart watch or smart bracelet. The controller 154 may be a processing unit in the form of, for instance, one or more microcontrollers, CPUs and/or DSPs, being programmed to perform its functionality as described in this document by the processing unit executing program instructions of a computer program. To this end, the mobile computing device 150 may have computer program code for an app, or similar program, stored in the memory 152 and executable by the controller 154 to perform the functionality of the mobile device MD. Alternatively, the controller 154 may be implemented as an FPGA, ASIC, etc.
Copies of identity information for the first and/or second transmitter functions TX1, TX2 of the service terminal ST may be stored in the memory 152 of the mobile computing device 150, to facilitate detection (e.g. monitoring, ranging) of the first and/or second signals S1, S2.
In some embodiments, the first and second transmitter functions TX1, TX2 in or at the physical location PL are configured for sending the first and second short-range wireless communication signals S1, S2 at respective defined periodicities. These periodicities may be the same or different.
In some embodiments, the first and second transmitter functions TX1, TX2 in or at the physical location PL are configured for sending the first and second short-range wireless communication signals S1, S2 at respective transmission power levels, the transmission power level of the first short-range wireless communication signal S1 being higher than the transmission power level of the second short-range wireless communication signal S2. In this way, the first distance D1/distance range DR1 is made farther than the second distance D2/distance range DR2.
In some embodiments, the first and second transmitter functions TX1, TX2 in or at the physical location PL are configured for sending the first and second short-range wireless communication signals S1, S2 with respective and different radio signals propagation profiles. For instance, one of the radio signals propagation profiles may be more or less omni-directional, whereas the other of the radio signals propagation profiles may have a narrower directional coverage. This may be advantageous since it may reduce the risk of activating other signal receivers than the intended mobile device MD.
In some embodiments, one or both of the first and second transmitter functions TX1, TX2 is/are separate transmitter device(s) being positioned external to but physically near the physical location PL. Physically near may include one or both of the transmitter devices being mounted at ceiling level or floor level.
In some embodiments, one or both of the first and second transmitter functions TX1, TX2 are implemented by short-range wireless communication circuitry comprised in a communication device 3 (see
In some embodiments, two logical transmitter functions TX1, TX2 may be implemented by one single physical communication device 3.
One or both of the first and second transmitter functions TX1, TX2 may be part of a transceiver function, i.e. they may also have a receiver function.
Even though Bluetooth Low Energy, BLE, is presently considered an advantageous short-range wireless communication technology for the first and second transmitter functions TX1, TX2, other technologies are also conceivable, including but not limited to near-field communication (NFC), radio frequency identification (RFID), wireless LAN (WLAN, WiFi), or another form of proximity-based device-to-device radio communication signal such as LTE Direct.
For embodiments which are indeed based on BLE, the following summary of BLE and beacon technology based on BLE is believed to facilitate the understanding of some embodiments of the present invention.
The iBeacon technology from Apple allows for mobile devices to understand their location on a micro-local scale, and also allows delivery of hyper-contextual content to the users of mobile devices based on their current location. The iBeacon technology is based on the BLE standard, and more particularly on Generic Access Profile (GAP) advertising packets. There are several other kinds of short-range wireless beacon technologies, for instance AltBeacon, URIBeacon and Eddystone, which are also based on BLE and GAP.
In a basic short-range wireless beacon communication system based on the BLE standard, a beacon transmitter device repeatedly broadcasts a short-range wireless beacon advertisement signal in a 31-byte GAP BLE packet. The beacon advertisement signal contains a 128-bit universally unique identifier, UUID. The beacon advertisement signal may also include a 16-bit major portion and a 16-bit minor portion. The beacon signal identifies a beacon region associated with the beacon transmitter device. Whereas, as is commonly known, a geographical region is an area defined by a circle of a specified radius around a known point on the Earth's surface, a beacon region is in contrast an area defined by a mobile device's proximity to one or more beacon transmitter devices.
In some implementations, the beacon region is represented by the UUID, the major portion and the minor portion in the beacon advertisement signal. In other implementations, the beacon region is represented by the UUID and the major or minor portion in the beacon signal. In still other implementations, the beacon region is represented by the UUID alone.
To be able to receive the short-range wireless beacon signal when being within range of a beacon transmitter device, each mobile device is provided with an application program, app, which is configured to detect and react on short-range wireless beacon signals, such as the aforementioned beacon advertisement signal, with support from the underlying operating system. In one known beacon technology, the apps in mobile devices can detect and react on beacons in two ways, monitoring and ranging. Monitoring enables the app to detect movement in and out of the beacon region (i.e., whether the mobile device is within or outside of the range of any of the beacon transmitter devices with which the beacon region is associated). Hence, monitoring allows the app to scan for beacon regions. Ranging is more granular and provides a list of beacon transmitter devices in range, together with their respective received signal strength, which may be used to estimate a distance to each of them. Hence, ranging allows the app to detect and react on individual beacon transmitter devices in a beacon region.
These apps may be handled by the operating system of the mobile device in different modes. The most prominent mode is the active mode, in which the app executes in the foreground and is typically capable of interacting with the user of the mobile device and also to communicate with an external device such as a server via the short-range wireless beacon interface and/or another communication interface. As regards short-range wireless beacon communication, ranging typically only works when the app is in active mode.
When a mobile device receives the beacon advertisement signal, the app in the mobile device may detect that it has entered the beacon region from the UUID (and the major/minor as the case may be) contained in the beacon advertisement signal, and react as appropriate in some way which is beneficial to the user and/or the host of the beacon transmitter device and which often involves interaction between the app in the mobile device and a service provider over a broadband communication network. A system server may also be included in some implementations.
Examples of such beneficial use include, without limitation, determining a current approximate position of the mobile device by retrieving a predefined position of the beacon transmitter device from the service provider or by cross reference with local lookup data, or retrieving content from the service provider.
A mobile device where the app is in active mode is referred to as an active mobile device in this document. An active mobile device may receive and react to additional transmissions of the beacon advertisement signal from the beacon transmitter device; this may be useful for instance if the content associated with the host of the beacon transmitter device is updated or changed.
Furthermore, an active mobile device may receive and react to beacon advertisement signals from other beacon transmitter devices nearby, provided of course that they are within range of the respective beacon transmitter device, or move closer to it. This is so irrespective of whether the different beacon transmitter devices advertise the same beacon region (i.e. contain the same UUID and major/minor in the respective beacon advertisement signals), or different beacon regions (provided that the app is configured to monitor for such different beacon regions). It is to be noticed that the same beacon region (e.g. same UUID) is very often used for different beacon transmitter devices hosted by the same host, such as within the same supermarket, arena, fastfood restaurant, etc.
The operating system of the mobile devices may also handle apps in a passive mode. A purpose of the passive mode is power preservation, since the mobile devices are typically powered by batteries and since it is a general technical ambition to maximize the operational time of a mobile device between successive charging sessions. In the passive mode, the app executes in the background or is only installed on the mobile device. Monitoring works when the app is in active mode as well as when the app is in passive mode, whereas ranging may only work when the app is in active mode, or may only work for a limited time period when the app is in passive mode.
Transitions between active mode and passive mode may be based on user interaction, user preference settings in the app or the operating system, or program logic in the app or the operating system.
A mobile device where the app is in passive mode is referred to as a passive mobile device in this document. In the passive mode, the app typically cannot interact with the user via the user interface, nor communicate with a server or another device—except for the following. Just like active mobile devices, a nearby passive mobile device may monitor for a beacon region and hence receive a short-range wireless beacon advertisement signal if it is within range of the beacon transmitter device in question. However, unlike active mobile devices, the passive mobile device will not be able to use ranging functionality to estimate a distance to the beacon transmitter device.
In some embodiments, the first signal Si from the first transmitter function TX1 serves to cause the mobile device MD to switch from passive mode to active mode, thereby allowing efficient scanning for the second transmitter function TX2 and quick detection and handling of the second signal S2.
The invention has mainly been described above with reference to a few embodiments. However, as is readily appreciated by a person skilled in the art, other embodiments than the ones disclosed above are equally possible within the scope of the invention, as defined by the appended patent claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1850266-6 | Mar 2018 | SE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/SE2019/050198 | 3/6/2019 | WO | 00 |
