When different kinds of area specific positioning techniques develop, more and more useful applications are found.
On the market have been on sale RFID-antennas (Radio Frequency IDentification), which limit a controlled area by RF (Radio Frequency) radiation pattern to a certain area, in which limited RF area arriving mobile devices i.e. TAGs can be identified. The mobile device is by nature a RFID tag, which does not need a current consuming active front amplifier in a RF receiver of the TAG as it operates in RF near field based on passive signal detection not becoming active before it arrives to an area of signal of sufficient strength, when it preferably and immediately can measure directly the coming signal without a load of the front amplifier, which load could be for example about 10 mA.
In this technology, such as access control applications, the problem has been the fact that precisely in the location of the interior roof of the controlled building where the antenna would most advantageously locate, it is very often the lamp. In other words, the location of the lamp would be just the best antenna location or even the only good location. In addition, the problem is that the lamps are often metal from outside i.e. from the sides, and thus they can easily distort the radiation pattern of the RFID antenna installed beside. Thus, the antenna should be able, if necessary to replace the lamp when the antenna is to be positioned to the place reserved by the lamp.
Another major problem, especially in the traditional RFID positioning has been the fact that if is wanted positioning with exact limits in a small space, taking into account movement direction, two antennas have to be installed, which often require their own readers, and whose radiation patterns interfere with each other without special arrangements. Especially when broadcasting at the same time, the radiation patterns suffer from bad interferes. In narrow places the antennas often must be placed near metal structures, such as door constructions, or pipes, which also cause distortions to radiation patterns, and for example at about 50 cm distance, can even destroy the radiation pattern.
Even if the antennas are fitted into a small space, signals are received from both antennas of the interface. In this case, without any special arrangements, area changes all the time when new signals are received even when being in place, unless the signals are measured and a TAG position is evaluated on the basis of calculations and judgements at each time point as in the patent application publication FI20095222 is presented.
The problem to automatically send a location-based emergency call on the basis of abnormal health status of a person for example in the case of downfall is that an accelerometer should in principle be measuring all the time when a hit possibly indicating the downfall becomes until at the end of the accelerating when the measurement is already too late. On the other hand, all downfalls due to worsened health status are not sudden, but a person can also be slowly and cautiously falling to the floor, when the head begins to spin. On the other not only the horizontal position could be used as an indicator, because the horizontal position is also in normal situations, at least in bed.
The object of the invention is an advanced antenna technology embodiment as one positioning cell of a positioning system, where antennas and radiators can be located to as good locations as possible and having close distances between them so that said close distance or other metal structure causes no interferences in the positioning technology or neither simultaneous operation of the antennas or radiators causes interferences in the positioning technology. This is achieved by an active positioning system for positioning at least one mobile device by utilizing radio frequency technology, the positioning system comprising at least one essentially stationary fixed base station i.e. an active positioning system antenna, and an electronics unit i.e. a transceiver of the antenna, which transceiver comprises at least one antenna for transmitting signals comprising at least position information to at least one mobile device, which position information of the signals comprises information on an effect area of the antenna by using certain transmit power, which effect area of the antenna is dividable on two or more sections based on power measurement, calculation and/or judging. The active positioning system comprises as the mobile device a TAG, which is fixed to the user or application of the TAG directly or indirectly, an electronics unit of the base station, at least one antenna directed to different sections of a controlled area, and, if necessary, at least one external antenna to divide the controlled area to sections and to transmit additional information signals comprising antenna specific limit and control values to the mobile device i.e. the TAG in addition to transmitting signals comprising position information, and said TAG comprises at least one antenna to receive said signals and additional information signals transmitted by at least one antenna, and the TAG comprises at least one electronics unit to form measurement signals and information signals based on said signals and additional information signals received by the antenna for performing information processing of TAG position, and TAG comprises said at least one antenna to transmit at least one of the formed measurement signals and information signals to the active positioning system, which comprises said base station to receive said transmitted at least one signal of the formed measurement signals and information signals, and the positioning system comprises control means to control transmit power of said at least one antenna based on at least one signal of the formed measurement signals and information signals received at least by the base station for performing information processing of the mobile device position i.e. the TAG position at least based on transmit power level.
The invention is based on time division of signals used in the positioning and on dividing the controlled area to different parts and on functional effectivity in the co-operation of positioning system technology such as antennas, radiators and the electronics units to utilize said time division and area division.
The benefit of the invention is so preferred relocation as possible of antenna technology used for positioning as possible. According to the invention is also compensated for successfully out the main sources of error, which have been problems of prior art.
The active positioning system antenna according to the invention, i.e. the active antenna can also in one embodiment replace a lighting unit, which has been unfortunately located in buildings in just those places where the placement of positioning system antenna is optimal.
For example, the positioning system antenna according to the invention integrated with efficient LED technology (Light Emitting Diode) lighting is feasible with so low current that a lamp can in power outage situation, act as emergency exit lighting supplied by own battery or batteries or supplied by some external certified current source or voltage source.
According to the advanced antenna and tag technology according to the invention can also improve the functionality of the prior art solution in positioning, where the mobile device TAG sends a beacon signal and the base stations measure the RSSI value of the incoming signal, and try calculatively on system level to determine the location of the TAG.
The main benefit will be that the active antenna with several radiators is able to determine the direction where the signal comes from and can together with step measurement of TAG and with electronic compass-based measurements define the TAG location without a base station network, which is required in conventional triangulation-based systems without removing still the possibility to further improve the positioning accuracy by co-operation of network of several active antennas utilizing for example triangulation. Electronic compass solution of TAG enables utilization of TAG attached to the user's body or clothing to detect position of the user in at least three coordinates (x, y, z), which feature together with TAG informing the person being in bed based on, for example, the bed weight and/or on measurement of movement in the bed, at least together with positioning information provided by the system enables an automatic information transmission of an abnormal situation in which a person is in a horizontal position outside of his bed.
According to the implementation of the invention is carried out positioning of at least one mobile unit, i.e. a TAG 100 in a positioning system area by an active positioning system antenna 101 utilizing RFID-technology (Radio Frequency IDentification) radio frequency technology in the region of the system according to the invention. Tag in this patent application does not necessarily mean any standards compliant device or device part, but a device that is attached to a monitored, at least intermittently, moving and stationary target. As an antenna is used for example, a direction antenna 202 or a message traffic antenna to reception and/or broadcasting in RF frequencies. When an antenna has a name radiator 102, 104, it is then emphasized the fact that the radiator is used primarily to broadcast signals, but the radiator is, therefore, also the antenna, which can be used, when necessary, for both signal transmission and reception tasks.
A very preferred solution when aiming to small size is to locate for example an entity of two antennas 202 to the same casing so that two separate radiators 102, 104 performing corresponding function are installed to the same casing. In this case, the outer dimensions of the solution are obtained to smallest possible levels, and manufacturability of the product is as simple as possible. Also the base station electronics 106 is then very preferably installed inside the same antenna casing.
The active positioning system antenna 101 comprises a lighting arrangement integrated or attached to an electronics unit 106 of the antenna 101, said lighting unit being preferably accomplished by LED technology 132, 134.
An active positioning system antenna, i.e. an active antenna 101 can replace a lamp, which is interfering the antenna, and for example two separate antennas and the RFID-base station, enabling said RFID control package for the installation of a very small space, and also situated in the most preferred location area of area limitation and operability of the passage control. The active antenna 101 can also be in a high room lowered to a suitable height with a wire of the antenna such as it can be done with a normal lamp.
In demanding projects the active positioning system antenna 101 comprises one or more antenna operating in time-divided manner attached to the electronics unit 106 of the antenna 106 with an external cable to obtain essentially clear area distinction.
The active antenna 101 comprises one or more radiator 102,104, which is connected to, or more preferably integrated into the electronics unit 106. The radiators are connected most preferably to a common end amplifier time-divisionally so that the radiator, which is not connected, represents a high impedance, at least with broadcast frequencies, when said radiator is not radiating, i.e. transmitting.
The radiators are separated from the amplifiers by RF switches so that each radiator in turn is in connection to own amplifier or to a common end amplifier of the radiators. An area monitored by locating and directing one or more of the external antenna 202 and/or the radiators 102, 104 is divided into one or more sub-areas, especially when it is wanted to distinguish essentially clearly these sub-areas from each other.
The mobile device, i.e. the TAG 100 knows on the basis of RF signals transmitted by one or more of the radiators, or by an external antenna, the area of the radiator or the antenna, which is involved at each time point. The active antenna 101 can through one or more external antenna 202 and/or internal radiators 102, 104 send additional information to TAG, such as antenna and radiator specific control values on the basis of which the TAG will be better able to calculate and/or judge current location. TAG 100 comprises at least one antenna 103 to perform RF-transmission/reception tasks and and an electronics unit 110 for measurement of said signals received and for processing on the basis of additional information received via the antenna and/or stored in its memory.
The positioning according to the invention is performed so that a mobile device, i.e. the TAG 100 in the interface receives via one or more of the antenna 202 and/or the radiator 102, 104 signals, the intensity of which the mobile device self-measures and/or counts amount of said signals per time unit, and calculates and/or concludes by using different kind of algorithms on which area expressed by positioning signal transmitting antennas or radiators the TAG 100 is at each time moment. In this a crucial benefit is that the mobile device 100 itself measures the signal strength and processes it mathematically and logically so, that it is comparable to signals received by other radiators and/or antennas. The interface is to be set and changed also programmatically. These matters enables the area interfacing to operate reliably in a very small space, since in this antenna and/or radiator signals may extend overlapping each other's areas.
The invention is based on the internal radiators 102, 104 of the active postioning system antenna, i.e. the active antenna 101, directed at different points of the monitored area and/or one or more of an external antenna 202 cable connected to the active antenna electronics unit 106 sends by using at least one radiator limit and adjusting values, which are radiator specific comprising the additional information signals time divisionally in addition to spatial information containing signals. The mobile device, i.e. the TAG 100 receives said signals sent by the external antenna and/or internal radiator to process location information of said mobile device and to form measurement signals, which measurement signals and/or the processed values of them the mobile device 100 may, when necessary, send to control means comprised by the active positioning system antenna 101, when at least in the so-called learning situation radiating efficiency of the at least one of the radiator and/or the antenna is controlled situation specifically on the basis of said measurement signals and/or processed values of them so that the processing of mobile device location information is specified at least based on the level of radiating efficiency. At the same time can be perform filtering and create on the basis of them parameters to be send to the mobile device, to avoid error values existing in some awkward positioning coordinates caused by positioning signal distortions in influencing the location information processing of the mobile device.
An processing part of the active positioning system antenna or active antenna 101 memorizes at least in configuration and in learning situations the values and parameters received by the TAG 100 and possibly further processed values and parameters by the processing part as radiator 102, 104 specific values or in the case of an external antenna 202 as antenna specific values, and sends this information as additional information in addition to signals containing location information to all other mobile devices 100 of the system at least when they move onto the area of said positioning cell.
In an implementation according to the invention external antennas 202 and internal radiators 102, 104 are to be placed close to each other, as they are, or at least some of them, time divisionally asynchronously working, so that their fields do not interfere or even cancel each other out. This time divisional is formed preferably by using an RF switch arrangement, when one and the same power amplifier is preferably used in transmission operation of several radiators or antennas.
However, the mere time divisional is not yet sufficient to allow normal structured antennas 202 and radiators 102, 104 to be placed very close to each other, because without special arrangements a very close second antenna, or radiator causes radiation loss of first antenna, at least by distorting the radiation pattern. Very close places mean in this for example such places of antennas and radiators that the antennas with each other or the radiators with each other or both the antennas and radiators with each other, each depending on the implementation, are placed 2 mm-60 cm apart from each other. Transmission of antennas and/or radiators, which area placed very close to each other is important to have different timings at least time divisionally, and in addition antennas and/or radiators which are not transmitting should very preferably be electrically disconnected from the antenna or radiator which is transmitting during the transmission time, in other words should represent a very high impedance to the transmitting radiator 102, 104 and to the antenna 202 being at close proximity, at least when aiming at small outer dimensions of the entity. In this way, the antennas and/or radiators do not interfere each other's signals.
The specially designed radiators, such as the CAN antennas (English name comes from a can-shape), is to be one application form of an active antenna, in which can be achieved radiator specific directivity and without interfering each other with certain arrangements so that other radiators need not to be electronically disconnected when one radiator is transmitting, but at least outer dimensions of the solution become large compared to the smaller radiator solutions who benefit from the disconnections performed by the RF switches.
In the embodiment according to the invention is also achieved as a significant advantage a low power consumption of the TAG 100, due to the fact that the TAG do not need a RF pre-amplifier. Indeed, in the prior art embodiment, when using the RF pre-amplifier, the power consumption is easily up to 10 mA range. In the embodiment according to the invention, the TAG is able to passively indicate a strong time divisional signal of the active positioning system antenna 101, which is in practice an RFID base station with antennas, and the TAG is able to wake up from sleep mode, when duration of the indicated signal exceeds a preset threshold, and then TAG begins to process the indicated signal. After this, the TAG will move back to sleep mode to wait for a new signal. In one embodiment of the invention, the TAG waits for a signal to its movement indicator, after which the TAG 100 only allows awakening to the positioning signal, or to start a positioning signal processing.
In the processing according to the invention a mobile device 100 utilizes a motion sensor 153 to conserve power at least by step measurement principle by rejecting repeated similar values when being in a place, or even by refusing to measure them at all, thus sparing energy in its battery.
The active antenna electronics unit 106 may further comprise at least one RFID transceiver with its processing units i.e. in practice realize the use function of a base station comprising at least one radiator to send signals containing at least location information to art least one TAG. In this case is not required a separate base station, but all base station operations are located in a same casing, i.e. in a package. In this case, one active antenna 101, which may comprise one or more radiators 102, 104 operating time divisionally at different times, is able by itself, at least with more of the radiators, to perform an effective area limitation in a very small area the same way as if it were two separate antennas in different locations. This embodiment enables in addition one or more external antennas 202 to be connected to the active antenna, which allows the positioning area for example to be widened to cover effectively bigger passageway.
In RFID passage control is also beneficial to create also other abilities to the active antenna electronics unit according to the invention, such as perform on the monitored area measurements by an infrared (PIR, Passive InfraRed), 133, 135 and/or ultrasound (US) motion detector, and also/alternatively, if necessary, to use the IR (InfraRed s) and/or ultrasound to communicate with TAG.
In this case, the active positioning system the antenna comprises of a motion detector combined to its electronics unit 106 externally of the casing or internally of the casing, most preferably a motion detection component integrated to the same printed circuit board with the electronics unit 106, the operation of which component is based on utilization of at least one of techniques for infrared technology PIR 133, 135 and ultrasound technology and microwave technology, and detection area of said component is most preferably overlapping with the area limitation performed by the radiators 102, 104, the solution then surely ensuring detection of non-permissed person on the detection area on the basis that the person is not having a TAG 100, which would transmit to the system a permissed access code and/or identification information when entering the positioning area of the cell.
The active positioning system antenna 101 comprises at least data communication connection arrangement 121, 125 connected to its electronics unit 106 and most preferably integrated to to the circuit board to deliver data between the active positioning system antenna and the outside world.
Thus to the same active antenna according to the invention is, when necessary, preferably integrated voice and/or an IP connection to the outside world, for example, by using at least one GSM/GPRS/3G/CDMA, WLAN/WiFi/WiMAX/Flash-OFDM/W-CDMA- to implement a module 125 and/or wired by using at least one of techniques phone/modem/ISDN/ADSL/VOIP/USB/Ethernet to implement a module 121.
In this case, preferably is avoided problems caused by acoustic feedback, and in the loudspeaker 111 can, if necessary, be used high volume levels, when the microphone 138 and the loudspeaker 111 are far apart from each others.
In some applications, the active antenna 101 is able to operate the wired communication with the outside world, by using one or more of common Ethernet, RS-232, and for example, units and communication protocols in accordance with USB and RS485/422—x.0 standards for example when joining a passage control system of a building. For this purpose the device comprises one or more wired telecommunication module 121 as a separate and/or the equivalent electronics integrated directly to the circuit board 127.
Both control means of the TAG 100 and the active antenna comprise preferably programmable processor technology, such as PLC (Programmable Logic Controller), to carry out its measures, such as, for example, to form measurement signals in the TAG and to perform control operations of radiating efficiency by the control means.
In the preferred embodiment of the invention the active antenna may comprise at least one antenna, which is a separated antenna from the actual positioning system antennas, by which is carried out an RF signal transmission and reception to other purpose of use than the positioning. This is carried out preferably in such a way that the transmission and reception can be mutually independent on their own frequency range.
The antenna is required in some applications only to other radio frequency communication, because the RFID radiators can not receive well outside of their radiation patterns because of their directivity. In one preferred embodiment the antenna is connected or integrated the connection cable 109 of the active antenna.
The active positioning system antenna can be placed in its most preferred location for example, so that it is accompanied by an integrated lighting arrangement, in which case both, as well as a lighting unit and the active positioning system antenna, may realize their use function in a preferred location, such as for example in a lobby room of the building.
The active antenna comprises at least one RF switch available to each of the radiator, or an external antenna in turn and/or selectively at the same time being connected to one or more power amplifier, and a removable radiator 102, 104 of the isolation embodiment and/or an external antenna 202 to be galvanically so isolated that said radiator 102 or external antenna 202 becomes a high impedance object in respect to one or more other radiator 104 and/or external antenna.
The RF switch electronics can be preferably implemented in one or more integrated circuit, each of which comprising one or more of the RF switches.
The RF switch solution in the active antenna electronics unit 106, which is used for connecting the radiators, can also be used for adjusting electrical length of them and other parameters such as a reflectivity, and at least the ground level size and/or shape in order to change active antenna characteristics depending on the situation and time moment needs so that transmission frequency and radiation pattern of the radiators can be altered so that operation of the solution suffer significantly. For example, transmission frequency and directivity can differ greatly from receivement frequency and directivity.
The active positioning system antenna may be developed in the preferred embodiment also in such a way that to the active antenna is connected or integrated a motion detection component, which is preferably based on simultaneous utilization of infrared technology PIR 133, 135 and ultra-sound, or on utilization of at least one of them. Active antenna 101 can also be connected to data communication connection arrangement 121, 125 to deliver data between the active antenna and the outside world, i.e. other devices and/or data communication networks. Data communication connection arrangement to outside world can also be connected to or integrated with other parts of the active antenna such as for example the control means. The active antenna may also comprise means for sound reproduction and for at least two-way voice connection. As means for sound reproduction can be at least one of a speaker 111 and a microphone MIC 138, and at least one of said means can be located to the mobile device, i.e. to the TAG 100, which has a telecommunications link to at least one antenna of the positioning system antenna 101, and thus possibly also to the outside world. For example, at least one microphone 139 may be located in a TAG locating in the telecommunications link area, and be connected to at least one antenna of the positioning system antenna.
In the preferred embodiment of the invention can be utilized a connection realized by articulated joints, by which connection the direction radiator is connected to its electronics unit 106 to utilize said articulated joints in directing of the direction radiator 102, 104. The articulated joints 118 can be as simplest be freely bending strip made from metal or from other suitable material, which connects the radiator module to the body structure of the casing formed by the electronics unit 106, ground level or to the circuit board 127.
In addition that the multi-radiator solution achieves in the RF near field a good area selectivity, can the solution be used effectively in improving the long-distance field positioning, so that the TAG 100 itself sends a beacon signal after leaving the local field and the active antenna measures from a signal it receives a RSSI (Received Signal Strength Information) value by each of its radiators and/or antennas.
The active antenna is able to measure from the TAG 100 signal RSSI (Received Signal Strength Information) value by each of its radiators 102.104, and/or antennas 202, and it gets the biggest measure from the radiator 102, 104 and/or the external antenna locating in the best direction as seen from the TAG 100 and from the others correspondingly smaller measurement values in relation to value of angular deviation of their direction from the best direction.
For example, a solution of four radiators achieves a very high selectivity for the direction compared to normal solutions, where single antenna cannot provide any information about the beacon (TAG 100) direction. In a preferred embodiment of the invention according to direction selectively a single radiator is structurally independent radiator module with directional antenna 102, 104 capabilities, in which case its radiation pattern has a good front/rear ratio (eg 10 dB) when it receives the signal coming from behind at a 10 dB lower level than the signal coming directly from front.
TAG sends step detection as seldom as possible to minimize power consumption and most preferably also step measurement by utilizing for example piezo motion detector 153. Most preferably the motion sensor is carried out in connection with a shock sensor 151, in which case the combination of the sensors is adjustable for different sensitivity settings.
Step length of the distance travelled can be re-calibrated each time when a person passes through a near field comprising known dimensions, which are already being formed by an active cell of the active antenna. In this role, the active positioning system antenna to notifies the tag of the boundaries and/or the dimensions formed by the radiation field at least based on radiation intensities of its radiators 102, 104, and of any of its external antennas 202, 204, and if necessary, for example, utilizing data given by an IR or ultrasound radar. The method increases after the calibration measurement accuracy in assessment of distance travelled by the TAG.
By this advanced step measurement method can in addition be better assessed person's energy consumption, especially when also the person's body weight is known.
In one application of the system, in an electronics unit 110 of the TAG 100, which sends beacon signal and performs step measurement is preferably a an electronic compass solution 152 to measure direction of travelling in addition to measure number of steps, when the positioning can be performed even in a nearfield of a cell formed by a single active antenna 101, when the TAGs direction of travelling is known when it exits from the near field of the positioning cell formed by the active antenna 100, information of the compass direction and of the travelled distance sent by the TAG 100 and strength information (RSSI) of the beacon signal sent by the TAG 100, which is preferably obtained, while the TAG 100 sends said step measurement information and direction information.
TAG sends rarely its data and a beacon signal in order to minimize power consumption, only when its location changes significantly, or because of any event recognized by its operation logic. The implementation of electronic compass 152 is most preferably based on an integrated circuit solution, i.e. on an electronic compass circuit.
Positioning in a system based on one or more of the active antennas and TAG performing step and direction measurement can be further improved by placing over the doors of lanes fixed installations versions of TAG 100 of the system, type Door-TAG, which identifies for example, a distance change of a magnet attached to a door in relation to the location of the TAG most simply based on a reed switch, or in a sophisticated version the magnetic field is measured by a sensor, which allows a greater detection range to place the TAG more freely. Said sensing element may preferably be even the same sensor, by which the compass of the mobile TAG 100 is implemented.
Thus, the system receives the information of the room door which has been opened in the hallway at the same time, while the TAG 100 is moving in said direction. Event detection logic is improved by the TAG information that stepping has stopped and/or that direction has changed at the same moment, when the door-TAG indicates the event. On the basis of said information the events can be logically combined by a very high probability and do so quite reliably accurate positioning to the room in question. At the same time the system will automatically certify tracking information as RSSI measurement values from the TAG in said room without separate “site survey”-type system teaching, which has to be made in the traditional systems when taking the system into use.
In addition, beacon signal measurement values obtained by the active antenna can be statistically processed and over time can be detected readings on the basis of measurement values, which refer to said person's general places of location, including workplaces, bed, toilet, etc., that information can be used in the automatic learning of the system, still without a need for “site survey” type teaching. Additional value to Door-TAG investment in a building is for example in a emergency call application, when the same door-TAG indicates preferably, e.g. by voice and sign light flashing above the door of the room where a person needing assistance locates in the corridor after the person has called help by his alarmTAG, making it easier and faster to get help.
The electronic compass solution 152 of TAG 100 allows utilization of a TAG 100 attached to the user body or clothing in at least three coordinates (x, y, z), which feature together with information of TAG measurements of bed weight and/or of movements in the bed and at least together with positioning information updated by the system implements an automatic notification of an abnormal situation, where the user is in a horizontal position outside of his bed.
The TAG according to the invention is able to, in a particular application with the aid of an electronic compass 152 and a shock sensor by using suitable program algorithms, to detect, for example, that the person carrying it falls down or other abnormal behaviour and is able to inform this by its radio part at least to the active antenna, which by its telecommunications means forwards this information without limitations, by using wired or wireless communication. If necessary, detection accuracy of a fall down situation can be improved by use of an acceleration sensor of the electronic compass circuit, for example, AK8976A, acceleration sensor, or by use of a separate acceleration sensor, if the electronic compass circuit of the application is not able to measure acceleration.
In a very preferred embodiment of the invention to detect fall down situation use of the traditional “acceleration, followed by a hit, and horizontal position” measurement procedure is even unnecessary, even when as a condition for fall down notification is used only horizontal position of the person and information that the person has left his bed. This ensures that a error alarm is not given when the person goes normally to sleep in a horizontal position. Similarly, when a person to lies down, though very slowly, as in the case of sick incident can occur, and the matter may be reported immediately at least as abnormal event, in such as work safety or patient safety control related applications.
In addition, the method related to identification of the horizontal position forgives in energy budget of the battery of the TAG 100 the user holds so that the acceleration measurement need not hurry with situation processing, because for abnormal event indication is sufficient that the person has left the bed and is in a horizontal position.
The sequence of events is problematic for the use of acceleration sensor, because the triggering to the situation is only got from the hit, which wakes up the TAG to measure, when the acceleration sensor should have been connected to measure already before the hit, which means in principle, constantly, if it should be able to express such an event. As IC technology advances, the power consumption problem of acceleration measurement is diminishing, and with new circuit solutions, such as for example the Analog Devices ADXL346 chip can be up to continuously measure with power consumption, which according to the manufacturer is only 23 uA. It is then possible with one acceleration sensor, in addition to detect fall down situation, perform other functions such as the identification of hit, which functions would otherwise require their own sensors for and programs. Also the step measurement can be performed in the same circuit, such as by the above-mentioned Analog Devices ADXL346.
For the detection of fall down the TAG should be attached to the body, such as e.g. pulse counter, so that the horizontal position of the body can be indicated with certainty. Also with an appropriate way to clothing or headgear attached TAG 100 is able to indicate the position of the body and depending on the application the alarm can be conditioned to avoid error alarm with other measurement or feedback data, such as the person is not moving, or is passive, or lack of response to such as loud generated by a TAG piezo membrane 151, or to generate vibrations from a vibration element which is familiar from the mobile phone. In this bed control task is a preferred TAG 100 embodiment of the invention, a bed-TAG_1100, where the hit sensor 151 of
The TAG may also send information about the person's movement in bed during the night, for example on the basis of signals from a piezoelectric movement sensor 153 located in the same unit, if the TAG's weight/pressure-measuring sensor 151 is unable to adequate sensitivity.
A preferred bed-TAG versio2 may be nearly the same as normal TAG 100 according to the invention, which needs to have only sensitive motion sensor, for example, piezoelectric, when it for example below a mattress, indicates and identifies motion and/or pressure against the mattress, said data together with positioning information is sufficient to guarantee a reliable indication of the bed conditions. To the tag can also be attached a bed sensor, for example Emfit Bed Sensor, which is normally located under the mattress and commonly available.
At best, the TAG may send the collected kinetic measurement data as time series, for example, in one or more package in RF at specified time intervals to minimize power consumption, in which case the receiving active antenna can transmit the data for example to PC, where it can be viewed as a graphic activity curve also through a browser and remotely.
The drawing of the activity curve continues, if necessary, as when the person is away from the bed the carried TAG 100 operating the same way as the bed-TAG 100, at least based on the measurement results of the motion detector, By this way drawing of the activity curve can operate around the clock, even if the person took off the carried TAG.
The mobile TAG can also store measurement information during the day while being out of reach of the active antenna and process the stored measurement data when re-entering the range area.
Since for the detection of fall down the TAG 100 is already attached to the body, e.g. such as pulse counters, it can also be conveniently measure by heart rate by its motion detector, which information it can send for example to pulse counter wrist with an appropriate protocol in addition to that heart rate data is sent with other information to the active antenna. Pulse is obtained as activity curve and the curve of energy consumption in the corresponding graph, to eg a PC or most simply as a numerical figure to the active antenna 101 connected is play device.
Energy consumption can be estimated fairly accurately, when the heart rate, distance/pace and the person's weight is known, which weight can be measured if desired automatically by bed sensors, by installing under all legs of the bed corresponding tags, and on the basis of reported measurement values from said tags for example the mobile TAG 100, or the active antenna 101 can calculate a common weight of the person and the bed and reduce the weight of the bed, which can be measured when the positioning notifies the person to be far away from the bed. By this tag solution can be implemented even up to a passive observation of person's weight variation and a person's weight curve can be represented graphically in a time domain with other curves which function is of significant benefit for example in monitoring effects of medication dispensing in a person being in diuretic medication.
As additional information on verifying the person being in the bed, the active antenna can utilize the automatically learned location information of the bed, which information together with weighing of the bed significantly makes faster to give an automatic alert of the certified so called real fall down situation outside of the bed when compared to traditional solutions, in which have to be waited for an unreasonable long time analyzing the situation to continue, before is enough courage to report due to fear of false alarms.
A localised fall down event can also be notified when the TAG 100 is outside the active antennas 101 RF range, for example outdoors, when to the tag according the invention is integrated at least the GPS electronics part 155 and, alternatively, either the general wireless communication electronics part with for example a GPRS-compatible protocol implemented module 156 or the person has a cell phone, for example, with a Bluetooth readiness and installed such as a Java application, which will discuss with the TAG via Bluetooth.
One version of the active TAG 100 can also be integrated inside a mobile phone or other portable device so that it informs the phone of its location indoors out of reach of the GPS at the same time allowing for the fact that the phone turns the GPS on, only outdoors, what information will enable significant energy savings of phone power consumption, especially if you are mostly indoors.
Such a version of tag that is enabled to operate even independently without an active antenna, with the bed sensor together, but expressing an exit to outdoors is then depended on the RF range of the mobile TAG and the bed-TAG, which range is inaccurate.
When to the tag 100 is yet added the mentioned electronic compass based on the earth's magnetic field to measure direction of travel, can even only on near field of cell formed by one active antenna 101 be carried out positioning on the basis of information thus obtained, when is known the distance, direction and the beacon signal strength sent by the TAG. TAG sends a beacon signal with the above-mentioned data and receives, if not immediately, then next time, from the active antenna new data based at least on said measurements on the RF receivement direction, and if necessary, also information about a larger entity. Most simply the TAG 100 may inform its location change in the beacon signal, for example, the travelled distance as subdistances and the direction every time the direction changes, starting from the last active 101 antenna and/or from the point mentioned in message before last message each time the travel direction meet a deviation which is bigger than a set threshold, or at specified time intervals by storing information in order to minimize power consumption, and by sending the information at mentioned time intervals, eg once every 20 seconds, as a sequence, which consists of a series of successive measurements.
In a larger entity comprised of several active antennas 101 can also take advantage of triangulation and mathematical algorithms in tracking of more accurate location of TAG 100 on the basis of a RSSI value of the beacon signal sent by the TAG 100, and at the same time utilizing in the measurement accuracy significantly for each individual active antenna's 101 good direction selectivity and in further accurated location determination in addition to step measurement information/direction information sent by the TAG 100 with the beacon signal.
In outdoor positioning active antennas are needed, for example about one kilometre spaced network whose components can also be active antennas placed in private residences, or in service residences, and then can be preferably constituted a very extensive positioning area by the TAGs whose power consumption is minimal for example compared to GPS positioning using solutions.
Active antenna or some other system preferably updates and refines as return data to the tag its self-maintained location information such as coordinates, vectors and/or area knowledge, which information presentation form depends on the application and on the system way and required accuracy to perceive location for example on map presented on PC's display or on alphanumeric corridor screen.
Tag will be able to inform in addition to its user-id also its location, for example, in emergency call situation, the person calling for help by pressing a button 150, or by hitting a hit sensor 151 associated with the TAG, which sensor can be adjusted to the appropriate sensitivity depending on the application. The hit sensor principle to trigger the alarm allows locating the TAG under clothing, for example, because for the hit accuracy of the hand it is sufficient that the tag gets a hit strong enough, which differs from the normal operation.
At least the location of the push button 150 and the hit sensor 151, as well as the location of a microphone, and other electronics, may vary depending on application in different parts of the circuit board being different from that presented in
To the tag according to the invention can be attached, or more preferably integrated a GPS electronics part 155 for outdoor positioning as well as the common wireless communication electronics component for example implemented as a GPRS-compatible protocol module 156 or as integrated to circuit board, which the device can indicate its location out of reach of the active antenna such as on outdoor areas and still perform with very low power consumption of most of the time because the active antenna being in exit of the building, the TAG knows that the GPS is turned on only outdoors, and for example, GPRS only when it is needed to connect to. This allows a very compact implementation of the mobile device, at least of the size of the batteries, because many outdoor-use applications have normally very short periods of operating time.
At least half-duplex voice communication can be implemented using a GPRS connection very cheaply, as for example a hit sensor 151 based on a piezoelectric audio element is connected to GPRS 156 audio terminal in the same switching solution, as the microphone 139 is disconnected from other electronics and is connected to GPRS 156 audio input for the time of voice communication. When aiming at improved sound quality, instead of the audio element can be connected an actual loudspeaker solution.
In a preferred form, instead of the separate antennas, TAG 100 RFID electronic and/or GPS electronics 155 and the common wireless communication electronics 156 use a common antenna 103, the electrical length of which is changed for each frequency suitable for the use purpose, for example, with the same RF switch solution, which is used for the active antenna electronics unit 106 in connection of the radiators. In some applications, the common wireless communication electronic unit 156 is replaced by the Blue tooth electronics, through which the TAG discusses with such as a mobile phone, allowing TAG power consumption and size reduction compared to a scenario in which the TAG consists of electronics such as GPRS.
According to the same principle the TAG 100 may change the electrical length of its antenna when operating in other frequency bands as the RFID-band signalling of the active antenna 101. Thus the actual data communication between the TAG and the active antenna 101 in the long distance field, for example FSK signalling, can operate at a completely different frequency range than RFID positioning.
Active antenna wireless communication module 125 may also be a WLAN base station, when the active antenna can thus replace the WLAN base station. Outdoor positioning can be also performed with the active antenna solution preferably in such a way that is formed large monitored area by a network of several active antennas, so that at least on the area edges are placed the active antennas 10, which are targeted to receive a beacon signal sent by the TAG 100, the measurement values obtained from the beacon signal each active antenna transmits, e.g. by radio link to the central computing unit, which can be for example a PC, which on the basis of mathematical algorithms calculates locations of tags moving on the area, and which location information is available from the server in real time, for example, by using a web browser for example when searching for a missing person. This network can be formed easily also in such a way that active antennas are placed to main buildings on the area providing services, which together with active antennas locating in homes can realize even without special arrangements a quite wide positioning network.
In outdoors positioning distances can reach up to a kilometre away from the active antenna, when the location of the antenna is high enough, and an appropriate radio frequency band is selected, as well as the TAG beacon signal is to be sent using adequate transmission power when the TAG is moved to the outdoors.
In the text and claims the electronics unit components presented as modules, such as the wired communications module 121, can in some applications be also highly integrated to the printed circuit board, and would therefore not necessarily be as individual units, as illustrated in
The RF amplifier/connector part located in the electronics unit 106 of the invention presented in
The division to near field and far field presented in this document refers to the fact that in the near field RF signal reception and detection performed by the TAG 100 is possible directly without a pre-amplifier, for example with a diode detector. In the far field is required, at least, a preamplifier, and to a long distance it has to be added at least one amplifier stage. That is why it makes sense that far field measurement is performed by base station electronics 106 on the basis of beacon signal sent by the TAG100.
Although the invention has been presented in reference to the attached figures and specification, the invention is by no means limited to those as the invention is subject to variations within the scope allowed for by the claims according to different kind of applications.
Number | Date | Country | Kind |
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20105860 | Aug 2010 | FI | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FI2011/050718 | 8/17/2011 | WO | 00 | 2/12/2013 |