DE20110926U1 - Transponder reading unit with extended reading area - Google Patents

Description

204 7 8DEGM/J/wkm
14.05.2001

Interflex Data Systems GmbH & Co. KG Zettachring 16, 70567 Stuttgart

Transponder reader with extended reading range Description

The invention relates to a transponder reading unit according to the preamble of claim 1.

Contactless transponders are known to be read using a reader or a reading station. Such a reading station has, among other things, a fixed transmitting/receiving antenna that uses a high frequency (HF) field to transmit data unidirectionally or bidirectionally to or from a passive transponder identification device (so-called proximity).

The identification means mentioned usually consists of a microchip with an associated antenna, but has

no power supply of its own. The antenna is often designed as a planar conductor structure and an associated transmitting/receiving module as an integrated circuit. The identification device is therefore also referred to as a "passive transponder".

Such a passive transponder is known from EP 1 035 418 A1 and has an antenna in the form of a metal body with two surfaces, whereby the two surfaces are DC-decoupled by means of a diode. The electrical current required for operation is supplied by the RF field of the reading unit. The RF field is typically operated with a carrier frequency of 100 kHz to several 10 MHz, whereby the carrier frequency is modulated for data transmission, e.g. amplitude modulated.

The transponders mentioned open up many areas of application and are often used for contactless detection of people or objects, such as the identification of authorized persons, for example in access-restricting facilities such as revolving gates or barrier systems or in baggage detection at airports or train stations. The transponders or the associated identification devices are attached to the objects to be monitored or detected (sales goods, pieces of baggage, etc.) and provided with a specific code, which is the same as the one in

·

The transmitter/receiver unit located at the reading station can establish an active connection and exchange data via radio, such as the coding stored in the transponder, and possibly carry out other actions such as triggering an alarm signal, forwarding a piece of luggage, etc.

The designs for the respective means of identification are generally those in which a microchip can be integrated, such as checks, key chains or wristwatches.

The contactless recording of computer-readable data also facilitates the execution of many industrial applications in the industrial environment. Another area of application is the communication between a vehicle and a telematics service, as described in DE 19 925 663 A1, for example.

The disadvantage of the known transponders is a limitation of the signal range of the transponder chips or the reading units, which is typically up to 10 cm due to the field range of the HF radiation. This range limits the available reading area and therefore requires a maximum distance to respond to the reading unit or to transmit data, which, however, makes handling the transponders considerably more difficult in many areas of application.

The invention is therefore based on the object of developing a transponder reading unit of the type mentioned at the outset in such a way that the effective or reading range is increased using the simplest possible means and therefore at low cost.

This object is achieved by the features of independent claim 1. Advantageous embodiments are the subject of the subclaims.

The special feature of the transponder reading unit according to the invention is that it provides a passive antenna that is arranged in the field area of the active antenna and is not electrically connected to the transmitting and/or receiving unit. By using one or more passive antennas, the effective range or the reading range of the reading unit is increased. The passive antenna is excited to oscillate by the field of the active antenna. Likewise, an oscillation generated by an identification means in the passive antenna couples with the active antenna. Communication with the identification means is therefore possible bidirectionally.

The invention is described in more detail below using exemplary embodiments, wherein identical or functionally identical features are provided with identical reference numbers.

In detail

Fig. 1 shows a schematic arrangement of an active and a passive antenna of a transponder reading station according to the invention, each with its own effective range;

Fig. 2 shows a schematic arrangement of an active and a passive antenna of a transponder reading station according to the invention, with overlapping effective ranges; and

Fig. 3 shows an embodiment of a transponder reading station according to the invention.

The antenna arrangement shown in Fig. 1 has an active antenna 10, above which a passive antenna 12 is arranged. Only the active antenna 10 is connected to an electrical power supply (not shown) for generating a high-frequency alternating field. The passive antenna 12 is positioned in the field area of the active antenna 10 in such a way that the field of the active antenna 10 couples into the passive antenna 12 and the passive antenna 12 thus also becomes an active radiator. It is therefore not necessary to connect the passive antenna 12 to a

to supply electricity to its own transmitting and/or receiving module.

In order to optimize the coupling, both antennas are adjusted to a uniform carrier frequency of 13.56 MHz or 125 KHz, onto which the actual data signals are modulated in a known manner. The field areas generated by the two antennas with sufficient signal strength to transmit the signal to an identification device are shown in dashed lines and define the respective effective range of the two antennas.

Depending on the arrangement of the antennas, either the range can be increased or a second effective range can be created. In the embodiment shown in Fig. 1, the passive antenna 12 has its own effective range 16 that is separate from the effective range 14 of the active antenna 10. The two effective ranges 14, 16 can thus be spatially separated from one another in such a way that an area is arranged between the active antenna 10 and the passive antenna 12 in which an identification means cannot be read (see Fig. 3).

An alternative antenna arrangement to that shown in Fig. 1 is shown in Fig. 2. In this embodiment, the passive antenna 12 has a

with the active antenna 10 overlapping, i.e. common, area of effect 18.

The transponder reading station shown in perspective in Fig. 3 is used to read passive identification means 30 over a distance of at least 0.5 m. This reading distance is made possible by using the passive antenna 12 provided in addition to the active antenna 10. The active antenna 10 is electrically connected to a conventional transmitting and/or receiving unit (not shown) which is housed in a control unit 32 forming a base of the reading unit.

The passive antenna 12 has no electrical connections of its own and is formed by a first loop 36 of a bracket 34 which projects upwards from the control unit 32. The second 38 of three loops 36-40 is operatively connected to the transmit/receive module (not shown) of the control unit 32, the second 38 and the third of the loops forming the active antenna 10 and the passive antenna 12, respectively.

Due to the matching carrier frequency, the passive antenna 12 is excited to oscillate by the field of the active antenna 10 penetrating it according to the law of induction. The three loops 36 - 40 are approximately square in the example, with

the ratio of length to width of the bracket 34 in the case of the three loops 36 - 40 shown is essentially 3:1. The length of the bracket 34 is in the range of 1.5 to 2.5 m, preferably 2.15 m, and the width of the bracket 34 is in the range of 0.3 to 0.6 m, preferably 0.4 m.

In order to electrically activate the identification means 30 shown, the antenna arrangement consisting of the active antenna 10 and the passive antenna 12 is first operated by means of the transmission module (not shown) housed in the control unit 32. The active antenna 10 initially couples into the passive antenna 12. The RF field emitted in a superimposed manner by both antennas 10, 12 penetrates a transponder chip (not shown) of the identification means 30. The transponder chip is briefly electrically activated and radiates back into both the active antenna 10 and the passive antenna 12, with the passive antenna 12 in turn coupling inductively or capacitively with the active antenna 10. Communication with the identification means 30 shown therefore takes place bidirectionally via both the active antenna 10 and the passive antenna 12.

It is understood that the antenna arrangements described above are only examples and may be supplemented by additional active and/or passive antennas

can be extended in order to further expand the range of the reading station.

Claims (10)

1. Transponder reading unit, with an active transmitting and/or receiving antenna ( 10 ) and with a transmitting and/or receiving unit electrically connected to the at least one active antenna ( 10 ), wherein the at least one active antenna ( 10 ) is operated by means of the transmitting and/or receiving unit with a carrier frequency, characterized by at least one passive antenna ( 12 ) arranged in the field region of the at least one active antenna ( 10 ) and not electrically connected to the transmitting and/or receiving unit. 2. Transponder reading unit according to claim 1, characterized in that the at least one passive antenna ( 12 ) is tuned to the carrier frequency of the at least one active antenna ( 10 ). 3. Transponder reading unit according to claim 1 or 2, characterized in that the at least one passive antenna ( 12 ) has its own effective range ( 16 ) compared to the effective range ( 14 ) of the at least one active antenna ( 10 ). 4. Transponder reading unit according to claim 3, characterized in that between the at least one active antenna ( 10 ) and the at least one passive antenna ( 12 ) there is an area in which an identification means ( 30 ) cannot be read. 5. Transponder reading unit according to claim 1 or 2, characterized in that the at least one passive antenna ( 12 ) has an effective range ( 18 ) overlapping with the at least one active antenna ( 10 ). 6. Transponder reading unit according to one of the preceding claims, characterized in that the communication with an identification means ( 30 ) via the at least one active antenna ( 10 ) and the at least one passive antenna ( 12 ) takes place bidirectionally. 7. Transponder reading unit according to one of the preceding claims, characterized by a one-piece bracket ( 34 ) or the like having at least three electrical loops (36-40), wherein the first ( 38 ) of the at least three loops ( 36-40 ) is operatively connected to the transmitting and/or receiving unit, and the second ( 40 ) and at least third ( 36 ) of the loops ( 36-40 ) each form the active antenna ( 10 ) and passive antenna ( 12 ). 8. Transponder reading unit according to claim 7, characterized in that the transmitting and/or receiving unit is accommodated in a control unit ( 32 ) forming a foot of the reading unit, wherein the second ( 40 ) and the at least third loop ( 36 ) of the bracket ( 34 ) protrude substantially upwards from the control unit ( 32 ). 9. Transponder reading unit according to claim 7 or 8, characterized in that the at least three loops ( 36-40 ) have a substantially square cross-section, the ratio of length to width of the bracket ( 34 ) being substantially 3:1 in the case of three loops. 10. Transponder reading unit according to claim 9, characterized in that the length of the bracket ( 34 ) in the case of three loops ( 36-40 ) is in the range of 1.5 to 2.5 m, preferably 2.15 m, and the width of the bracket ( 34 ) is in the range of 0.3 to 0.6 m, preferably 0.4 m.