DE102004004257A1 - A method for reducing the energy demand for a locking system remote operating unit has a high frequency transmitter sending short duration pulses to the receiving unit to initiate reception - Google Patents

Abstract

The remote transmission unit (3) has a transmitter (5) which consumes .5mu A in standby mode rising to 1mu A in transmitting a brief initiating pulse before a longer 2mu A actuating pulse to the receiving locking unit (2) receiver (1).

Description

The The invention relates to electronic transponder locking systems according to the generic term of claim 1.

electronic locking systems usually exist from the components input unit, evaluation and control electronics and locking mechanism. Users have locking permissions in Form of physical identification carriers or spiritual codes. The locking permissions are over a or more input units entered into the locking system and from the input unit to the evaluation and control electronics on directed. This one has one Stock valid stored locking authorizations. Newly entered locking authorizations are verified against this stock. Is a newly entered access authorization valid saved, the locking mechanism time-effectively controlled by the evaluation and control electronics and allows then directly or indirectly via a mortise lock unlocked and opening or connected to it Locking. Electronic locking systems are often called compact units constructed where input unit, locking mechanism and electronics physically with each other are connected. Such a compact unit is referred to below as a closing unit.

Become the closing authorizations stored in transponders, there is a wireless data exchange between closing unit and transponders, through which the identification of the transponder allows becomes. Is the identification of the transponder as valid authorization stored, gives the closing unit free admission. Ideally, the data exchange should be automatic begin as soon as a transponder of a clamping unit approximated Has. However, this requires that both components are always turned on are. Since transponders are often just the size of a credit card or one Key Chain, feature she just over very small batteries, with permanent connection after a short time exhausted are.

To avoid this disadvantage, passively operated transponders are often used. These only evaluate an echo of a signal transmitted by the clamping unit. Or transponders are used which take their operating energy from the signal they receive from the clamping unit. Systems of the two aforementioned types are in DE 41 11 582 A1 . DE 41 34 922 C1 and in DE 42 30 011 A1 described. Such systems have the serious disadvantage that they have a high power consumption and therefore are not suitable for battery operation. The required power supply makes the actually desired mounting directly on mortise locks of doors far too expensive.

In the DE 195 19 450 C2 a possibility is suggested to minimize the power consumption of the transponder. For this purpose, the transponder has a switch, by the operation of which can be aroused in the power-saving sleep mode transponder. However, this has the disadvantage that the transponder can not be used "handsfree." If the wearer of the transponder comes close to the locking unit, he must take the transponder in his hand and operate the alarm switch.

In the DE 195 19 450 C2 Another way to reduce power consumption is described. The transponder has two operating modes: in the activated operating mode, the power requirement is relatively high, in standby mode, however, relatively low. The transponder is periodically briefly switched to the activated operating mode to check whether the activation signal of a possibly close closing unit is present. If this is not the case, the transponder switches back to the energy-saving standby mode. A disadvantage of this procedure is that the transponder must be repeatedly switched to the activated operating mode with the higher power requirements. In order to avoid too long waiting times of the transponder carrier at the closing units, this periodic switching to the activated operating mode must probably take place every second. Even more serious is the disadvantage that the clamping unit must send its periodic wake-up signal very long-lasting in order to fall safely with their signal in the only briefly applied activated operating mode of the transponder.

The The object of the invention is to provide an extremely power-saving solution find, which allows the transponder permanently in the power-saving Keep ready mode, as long as no wake-up signal of a closing unit is present. Another object of the invention is to provide this Principle apply even if not the transponder through the closing unit is awakened, but if, conversely, the transponder, the closing unit wakes.

The Task is solved advantageously by the measures listed in the characterizing part of patent claim 1.

By the measures described in claim 2 is advantageously causes the closing units operated extremely energy efficient can be because they do not send out periodic activation signals and are awakened only when approaching a transponder. This solution makes sense if relatively few transponders are used on relatively many closing units within the entire locking system.

The Measures described in claim 3 have the advantage that both the transponder and the locking units extremely power-saving can be operated, since neither transponder nor closing units must send periodic activation signals. The disadvantage of this proposal is however, in that no "handsfree" use of the transponder possible is.

By the measures described in claim 4 will be the big advantage ensures that the component to be awakened permanently in the extremely energy-efficient standby listening mode can be held as long as no wake-up signal is present.

By the measures described in claim 5 is advantageously effected that the wake-up signal can be sent very energy efficient.

The Measures described in claim 6 have the big one Advantage that the transponders "handsfree" can be used that so when approaching to the door can stay in the bag.

embodiments The invention will be described below with reference to the drawings.

1 : Schematic representation of a locking system in which the transponders are awakened by closing units.

2 : Schematic representation of a locking system in which the locking units are awakened by transponders.

3 : Schematic representation of a locking system in which the transponders are awakened by an activation element.

4 : Communication protocol of the extremely low power receiver

The 1 to 3 show three alternative possible versions 1, 2 and 3 of the locking system according to the invention, which differ mainly by what component sends the wake-up pulses and in what form these wake-up pulses are triggered.

1 shows as version 1 the schematic representation of a transponder locking system in which the controllers of the transponder ( 3 ) by the closing units ( 2 ).

Each clamping unit ( 2 ) has a transmitter ( 1 ), which periodically radiofrequency pulses ( 4 ) transmits with 6 ms duration and then switches off the carrier frequency. This periodic transmission serves as an initiation signal ( 7 ), with which the controller of a possibly approximated transponder ( 3 ) via its receiver ( 5 ) can be awakened. To wait for the carrier of the transponder ( 3 ) to avoid the closing process, this program is repeated periodically every second. Because the transmitter ( 1 ) is tuned to a range of 50 to 100 cm distance, the transponder can usually be used "handsfree": the carrier of the transponder ( 3 ) does not have to take it out of the bag either when approaching or during the actual closing process. This "handsfree" use of the transponder ( 3 ) is a highly sought after property on the market for its comfort.

Each transponder ( 3 ) carries an extremely low power specialized receiver ( 5 ), which is characterized by being in standby listening mode ( 6 ) and that in this listening mode it uses only 0.5 micro Amperes minimum. This is very important for the transponder ( 3 ) can be supplied with a tiny battery for a long time, which is very important for its market success. If the transponder ( 3 ) to a distance of 50 to 100 cm or closer to the closing unit ( 2 ), its receiver ( 5 ) the initiation signals ( 7 ) of the transmitter ( 1 ) of the clamping unit ( 2 ). Once the recipient ( 5 ) Completely completed initiation signals ( 7 ), it switches to its activated mode and generates a wake-up signal ( 8th ) for the connected and sleep mode controller of the transponder ( 3 ). Now the actual data transfer between locking unit ( 2 ) and transponders ( 3 ) kick off.

2 shows as version 2 the schematic representation of a transponder locking system in which the controllers of the locking units ( 2 ) by the transponder ( 3 ).

Each transponder ( 3 ) has a transmitter ( 1 ), which periodically radiofrequency pulses ( 4 ) transmits with 6 ms duration and then switches off the carrier frequency. This periodic transmission serves as an initiation signal ( 7 ), with which the controller of a closing unit ( 2 ) about their receivers ( 5 ) can be awakened. To wait for the carrier of the transponder ( 3 ) to avoid the closing process, this program is periodically in seconds dentakt repeated. Because the transmitter ( 1 ) is tuned to a range of 50 to 100 cm distance, the transponder can usually be used "handsfree": the carrier of the transponder ( 3 ) does not have to take it out of the bag either when approaching or during the actual closing process. This "handsfree" use of the transponder ( 3 ) is a highly sought after property on the market for its comfort.

Each clamping unit ( 2 ) carries an extremely low power specialized receiver ( 5 ), which is characterized by being in standby listening mode ( 6 ) and that in this listening mode it uses only 0.5 micro Amperes minimum. This is important for the closing unit ( 2 ) can work with low power consumption. If the transponder ( 3 ) to a distance of 50 to 100 cm or closer to the closing unit ( 2 ), the receiver receives ( 5 ) of the clamping unit ( 2 ) the initiation signals ( 7 ) of the transmitter ( 1 ) of the transponder ( 3 ). Once the recipient ( 5 ) completed initiation signals ( 7 ), it switches to its activated mode and generates a wake-up signal ( 8th ) for the connected and in sleep mode controller of the clamping unit ( 2 ). Now the actual data transfer between locking unit ( 2 ) and transponders ( 3 ) kick off.

In this version 2 of the invention, the power requirement of the closing units ( 2 ) kept as low as possible. Instead, a comparatively higher power consumption of the transponder ( 3 ) accepted. So you will choose this version of the locking system so only if the locking system relatively few users and relatively many locking units ( 2 ).

3 shows as version 3 the schematic representation of a transponder locking system in which the controller of the transponder ( 3 ) by actuating an activation element ( 9 ) the transponder ( 3 ).

Each transponder ( 3 ) has an activation element ( 9 ) - z. Eg a push button. When a user approaches a closing unit ( 2 ) up to 50 to 100 cm or closer, he takes his transponder ( 3 ) and pushes its pushbutton. This will cause the transmitter ( 1 ) of the transponder ( 3 ) turned on. This now sends simple radio-frequency pulses ( 4 ) with 6 ms duration and then switches off the carrier frequency. This transmission serves as an initiation signal ( 7 ), through which the controller of the nearby closing unit ( 2 ) about their receivers ( 5 ) is awakened.

Each clamping unit ( 2 ) carries an extremely low power specialized receiver ( 5 ), which is characterized by being in standby listening mode ( 6 ) and that in this listening mode it uses only 0.5 micro Amperes minimum. This is important for the closing unit ( 2 ) can work with low power consumption. If the transponder ( 3 ) to a distance of 50 to 100 cm or closer to the closing unit ( 2 ), the receiver receives ( 5 ) of the clamping unit ( 2 ) the initiation signals ( 7 ) of the transmitter ( 1 ) of the transponder ( 3 ). Once the recipient ( 5 ) completed initiation signals ( 7 ), it switches to its activated mode and generates a wake-up signal ( 8th ) for the connected and in sleep mode controller of the clamping unit ( 2 ). Now the actual data transfer between locking unit ( 2 ) and transponders ( 3 ) kick off.

In this version 3 of the invention, the power requirement of the closing units ( 2 ) as low as in the previous version 2. At the same time, the power consumption of the transponder ( 3 ) is kept as low as in version 1. So this is the version of the locking system with the lowest overall power consumption. However, this advantage is paid for by the fact that the transponders ( 3 ) in this version can not be used "handsfree", which is a major disadvantage in the market.

4 shows the communication protocol of the recipient ( 5 ). To minimize power consumption, it is crucial that the receiver ( 5 ) in standby listening mode ( 6 ), can receive permanently. As long as there is no transmission, it remains in standby listening mode ( 6 ), in which it consumes only 0.5 micro-ampere. If a transmission is to be initiated, the receiver ( 5 ) by initiation signals ( 7 ) - consisting of a defined number of periods of the carrier frequency and subsequent Wegschaltung the carrier frequency - are switched to its activated operation in which it consumes a maximum of 2 micro-ampere and in which he a wake-up signal ( 8th ) for a connected microcontroller.

The aforementioned initiation signals ( 7 ) comprise two subareas. In order to exclude incorrect signals as initiation signals in a disturbed environment, a counter first counts whether there are 192 periods without interruption. Only then is the signal interpreted as valid. Short breaks are tolerated by the meter. Only when these 192 periods are present, the receiver starts ( 5 ) its automatic reception control. This takes at least 512 periods to complete successfully. Thus, a valid and complete initiation signal ( 7 ) a total of at least 704 periods. Now follows as the last condition, a switching off the carrier frequency. As soon as this happens is, the receiver generates ( 5 ) the wake-up signal ( 8th ) for the connected microcontroller.

Claims (6)

Electronic transponder locking system consisting of one or more locking units and one or more transponders, wherein a closing unit consists of a locking mechanism and an evaluation and control electronics connected to it, the locking mechanism either directly or indirectly via a mortise lock unlocking and opening or locking connected to it allows each transponder carries a locking authorization, locking authorizations are read using the transponder contactless in the locking unit, read access authorizations in the evaluation and control electronics are checked for validity and after entering a valid locking authorization, the locking mechanism is activated by the evaluation and control electronics, characterized in that a transmitter ( 1 ) of the clamping unit ( 2 ) for waking up the controller of a possibly approximated transponder ( 3 ) from time to time - preferably at intervals of one second - simple high-frequency pulses ( 4 ) short duration transmits and that each transponder ( 3 ) a receiver ( 5 ) with extremely low power consumption, which in the power-saving standby listening mode ( 6 ) can receive permanently and the radio-frequency pulses ( 4 ) of defined duration with subsequent switching off of the carrier frequency as an initiation signal ( 7 ) can recognize for switching to the activated operation. Electronic transponder locking system consisting of one or more locking units and one or more transponders, wherein a closing unit consists of a locking mechanism and an evaluation and control electronics connected to it, the locking mechanism either directly or indirectly via a mortise lock unlocking and opening or locking connected to it allows each transponder carries a locking authorization, locking authorizations are read using the transponder contactless in the locking unit, read access authorizations in the evaluation and control electronics are checked for validity and after entering a valid locking authorization, the locking mechanism is activated by the evaluation and control electronics, characterized in that each transponder ( 3 ) via a transmitter ( 1 ), to wake up the controller of any closing unit ( 2 ) from time to time - preferably at intervals of one second - simple high-frequency pulses ( 4 ) short duration and that each closing unit ( 2 ) a receiver ( 5 ) with extremely low power consumption, which in the power-saving standby listening mode ( 6 ) can receive permanently and the radio-frequency pulses ( 4 ) of defined duration with subsequent switching off of the carrier frequency as an initiation signal ( 7 ) can recognize for switching to the activated operation. Electronic transponder locking system consisting of one or more locking units and one or more transponders, wherein a closing unit consists of a locking mechanism and an evaluation and control electronics connected to it, the locking mechanism either directly or indirectly via a mortise lock unlocking and opening or locking connected to it allows each transponder carries a locking authorization, locking authorizations are read using the transponder contactless in the locking unit, read access authorizations in the evaluation and control electronics are checked for validity and after entering a valid locking authorization, the locking mechanism is activated by the evaluation and control electronics, characterized in that each transponder ( 3 ) via an activation element ( 9 ) and a transmitter ( 1 ) has the transmitter ( 1 ) after actuation of the activation element ( 9 ) for awakening the controller of the clamping unit ( 2 ) simple high-frequency pulses ( 4 ) short duration with subsequent switching off of the carrier frequency and that each clamping unit ( 2 ) a receiver ( 5 ) with extremely low power consumption, which in the power-saving standby listening mode ( 6 ) can receive permanently and the radio-frequency pulses ( 4 ) of defined duration with subsequent switching off of the carrier frequency as an initiation signal ( 7 ) can recognize for switching to the activated operation. Arrangement according to claims 1 to 3, characterized in that the extremely low-power receiver ( 5 ) operates in the electromagnetic long wave range, in standby listening mode ( 6 ), while consuming only 0.5 micro-amperes, by way of initiation signals ( 7 ) is switched with a defined number of periods of the carrier frequency and subsequent switching off the carrier frequency in the activated operation in which he max. 2 micro-ampere consumed and in which he a wake-up signal ( 8th ) for a connected controller that is in sleep mode. Arrangement according to claims 1 to 4, characterized in that the radio-frequency pulses ( 4 ) with a duration of less than 7 ms. Arrangement according to claims 1 to 5, characterized in that the transmitters ( 1 ) are tuned to about 50 to 100 cm range.