WO2007112717A1

WO2007112717A1 - Method and circuit arrangement for triggering a transmitting antenna

Info

Publication number: WO2007112717A1
Application number: PCT/DE2007/000417
Authority: WO
Inventors: Ulrich Joos; Heinrich Haas; Jochen Zwick; Ulrich Möller
Original assignee: Conti Temic Microelectronic Gmbh
Priority date: 2006-04-06
Filing date: 2007-03-08
Publication date: 2007-10-11
Also published as: DE112007000075A5; DE102006016219A1

Abstract

Disclosed is a method for triggering a transmitting antenna, a circuit arrangement for carrying out said method, and a keyless identification system comprising such a circuit arrangement. A first output signal (a1) and a second output signal (a2) that is essentially inverse to the first output signal (a1) are generated from a substantially trapezoidal input signal (e), and the first output signal (a1) is fed to the transmitting antenna (ANT) via a forward line (L1) while the second, inverse output signal (a2) is fed to the transmitting antenna (ANT) via a return line (L2), the two mutually inverse and symmetrical output signals having a trapezoidal shape in accordance with the shape of the input signal. To this avail, preferably two mutually inverse and at least substantially symmetrical linear amplifier units (101, 102) are used which are provided with mutually inverse, essentially symmetrical linear amplification factors.

Description

Conti Temic microelectronic GmbH Sieboldstr. 19, 90411 Nuremberg

Method and circuit arrangement for driving a transmitting antenna

The invention relates to a method / for driving a transmitting antenna according to the preamble of claim .1. Furthermore, the invention relates to a Schaltungsaπordnung for carrying out the method according to the invention.

Transmitting antennas are used, for example, in keyless identification systems, for example for so-called passive entry systems in motor vehicles. Most long waves are sent for location detection and communication with intelligent identification encoders.

The structure of such a circuit arrangement for controlling a transmitting antenna is sketched in FIG. The input signal is amplified and coupled into the antenna.

For driving transmission devices in the long wave range, a transmitting coil is operated in parallel or series resonance. The control is preferably carried out sinusoidally or with a higher harmonic content (for example, rectangular or trapezoidal).

Rectangular drive methods have the advantage of low circuit complexity and low power loss in the power output stage.

However, the high harmonic content of the output voltage for large supply line lengths requires a high filtering or Schirmungsaufwand for operating the assembly in motor vehicles.

Sinusoidal methods and trapezoidal methods, in particular with rounded corners, emit significantly less electromagnetic interference, yet parasitic line capacitances can produce interference that is radiated from the antenna or supply lines. The patent US 2005/0159117 A1 discloses a method or a circuit arrangement for increasing the transmission power of a balanced load, for example a dipole antenna, wherein in addition to the first antenna output signal, another inverse to the first output signal is generated, and a part of the balanced load, for example, the first part of the dipole antenna with the first output signal with supply voltage of V +, and another part of the balanced load namely the second part of the dipole antenna (the bottom dipole part of the dipole-antenna) are supplied with the second output signal with supply voltage of - (V +). This is intended to quadruple the total transmission power. In particular, two push-pull output stages (totem pole arrangement) are arranged to increase the transmission current so that the transmission power at the two signal outputs. Disadvantage of this method or this circuit arrangement is that the method or the circuit arrangement used switched or digital signals and thus can not achieve broadband symmetry on the transmission lines.

The patent AT 113 802 B describes a circuit for tube transmitter to increase the transmission power of a balanced antenna, wherein by grounding the transformer, a symmetrical arrangement is achieved. However, such a circuit arrangement can only be used if the transmission stage is carried out with transformers.

The object of the present invention is therefore to provide a method and a circuit arrangement, using this circuit arrangement, the disturbing electromagnetic radiation is reduced in the transmitting antennas. In addition, the circuit complexity and power loss should be reduced.

This object is solved by the features of the independent claims. Advantageous developments of the invention will become apparent from the dependent claims, wherein combinations and developments of individual features are conceivable with each other. An essential idea of the invention is that the transmitter antenna to drive with a substantially trapezoidal input signal. In this case, two mutually substantially inverse, ie inverted and largely symmetrical output signals are generated from the trapezoidal input signal, wherein the two preferably amplified output signals essentially receives the shape of the band-limited input signal and fed via the two lines in the transmitting antenna. The band limitation is necessary so that the amplification of the transmission signals can be performed with sufficient accuracy.

The proposed method drives the transmit antennas with a signal which keeps the common mode on the antenna lines approximately constant and thus minimizes the disturbing electromagnetic emission due to parasitic couplings.

In this case, the principle is independent of a driving waveform of the arrangement, as long as the amplifiers have sufficient bandwidth corresponding to gain accuracy.

The invention will now be explained in more detail below with reference to an embodiment with the aid of the figures. In the following, functionally identical and / or identical elements are designated by the same reference numerals.

Show it,

1 shows a circuit arrangement according to the prior art,

FIG. 2: embodiment of a circuit arrangement according to the invention,

Figure 3: embodiment of an input signal according to the invention. Figure 1 shows a circuit arrangement according to the prior art in which from a system clock (Clock Input) for the control of the transmitting antenna (ANT) required waveform, for example. A sine or trapezoidal signal is generated. This input signal is amplified by an amplifier to the required transmission power, wherein the output of the amplifier is connected to the one terminal of the antenna, commonly referred to as Hinleitung, while the other terminal of the antenna, usually designed as a return line, is connected to the ground potential.

In FIG. 2, the signal required for the control of the transmitting antenna (ANT), for example a trapezoidal signal, is likewise generated from the system clock (clock input) in a signal generator (3).

The circuit arrangement (10) according to the invention essentially comprises two subcircuits, namely two signal amplifier units (101, 102) which, apart from the amplifiers (1.1, 1.2), generate two mutually inverse intermediate signals (d, c2) from the common input signal (e) , preferably identical. In FIG. 2, however, in contrast to FIG. 1, the trapezoidal input signal (e) to be driven is supplied in two linear amplifier units (101, 102) with mutually inversely substantially symmetrical linear amplification factors. These two linear amplifier units (101, 102) each have an amplifier (1.1, 1.2), wherein the amplification factors (x1, x2) of the amplifiers (1.1 and 1.2) are inverse to one another and preferably have the following relationship: x1 = -x2. Of course, the amplification factors x1 and x2 can of course also be 1 or -1 different linear amplification factors, as long as the amplification factors correspond in absolute terms as precisely as possible and are inverse to each other from the sign. The two intermediate signals d, c2 essentially fulfill the following mathematical relationship: cl = -dl

The mutually inverse intermediate signals d, c2 obtained after the amplification can be further amplified by a respective downstream linear output driver stage 2.1 and 2.2, the symmetry of the output signals a1 and a2 generated therefrom being determined by the substantially equal linear amplification factors x3 and x4, preferably the Equation x3 = x4 holds, is preserved. The two output signals a1, a2 essentially fulfill the following mathematical relationship: β1 = -α2

Since the resulting drive signals a1 and a2 of the output stages 2.1 and 2.2 are symmetrical, the sum of the potentials on the antenna leads is also approximately constant. The output signal a1 is supplied to one of the lines, for example, positive line (ANT +) of the transmitting antenna (ANT) and the output signal a2 to another line, for example, negative line (ANT-) of the transmitting antenna (ANT). FIG. 3 shows an inventive substantially trapezoidal input signal compared to a sinusoidal or a rectangular signal.

A sinusoidal signal is very well suited for generating broadband-symmetrical Ausgangssignaie. However, a sinusoidal signal has a relatively small voltage-time area at a given amplitude, which increases power dissipation in the final stage.

A rectangular signal, on the other hand, has a large voltage-time surface and therefore lower losses in the output stage, but due to the high bandwidth of the signal, extremely fast amplifiers are required for generating broadband-symmetrical output signals, which in turn causes an increase in cost. A very good compromise is a trapezoidal signal, especially if in addition the corners are rounded off. This signal has a much larger voltage-time-area compared to a sinusoidal signal at a constant given amplitude, but has a limited bandwidth, which has a favorable effect on a broadband symmetry of the amplified differential signals. By suitable selection of the input signal, the linear amplifier and likewise linear output stages and their combination parasitic currents in the antenna or supply lines can be largely avoided and so the EMC (Electromagnetic Compatibility) emission can be minimized. Especially with a limitation of the harmonic components by using trapezoidal input signals with preferably rounded corners symmetrical amplifiers can be realized at a reasonable cost. In this case, there is a favorable ratio of power loss in the final stage and achievable symmetry of the transmission signals.

In this case, the linear amplifier or the linear amplifier means that the amplification factors of the amplifier or the output stage are linear factors, whereby the output signals have a linear gain relative to the input signal.

The DC component on the antenna lines is almost constant and currents in the parasitic coupling capacitances are avoided.

The method and the circuit arrangement can be used in principle with different waveforms, in particular, the trapezoidal shape with rounded corners represents a good compromise between the power loss in the power amplifier and the harmonic components.

This can only be made possible by the fact that the amplifiers (1.1, 1.2, 2.1, 2.2) are linear amplifiers. This means that the amplification factors (x1, x2, x3, x4) of all amplifiers (1.1, 1.2, 2.1, 2.2) are linear factors, so that the output signals (a1, a2) generated by means of the inventive circuit arrangement (10) have substantially less electromagnetic interference radiation absorbed, caused for example by the parasitic capacitance currents. Such a method or such a circuit arrangement is particularly preferably used in a keyless identification system, as used, for example, as an access system for motor vehicles with so-called passive-entry function. The system has a central unit with at least one, but often spatially distributed on or in the vehicle arranged a plurality of transmission antennas. The driver has an identification transmitter, wherein the central unit via the circuit arrangement according to the invention with two mutually at least substantially symmetrical amplifier units (101, 102) with an inversion for generating two inverse output signals (a1, a2) of the transmitting antenna and of this the identification transmitter energy and / or Data transmitted.

Claims

claims

1) A method for driving a transmitting antenna, wherein an input signal (e) amplified and generates a first output signal (a1) and fed to the transmitting antenna and from the input signal (e) a second output signal (a2) is generated, which is the first output signal (a1) is substantially inverse, and the first output signal (a1) is supplied via an outgoing line (L1) and the second, inverse output signal (a2) via a return line (L2) to the transmitting antenna (ANT), characterized in that the input signal (e) in Is essentially trapezoidal.

2) A method according to claim 1, characterized in that the firing width of the substantially trapezoidal input signal (e) by rounding the corners is limited so far that the input signal (e) by linear amplifier (1.1, 1.2, 2.1, 2.2) with good broadband Symmetry can be amplified.

3) Method according to at least one of the preceding claims, characterized in that from a common input signal (e) preferably two linearly amplified output signals (a1, a2) are generated, wherein the two output signals (a1, a2) have mutually broadband symmetry.

4) Method according to at least one of the preceding claims, characterized in that both the first output signal (a1) and the second output signal (a2) by means of linear amplifiers (1.1, 1.2, 2.1, 2.2) is amplified, wherein the linear amplifier (1.1, 2.1 ) for the first output signal (a1) and the linear amplifiers (1.2, 2.2) for the second output signal (a2) as a whole have mutually inverse linear amplification factors.

5) Circuit arrangement (10) for carrying out the method according to one of the preceding claims, with an input for the substantially trapezoidal input signal (e) and two mutually at least substantially symmetrical linear amplifier units (101, 102) each having a substantially inverse inverse linear gain factor (x1 * x3, x2 * x4) for generating two mutually substantially inverse symmetrical also substantially trapezoidal output signal (a1, a2) at the outputs to the transmitting antenna (ANT).

6) Antenna control unit with at least one circuit arrangement according to claim 5. 7) Keyless identification system with at least one circuit according to claim 5.

8) Vehicle with at least one device or a method according to at least one of the preceding claims.