INDOOR LOCATION SYSTEM

Abstract

An indoor location system has acoustic wave emitters, electromagnetic emitters, and a mobile device. Each acoustic wave emitter is configured to emit an acoustic wave having an acoustic wave frequency and wavelength, and an electromagnetic signal that includes electromagnetic emitter data related to that electromagnetic emitter and data indicative of a frequency and/or wavelength of an acoustic wave emitted by the acoustic wave emitter that is associated with that electromagnetic emitter. The mobile device is configured to detect the acoustic waves and to receive the electromagnetic signals, and to determine the frequency and/or wavelength of the detected acoustic wave and to compare the determined acoustic wave frequency and/or wavelength with the data included in each received electromagnetic signal, thereby to determine which received electromagnetic emitter data was included in the electromagnetic signal which also included the data indicative of the frequency and/or wavelength of the detected acoustic wave.

Claims

1. An indoor location system for locating at least one mobile device, comprising a plurality of acoustic wave emitters, a plurality of electromagnetic emitters, and at least one mobile device; wherein: (a) each acoustic wave emitter is configured to emit an acoustic wave having at least one acoustic wave frequency and wavelength; (b) each electromagnetic emitter is configured to emit an electromagnetic signal that includes electromagnetic emitter data related to that electromagnetic emitter and data indicative of at least one of a frequency and a wavelength of an acoustic wave emitted by a said acoustic wave emitter that is associated with that electromagnetic emitter; and (c) the mobile device is configured to detect the acoustic waves and to receive the electromagnetic signals, and to determine at least one of the a and a wavelength of a detected acoustic wave and to compare the at least one of the frequency and the wavelength of the detected acoustic wave with the data included in each received electromagnetic signal, thereby to determine which received electromagnetic emitter data was included in the electromagnetic signal which also included the data indicative of the at least one of the frequency and the wavelength of the detected acoustic wave.

2. A location system according to claim 1, wherein each acoustic wave emitter is an ultrasound emitter and each acoustic wave is an ultrasound wave.

3. A location system according to claim 1, wherein each acoustic wave comprises at least one of: a continuous wave having substantially a single frequency and a single wavelength; a plurality of frequencies and wavelengths; a range of frequencies and wavelengths; a chirp of frequencies and wavelengths.

4. A location system according to claim 3, wherein the determination of the at least one of the frequency and the wavelength of the detected acoustic wave comprises the determination of at least one frequency and at least one wavelength of at least one of a plurality, a range and a chirp of frequencies and wavelengths.

5. A location system according to claim 1, wherein each electromagnetic emitter is at least one of: a radio frequency (RF) electromagnetic emitter; a near-field RF emitter; a far-field RF emitter; an electromagnetic inductor; a magnetic inductor; a radio wave emitter.

6. A location system according to claim 1, wherein each electromagnetic emitter is at least one of: a low frequency (LF) electromagnetic emitter configured to emit an electromagnetic signal in the form of a low frequency (LF) signal; a Bluetooth Low Energy (BLE) emitter configured to emit an electromagnetic signal in the form of a Bluetooth Low Energy (BLE) signal.

7. A location system according to claim 1, wherein the electromagnetic emitter data related to each electromagnetic emitter comprises data identifying at least one of that electromagnetic emitter and the physical location of that electromagnetic emitter.

8. A location system according to claim 1, wherein at least one of the location system and the mobile device is configured to determine at least one of the identity and the physical location of the electromagnetic emitter which is associated with the acoustic wave emitter whose at least one acoustic wave frequency or wavelength has been determined.

9. A location system according to claim 1, wherein at least one of the location system and the mobile device is configured to determine the physical location of the mobile device from the determined electromagnetic emitter data.

10. A location system according to claim 1, wherein the location of the mobile device is determined to be the same location as the location of the electromagnetic emitter that emitted the determined electromagnetic emitter data.

11. A location system according to claim 1, wherein the location of the mobile device is determined to be the same location as the location of the acoustic wave emitter that emitted the acoustic wave having the determined at least one acoustic wave frequency or wavelength.

12. A location system according to claim 1, wherein the data indicative of the at least one of frequency and wavelength of an acoustic wave comprises at least one of: a code representing the at least one of the frequency and the wavelength; and data denoting at least one of the frequency and the wavelength.

13. A location system according to claim 1, wherein the association between a said acoustic wave emitter and a said electromagnetic emitter comprises that acoustic wave emitter and that electromagnetic emitter both being substantially in the same location.

14. A location system according to claim 1, wherein each acoustic wave emitter is configured to emit an acoustic wave having a unique at least one frequency and wavelength selected from a plurality of possible acoustic wave frequencies and wavelengths of the system.

15. A location system according to claim 1, wherein each electromagnetic emitter includes, or is in communication with, a sensor, to sense at least one of physical movement and the presence of a person, in the vicinity of the electromagnetic emitter, and configured to activate the electromagnetic emitter.

16. A location system according to claim 15, wherein the activated electromagnetic emitter is configured to emit an electromagnetic signal to activate the mobile device, upon activation of the electromagnetic emitter.

17. A location system according to claim 1, wherein the mobile device is configured to measure at least one of: received signal strength of at least one of the received electromagnetic signals and the detected acoustic waves, to determine at least an approximate distance between the mobile device and the emitter of a said electromagnetic signal or acoustic wave; the time of flight of the detected acoustic waves to determine at least an approximate distance between the mobile device and the emitter of a said acoustic wave.

18. A method of locating at least one mobile device using a location system according to any preceding claim, comprising: (a) each acoustic wave emitter emitting an acoustic wave having at least one acoustic wave frequency and wavelength; (b) each electromagnetic emitter emitting an electromagnetic signal that includes electromagnetic emitter data related to that electromagnetic emitter and data indicative of at least one of a frequency and a wavelength of a detected acoustic wave of an acoustic wave emitted by a said acoustic wave emitter that is associated with that electromagnetic emitter; and (c) the mobile device detecting the acoustic waves and receiving the electromagnetic signals, and determining the at least one of the frequency and the wavelength of the detected acoustic wave, and comparing the at least one of the frequency and the wavelength of the detected acoustic wave with the data included in each received electromagnetic signal, thereby determining which received electromagnetic emitter data was included in the electromagnetic signal which also included the data indicative of the at least one of the frequency and the wavelength of the detected acoustic wave.

Description

[0041] Preferred embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings, of which:

[0042] FIG. 1 is a schematic illustration of a first embodiment of a location system according to the invention;

[0043] FIG. 2 is a schematic illustration of a second embodiment of a location system according to the invention;

[0044] FIG. 3 is a schematic illustration of at least some of the main functional components of an embodiment of a combined acoustic wave and electromagnetic emitter of a location system according to the invention; and

[0045] FIG. 4 is a schematic illustration of at least some of the main functional components of an embodiment of a mobile device of a location system according to the invention.

[0046] FIG. 1 shows, schematically, a first embodiment of a location system 1 according to the invention, in use in two rooms 3a and 3b, of a building. The location system 1 comprises at least one mobile device 5 (schematically shown oversize), a plurality of acoustic wave emitters 7, and a plurality of electromagnetic emitters 9. In particular, in the embodiment shown in FIG. 1, the location system 1 includes a plurality of combined ultrasound and Bluetooth Low Energy (BLE) emitter apparatuses 11, and a plurality of low frequency (LF) emitter devices 13. The ultrasound emitters are acoustic wave emitters 7, and the BLE and LF emitters are each electromagnetic emitters 9. Each room 3a, 3b, contains a respective single combined ultrasound and BLE emitter apparatus 11, and a respective single LF emitter device 13, and therefore each room contains a respective single acoustic wave emitter 7 and a respective single electromagnetic emitter 9 of each of two types (LF and BLE). Although in FIG. 1 a separate apparatus 11 and device 13 is shown in each room, preferably each room contains a single combined apparatus comprising the ultrasound emitter, the BLE emitter and the LF emitter. Alternatively, the ultrasound emitter, BLE emitter and LF emitter may be in separate individual devices, or in any combination of devices or apparatuses. Additionally, each room 3a, 3b preferably contains a respective infrared sensor 15, more preferably a passive infrared (PIR) sensor. The mobile device(s) 5 may, for example, be tags, transponders or mobile communications and/or computer devices (e.g. mobile phones or cell phones), and they may be active and/or passive.

[0047] As described above, each ultrasound acoustic wave emitter 7 is configured to emit an ultrasound acoustic wave 8 having an acoustic wave frequency and wavelength, preferably a single frequency and wavelength of a continuous wave (or alternatively a range, or chirp, of frequencies/wavelengths). The ultrasound acoustic wave emitter 7 of each room 3a, 3b is configured to emit an ultrasound acoustic wave 8 having a unique frequency and wavelength (or alternatively a unique range, or chirp, of frequencies/wavelengths) selected from a plurality of possible ultrasound acoustic wave frequencies and wavelengths of the location system 1. Consequently, each room 3a, 3b has its own unique ultrasound frequency/wavelength. (In larger buildings, the location system 1 may comprise a plurality of system subsets, for example, each subset having a unique ultrasound frequency/wavelength for each room, but different subsets of the system—e.g. groups of rooms in different parts of the building—both using the same series of ultrasound frequencies/wavelengths.)

[0048] Each low frequency (LF) electromagnetic emitter 13 is configured to emit a LF signal 14 that includes LF electromagnetic emitter data related to that LF electromagnetic emitter 13 and data indicative of a frequency and/or wavelength of the ultrasound acoustic wave 8 emitted by the ultrasound acoustic wave emitter 7 located in the same room as that LF electromagnetic emitter 13. For example, the data related to that LF electromagnetic emitter 13 may comprise data identifying that LF electromagnetic emitter 13 and/or the physical location of that LF electromagnetic emitter, for example the room 3a where the LF electromagnetic emitter 13 is located. The data indicative of a frequency and/or wavelength of the ultrasound acoustic wave 8 generally either comprises a code representing the frequency and/or wavelength, or data denoting the actual frequency and/or wavelength of the ultrasound acoustic wave 8.

[0049] (In alternative embodiments of the invention, each Bluetooth Low Energy (BLE) electromagnetic emitter is configured to emit a BLE signal 16 that includes BLE electromagnetic emitter data related to that BLE electromagnetic emitter and data indicative of a frequency and/or wavelength of the ultrasound acoustic wave 8 emitted by the ultrasound acoustic wave emitter 7 located in the same room as that BLE electromagnetic emitter. The data related to that BLE electromagnetic emitter may comprise data identifying that BLE electromagnetic emitter and/or the physical location of that BLE electromagnetic emitter, for example the room where the BLE electromagnetic emitter is located.)

[0050] The mobile device 5 is configured to detect the ultrasound acoustic waves 8 and to receive the LF and BLE electromagnetic signals 14 and 16. Because RF signals, such as LF and BLE signals, can frequently propagate through walls, floors and ceilings, the mobile device 5 will generally receive LF and BLE signals from not only the room where it is currently located, but also from outside that room, e.g. in one or more neighbouring rooms. However, ultrasound acoustic waves are generally unable to propagate through walls, floors and ceilings, and therefore the mobile device 5 will generally detect only the ultrasound acoustic wave 8 emitted by the ultrasound acoustic wave emitter 7 located in the room where the mobile device 5 is currently located (i.e. the same room).

[0051] The mobile device 5 is also configured to determine the frequency and/or wavelength (or range, or chirp, thereof) of a detected ultrasound acoustic wave 8 and to compare the determined ultrasound acoustic wave frequency and/or wavelength (or range, or chirp) with the data included in each LF signal that the mobile device 5 receives. (Or alternatively, to compare the determined ultrasound acoustic wave frequency and/or wavelength with the data included in each BLE signal that the mobile device 5 receives, depending on the system.) The mobile device 5 is additionally configured to determine which received LF (or alternatively BLE) electromagnetic emitter data was included in the LF (or alternatively BLE) electromagnetic signal which also included the data indicative of the frequency and/or wavelength of the ultrasound acoustic wave 8 that the mobile device 5 detected. By “matching” the frequency and/or wavelength (or range, or chirp, or chirp signature) of the detected ultrasound acoustic wave 8 with the particular electromagnetic emitter data which contained the indication of that particular ultrasound frequency/wavelength (or range, or chirp, or chirp signature), the mobile device 5 thereby determines its current room location (because, as explained above, the detected ultrasound acoustic wave 8 will have been emitted in the same room as the current room location of the mobile device 5).

[0052] As indicated above, the mobile device 5 may advantageously also be configured to measure received signal strength (e.g. RSSI, Received Signal Strength Indication) of the received LF and/or BLE electromagnetic signals and/or of the detected ultrasound acoustic waves 8. Such received signal strength measurements may be used to determine at least an approximate distance between the mobile device 5 and the emitter of the LF/BLE electromagnetic signal and/or ultrasound acoustic wave 8. Additionally or alternatively, the mobile device 5 may be configured to measure the time of flight (based on the time of arrival) of the detected ultrasound acoustic wave 8 to determine at least an approximate distance between the mobile device 5 and the ultrasound acoustic wave emitter 7. In order to measure the time of flight of the ultrasound acoustic wave 8, the associated LF and/or BLE electromagnetic signal data needs to include an indication of the time when the ultrasound acoustic wave 8 is emitted. Advantageously, the location system may be configured to use such at least approximately determined distances to assist, and/or to check for error, in the determination of the physical location of the mobile device(s), for example.

[0053] A preferred mode of operation of the location system 1 will now be described. When a person enters a room (e.g. room 3a in FIG. 1) carrying a mobile device 5, the infrared sensor 15 senses the motion of the person and activates (“wakes up”) the emitters 7, 9, 11 and/or 13 from a dormant and/or low-power mode of operation. The low frequency emitter 13 then emits a LF (e.g. 125 kHz) signal 14 to activate (“wake up”) the mobile device 5 from a dormant and/or low-power mode of operation. The low frequency emitter 13 also emits a LF signal 14 that includes LF electromagnetic emitter data related to that LF electromagnetic emitter 13, data indicating the frequency or wavelength of the ultrasound acoustic wave 8 emitted (or to be emitted) by the ultrasound acoustic wave emitter 7 located in the same room as that LF electromagnetic emitter 13, and optionally data indicating the time when that ultrasound acoustic wave 8 will be emitted. The data related to that LF electromagnetic emitter 13 preferably comprises data identifying that LF electromagnetic emitter 13, and at least comprises the room 3a (or, more generally, the physical location) where the LF electromagnetic emitter 13 is located. The BLE emitter preferably also emits a BLE advertisement signal, and the ultrasound acoustic wave emitter emits a single frequency/wavelength continuous wave ultrasound acoustic wave at the frequency/wavelength designated for that room 3a, and as indicated in the LF signal.

[0054] The mobile device 5 performs the following procedure. The mobile device 5 receives the LF and BLE signals, and any other LF and BLE signals that may have propagated to that room 3a from one or more other rooms or locations in the building. The mobile device 5 also detects the ultrasound acoustic wave 8 emitted by the ultrasound acoustic wave emitter 7 located in the room 3a that the person carrying the mobile device 5 has entered. The mobile device 5 measures the RSSI of the received LF signal(s) (and preferably also the RSSI of the received BLE signal(s)), measures the RSSI and/or time of flight of the ultrasound acoustic wave 8, and determines the frequency or wavelength of the ultrasound acoustic wave 8. The mobile device 5 determines which received LF electromagnetic emitter data was included in the LF electromagnetic signal which also included the data indicating the frequency or wavelength of the ultrasound acoustic wave 8 that the mobile device 5 has detected, and the mobile device 5 thereby determines its current room location from the room location data contained in that LF electromagnetic emitter data. The mobile device 5 also carries out an error-checking procedure of determining at least approximate distances to the various emitters whose RSSI and time of flight it has measured, to check whether or not its room location determination is consistent with such measured distances. If an inconsistency is found, this procedure may be repeated until a consistent result is obtained. Finally, the mobile device 5 preferably reports its location (e.g. via Wi-Fi™ or BLE) to a location engine (e.g. a server) of the location system 1.

[0055] FIG. 2 is a schematic illustration of a second embodiment of a location system 1 according to the invention, which is a variation on the first embodiment of FIG. 1. Like reference numerals indicate like, or functionally similar, features and components. In the embodiment of FIG. 2, each room 3a, 3b, contains a pair of ultrasound acoustic wave emitters 7a, 7b configured to direct ultrasound acoustic waves in different directions to each other. One ultrasound acoustic wave emitter 7a in each room 3a, 3b is configured to direct ultrasound acoustic waves 8a into the room, and the other ultrasound acoustic wave emitter 7b in each room 3a, 3b is configured to direct ultrasound acoustic waves 8b to an entrance/exit 18 (e.g. a doorway) to the room, as illustrated. The mobile device 5 is configured to measure the received signal strength and/or the time of flight of the detected ultrasound acoustic waves 8a and 8b to determine at least an approximate distance between the mobile device 5 and each ultrasound acoustic wave emitter 7a, 7b of the pair. The mobile device 5 preferably is configured to carry out the distance determination a plurality of times, and the location system 1, e.g. the mobile device 5, preferably is configured thereby to determine at least an approximate direction of movement of the mobile device 5 relative to the ultrasound acoustic wave emitters 7a, 7b of the pair. This preferably enables the determination of whether the mobile device 5 (and hence a person carrying the mobile device 5) is entering or exiting the room.

[0056] FIG. 3 is a schematic illustration of at least some of the main functional components of a preferred embodiment of a combined ultrasound acoustic wave and electromagnetic emitter of a location system 1 according to the invention. The combined emitter comprises a passive infrared receiver (PIR) 15, an ultrasound (US) receiver 17, a BLE directional antenna 19, a LF receiver 21, a microcontroller (MCU) and BLE unit 23, a LF circuit 25, an ultrasound (US) transmitter 27, and a power management unit 29, preferably including one or more batteries. The ultrasound receiver 17 is for noise immunity; it “listens” to the environment around it and preferably enables the selection of an appropriate and/or optimised ultrasound frequency/wavelength to be emitted, preferably dynamically and automatically. The LF receiver 21 preferably is for emitter-to-emitter communication.

[0057] FIG. 4 is a schematic illustration of at least some of the main functional components of an embodiment of a mobile device 5 of a location system 1 according to the invention. The mobile device 5 comprises an ultrasonic (US) microphone 31, a LF receiver 33, a microcontroller (MCU) and BLE unit 35, an optional Wi-Fi™ unit 37, and a battery 39.

[0058] It will be understood that the above description and the drawings are examples of particular implementations of the invention, but that other implementations of the invention are included in the scope of the claims.