WO2010076061A1

WO2010076061A1 - Method and device for amplifying a signal suited to detect the surroundings of a vehicle

Info

Publication number: WO2010076061A1
Application number: PCT/EP2009/064421
Authority: WO
Inventors: Matthias Karl
Original assignee: Robert Bosch Gmbh
Priority date: 2008-12-17
Filing date: 2009-11-02
Publication date: 2010-07-08
Also published as: EP2380037A1; DE102008054789A1

Abstract

The invention relates to a method for amplifying an echo signal suited to detect the surroundings of a vehicle, comprising a step of amplifying the echo signal with an amplification factor dependent on the delay time of the echo signal and a step of providing an amplified echo signal to an interface (212).

Description

description

title

Method and apparatus for amplifying a signal suitable for vehicle environment detection

State of the art

The present invention relates to a method according to claim 1, a device according to claim 11 and a computer program product according to claim 12.

Ultrasonic sensors (US sensors) are used to detect objects in an environment of a vehicle. These are installed remotely around the vehicle. The ultrasonic sensors are designed to receive echoes sent out and to a central one by means of transmission lines

Signal processing of the vehicle to transmit.

8 shows a schematic representation of an arrangement for vehicle environment detection according to the prior art. Shown is a vehicle 800 having a first converter 801, a second converter 802, a third converter

803 and a fourth transducer 804. The transducers 801, 802, 803, 804 may be disposed on an outside of the vehicle 800. The transducers 801, 802, 803, 804 can each be designed as ultrasonic transmitters and receivers. Thus, the transducers 801, 802, 803, 804 can receive both ultrasonic signals and their reflections. The converters 801, 802, 803, 804 are connected via transmission lines 805, 806, 807, 808 to a central signal processor 809. The central signal processing 809 is designed to detect an object in the vehicle environment based on the received signals. The number of transducers 801, 802, 803, 804 is exemplified and may be increased or decreased in accordance with the requirements of vehicle surroundings detection. Fig. 9 shows a block diagram of a decentralized sensor according to the prior art. The decentralized sensor has a converter 801. The transducer 801 may be implemented as an acoustic-to-electrical converter and is suitable for use with the vehicle surroundings detection shown in FIG. 8. The distributed sensor further has an interface 912 to a transmission line, via which the decentralized sensor can be coupled to the central signal processor 809 shown in FIG. 8. The distributed sensor is configured to filter and amplify a signal received by the converter 801. For this purpose, the decentralized sensor has an amplifier device with an amplifier 913, a

Bandpass 915 and an amplitude compression 916 and another bandpass 917 and an arrangement of a further amplifier 918 and another bandpass 919 on. If the amplified carrier band signal of the converter 801 is transmitted via the interface 912 and thus via the transmission line for central signal processing, then conventional reception amplifiers have

913, 918 on a fixed transmission. The amplifiers 913, 918 are mostly combined with filters 915, 917, 919 with band-pass characteristics, or the filters 915, 917, 919 are integrated into the amplifiers.

In the architecture shown in FIG. 8, the transmittable signal dynamics are determined on the one hand by the maximum permissible emission of the transmission line 805, 806, 807, 808 or by the maximum signal strength which can be generated with little effort and on the other hand by the coupling into the transmission lines 805, 806, 807, 808 Disturbances limited. In order to widen the signal dynamics, the amplitude compression 916 shown in FIG. 9 is frequently carried out in the case of analog transmission. Amplitude compression 916 may be performed by a logarithmic curve.

FIG. 10 shows a logarithmic characteristic suitable for amplitude compression. In the shown logarithmic curve, the degree of compression

K = ^A

be determined by selecting the variable A. In the case of the fixed amplification architecture described in particular, small signals are in danger of being disturbed during transmission for central signal processing.

DE 42 08 595 A1 describes a device for distance measurement with ultrasound. By measuring the transit time between the transmitted and the received signal, the distance between transmitter and receiver is determined. Since the height of the echo signal depends inter alia on the distance between transmitter and receiver, inaccuracies in the evaluation of the echo signal may occur. These can be avoided by changing a switching threshold or by changing the amplification of the echo signal or by influencing the radiated signal as a function of the previously received echo signal. The change in the gain of the echo signal is carried out in response to an envelope shape of a previous echo signal. The disadvantage here is that the set gain for the current echo signal may be inappropriate if the current echo signal deviates from a previous echo signal in an unforeseen way. In addition, the required evaluation of the envelope shape of the previous echo signal is complex and expensive.

Disclosure of the invention

Against this background, the present invention proposes a method for amplifying an echo signal suitable for vehicle environment detection, a method for vehicle environment detection, furthermore a device which uses these methods and finally a corresponding computer program product according to the independent patent claims. Advantageous embodiments emerge from the respective subclaims and the following description.

The invention is based on the recognition that in the pulse transit time measuring systems, the receiving sensitivity to compensate for the room attenuation can be continuously tracked to analyze the received pulses with little effort in terms of their amplitude. Thus, taking advantage of the known fact that the echo intensity decreases with increasing echo propagation time, an inexpensive solution for transmitting a received echo can be achieved. to create. Advantageously, the approach according to the invention also enables a distortion-free and low-interference analog transmission of the received echo. The inventive approach can thus be used advantageously in ultrasonic driver assistance systems.

The present invention provides a method of amplifying an echo signal suitable for vehicle surroundings detection, comprising the steps of: amplifying the echo signal with a gain factor dependent on a propagation time of the echo signal; and providing an amplified echo signal to an interface. The echo signal may be a reflection of a

Transmit signal act. The transmission signal can be emitted for detection of an object in the vehicle surroundings by a sensor arranged on the vehicle. For example, the transmission signal may be an ultrasonic signal. The duration of the echo signal may define a time duration between a transmission of the transmission signal and a reception of the echo signal.

By amplifying the echo signal according to the invention with a gain factor which depends on a transit time of the echo signal, the echo delay loss resulting from the echo propagation time can be compensated for. Thus, the gain may have a greater value for a longer runtime than for a shorter runtime.

According to the invention, a value of the amplification factor may increase between a first time and a later second time in accordance with a predetermined amplification function. In this way, the gain can be continuously adjusted while waiting for the arrival of the echo signal. In this case, the change of the amplification factor for each expected echo signal can be repeated in the same way. When the echo signal arrives, the amplification factor can then have a value optimally adapted to the transit time. Due to the continuous change of the amplification factor, it is not necessary to determine the propagation time of the echo signal separately.

If the echo signal represents a reflection of the transmission signal, the first time may be a predetermined time after a transmission time of the transmission signal. In this way, the adjustment of the amplification factor can be synchronized with the transit time. The predetermined gain function may be defined by a linear function, an exponential function, a power function or a jump function. The different functions make it possible to adapt the inventive approach to different requirements. Thus, for example, functions can be selected which allow an optimal adjustment of the amplification factor or it is possible to select functions which can be realized cost-effectively.

According to one embodiment, the method according to the invention may comprise a step of calibrating the amplification factor based on an echo signal serving as a reference, wherein the reference signal serving as echo signal represents a reflection of a reference transmission signal. Thus, no additional reference signal is required for calibration. The reference transmission signal may have a course optimized for calibration. For example, the reference transmission signal may be a static signal having a predetermined reference value. The transmission of the reference transmission signal with a predetermined reference value is advantageous when acoustic interferers occur that have no stationary size statistically. By contrast, if the acoustic interferers have a statistically stationary magnitude, then the predetermined reference value of the reference transmission signal can approach zero or be zero. In this case, the interference signal of the acoustic interferers is received as a supposed echo signal. By means of the calibration, it is possible to compensate for variations in the amplification that occur, for example, in the case of simple analog circuits in the case of temperature fluctuations.

The inventive method may further comprise a step of amplitude compression of the echo signal. In this way, signal strengths that are too large for further transmission can be compressed. The echo signal can be compressed both before and after amplification.

In one embodiment, the method may include a step of transmitting the amplified echo signal to an interface of central signal processing, wherein the central signal processing may be adapted to detect a vehicle environment based on a plurality of echo signals. The transmission can be wired or wireless. In this way, the gain of the echo signal can be performed decentralized.

The present invention further provides a method for vehicle surroundings detection based on a plurality of echo signals, comprising the steps of: amplifying at least one of the plurality of echo signals according to the inventive method for amplifying an echo signal suitable for vehicle surroundings detection; and evaluating the at least one amplified echo signal and the remainder of the plurality of echo signals to detect a vehicle environment. In this way, the inventive approach can be used in conjunction with known arrangements for vehicle environment detection.

Also by the embodiment of the invention in the form of a device, the object underlying the invention can be solved quickly and efficiently.

Also of advantage is a computer program product with program code, which is stored on a machine-readable carrier such as a semiconductor memory, a hard disk memory or an optical memory and is used to carry out the method according to one of the embodiments described above, when the program is executed on a control unit ,

According to the invention, the signal strength of an analog signal transmitted on the transmission line between the sensor and central signal evaluation does not decrease in the usual measure for the room attenuation. After transmitting a transmit pulse, the gain of a constant acoustic pulse in the receiver changes depending on the time of arrival of the acoustic pulse to the receiver.

The invention will now be described by way of example with reference to the accompanying drawings. Show it:

1 shows a flow chart of an embodiment of a method according to the invention; FIG. 2 is a block diagram of a remote sensor according to an embodiment of the present invention; FIG.

FIGS. 3 a to 3 d show timing diagrams for transmitting the transmission start of a transmission pulse, according to an exemplary embodiment of the present invention

Invention;

4 is a graph of a gain characteristic according to an embodiment of the present invention;

Fig. 5 is a circuit diagram of an adjustable gain, according to an embodiment of the present invention;

FIG. 6 is a graph showing a stepwise gain characteristic according to an embodiment of the present invention; FIG.

Fig. 7 is a circuit diagram of an adjustable gain, according to another embodiment of the present invention;

8 shows a schematic illustration of an arrangement for vehicle surroundings detection, according to the prior art;

9 is a block diagram of a decentralized sensor according to the prior art

Technology; and

10 shows a suitable for amplitude compression logarithmic characteristic, according to the prior art.

The same or similar elements may be provided in the following figures by the same or similar reference numerals. Furthermore, the figures of the drawings, the description and the claims contain numerous features in combination. It is clear to a person skilled in the art that these features are also considered individually or that they can be combined to form further combinations not explicitly described here. FIG. 1 shows a flow chart of a method for amplifying an echo signal suitable for vehicle environment detection in accordance with an embodiment of the present invention. In a first step 101, a received echo signal is amplified. An amplification factor on which the amplification is based is dependent on a transit time of the echo signal. In a second step 102, an amplified echo signal is provided to an interface. The amplified echo signal can be output for further evaluation via the interface. According to the invention, the amplification factor may have a greater value for a longer transit time than for a shorter transit time. The change of the amplification factor can be synchronized with the duration of the echo signal. When the echo signal arrives, the currently current value of the changing amplification factor can be selected and used to amplify the echo signal. Thus, apart from the synchronized changing of the amplification factor, no control, preselection or precalculation of the amplification factor is required.

The method according to the invention can be used in conjunction with an arrangement for vehicle surroundings detection, as shown in FIG. 8. In particular, the method can be implemented in a decentralized sensor of an arrangement for vehicle surroundings detection. In this case, the echo signals received by one, several or all of the transducers shown in FIG. 8 can be amplified by means of the method according to the invention and relayed via transmission channels to the central signal processing. Thus, in a vehicle surroundings detection method based on a plurality of echo signals, at least one of the plurality of echo signals may be amplified according to the method of the present invention. The detection of an object in the vehicle environment can then be based either only on echo signals which are amplified according to the invention or on a combination of inventive and conventionally amplified echo signals.

2 shows a block diagram of a decentralized sensor according to an embodiment of the present invention. The decentralized sensor has a converter 21 1. The converter is configured to receive an echo signal. For example, the transducer 21 1 may be formed as an acoustic-electric converter and used for the vehicle environment detection shown in Fig. 8.

The decentralized sensor is designed to detect the received echo signal. strengthen and provide as an amplified echo signal at an interface 212. At interface 212, the amplified echo signal may be provided as an analog signal for transmission to central signal processing.

The distributed sensor has an amplifier device with a variable amplifier 213. The amplifier device is designed to amplify the received echo signal and to provide it as an amplified echo signal to the interface 212. The variable amplifier 213 may be driven by a gain controller 214. The gain controller 214 may be configured to increase the gain of the variable gain amplifier 213 as the gain increases

Increase transit time of the echo signal and thus implement the inventive method for amplifying a suitable vehicle environment detection echo signal. The gain controller 214 may be coupled to the interface 212. Furthermore, the gain control 214 may have an interface for synchronization with a transmission time of the echo signal or of a transmission signal on which the echo signal is based. In addition to the variable amplifier 213, the amplifier device may further comprise a bandpass filter 215 and optionally an amplitude compression device 216. The bandpass filter 215 may filter the signal provided by the variable gain amplifier 213. The amplitude compression device 216 may perform amplitude compression of the filtered signal and provide a compressed signal to the interface 212.

The decentralized sensor may further comprise a further bandpass filter 217 and a further amplifier device with an amplifier 218 and another bandpass filter

219 have. The further bandpass 219 is designed to filter the echo signal provided by the converter 21 1 and to provide it to the amplifier 218. The further bandpass 219 is designed to filter the echo signal preamplified by the amplifier 218 and to provide it to the variable amplifier 213.

In the decentralized sensor, it is thus possible to realize a pulse-time-dependent reception amplification in the ultrasonic pulse-echo vehicle surroundings detection. The approach according to the invention is based on the recognition that echoes with a longer transit time T generally have a lower signal strength, since they As a result, the room attenuation are attenuated stronger than short-term echoes. This results from the fact that for the echo strength applies:

r (τ) ^« k ₄ • d ^{" x} .

The size k ₄ is not subject to closer inspection. The space attenuation increases with increasing object distance d, where the increase per object is: 1, 5 <x <4.

With

d = c • T

the expression follows:

r (τ) ^« k ₅ • r ^x .

Theoretically, therefore, an echo signal r _v (τ), in which the propagation-related space attenuation is compensated, by means of propagation time-dependent gain

certainly.

However, since the power x depends on the objects reflecting the acoustic transmission pulse, a general optimum gain V (τ) can not be given. For arbitrary objects, only the general rule can be derived that increasing gain with the propagation time in the receive amplifiers is desirable in order to be able to transmit large signals as free from distortion and small signals as possible to the central signal processing.

A corresponding receiver architecture of the decentralized sensors is shown in FIG. In contrast to the amplifier shown in FIG

2 sensor, at least one receiving amplifier 213 whose gain is variable and can be varied by means of a gain control 214. The timing of the receive amplification 213 should preferably run synchronously with the transmit pulse and thus also synchronously with the reflected echo signal.

Figures 3a to 3d represent possible timing schemes for easy transmission of the transmission start of the transmission pulse to all sensors of an arrangement for vehicle environment detection. If the receiver, as shown in Fig. 8, connected by means of transmission lines to a central signal processing, so the control center can tell all receivers the start of transmission of the pulse whose reflection represents the echo signal. This can e.g. be effected in that the supply voltage or the supply current to the decentralized sensors differs during the transmission of the pulse. By transmitting the transmission start, the amplification factor can be synchronized with the transit time of the echo signal.

The transmission start of a transmission pulse is at times τ = 0. The transmit pulse ends at the time τ = T _P.

3a shows a voltage curve U at the transmitting sensor, plotted against the time T. Until the instant τ = 0, the voltage has a constant

Value of eg U = 8V on. For example, at time τ = 0, the voltage drops to a value of U = OV and oscillates between OV and 8V at time TP. From time T _P , the voltage may again have the constant value of 8V.

3b shows a voltage curve U in a receiving sensor, plotted against the time T. Up to the time τ = 0, the voltage has a constant value of eg U = 8V. For example, at time τ = 0, the voltage drops to a value of U = OV and remains at OV at time T _P. From time T _P , the voltage again has the constant value of 8V.

3c shows a voltage curve U in the case of a further receiving sensor, plotted over time T. The voltage curve corresponds to the voltage curve shown in FIG. 3b. In the simple exemplary embodiments shown in FIGS. 3 a to 3 c, the transmitting sensor is informed by transmission of a clock signal that it is to transmit, while the receiving sensors are notified by means of a digital jump of duration T _P that another sensor is currently transmitting.

Fig. 3d illustrates different traces 321, 322, 323 of a propagation time dependent gain. Shown is the gain curve 321, 322, 323 of the receivers over time T. Preferably, the gain should only be after the duration of the transmit pulse Tp and after an optional additional delay T ₀ increase. Until a time τ = 0, the gain may have a maximum value V _max . For example, at time τ = 0, the gain may drop to a value of V ₀ and remain at V ₀ above time T _P until time Tp + T _D. From time T _P + T _D , the gain may increase until the value V _{max is reached} . Thus, a value of the gain factor between the time T _P + T _D and a later second

Increase time according to a predetermined gain function. The predetermined gain function may be defined by a linear function, an exponential function, a power function or a jump function. The basic principle of all curves 321, 322, 323 is here that the gain preferably starts from a basic gain V ₀ and with a maximum gain V _∞ or

V _max should end. Preferably, the basic gain should be chosen so that important strong echoes are still transmitted without distortion and the maximum gain is at most in the order of magnitude of the in-band background noise.

For the transition section of the gain curve 321, in which the gain increases, a gain according to

Vp (τ) = K ₁ (T - Tp - T _D ) ^X + V ₀ , where x ^« 2.5

be optimal.

However, such a course of the gain curve could be too costly for a cost-saving implementation, for example, with commercially available analog components. Therefore, also a linear gain increase 322

V ₀

be acceptable.

By means of a resistor-capacitor combination, it is easy to realize a time-dependent amplification 323 with an exponential character:

V _* (τ) =% - lk) e ** + I? «.

Further amplification processes are possible within the scope of the inventive approach.

FIG. 4 shows an embodiment of a profile of a gain characteristic 424 that is realized by approximating a plurality of curve pieces. By the time τ = 0, the gain V (τ) may have a maximum value V _∞ . For example, at time τ = 0, the gain may be at a value

V ₀ fall and remain at the time V _P + T _D at the value V ₀ . From time T _P + T _D , the gain can increase until the value V _{∞ is reached} . In this case, the steepness of the rise of the gain curve 424, according to this embodiment, is increased in four steps. Thus, an approximation of the transition of the gain from V ₀ to V _{∞ can be made} by means of curved pieces.

Fig. 5 shows a circuit diagram of an adjustable gain, which is realized according to this embodiment by means of steepness modulation. The slope modulation can be realized by means of a known slope multiplier, which is characterized by the characteristic curve

V.,

/ frr U _y <6

R .. 2üτ

wherein U _τ defines the voltage drop across the bipolar transistor.

6 shows an exemplary embodiment of a profile of a particularly simple variant of a gain characteristic with a sudden increase in gain. tion or gain switching. Shown are two variants. A first gain characteristic 625 has a time equidistant gain change. A second gain characteristic 626 has an amplitude equidistant gain change. Until a time τ = 0, the gain may have a maximum value V _∞ . At the time τ = 0, ₀ may fall and remain until the time T _P + T _D at the value V _0, the gain for example to a value V. From the time T _P + T _D , the gain can increase abruptly until the value V _{max is reached} . According to this embodiment, the first gain characteristic 625 increases in four steps from the value V ₀ to the value V _max . The second gain characteristic 625 increases in five steps from the value V ₀ to the value V _max .

FIG. 7 shows a circuit diagram of a realization of an abrupt gain, as shown in FIG. Shown is a particularly simple variant of the sudden change in gain, as described, for example, in US Pat. caused by a gain switching. The gain of the circuit shown in Fig. 7 can be changed abruptly by switching on or off resistors. The switching of the resistors can be done by the gain control shown in FIG.

If both the time and the changing amplification values are known to the central signal processing shown in FIG. 8, the signal distortion caused by the sudden change in amplification can preferably be compensated by means of digital signal processing.

If simple analog circuits are used for gain adjustment, then in particular temperature fluctuations can lead to strong variations in the gain. These amplification fluctuations can be detected by the central signal processing in different ways.

According to one embodiment, all the sensors may be controlled as receiving sensors, as shown in Figures 3b and 3c, and the acoustic noise may be used as a reference by multiple correlation if necessary. In this case, the central signal processing can determine from the time course of the signals from the reception amplifiers of the decentralized sensors the time profile of the respective amplification. It is assumed that the acoustic interferers are at least statistically a stationary size.

According to a further embodiment, at least one sensor can be set as "continuous tone transmitter" and all other sensors can, as in the

Figures 3b and 3c shown as receiving sensors are driven. If necessary, the continuous tone signals can be used as a reference by means of multiple correlation. In this case, the central signal processing can determine from the time course of the signals from the reception amplifiers of the decentralized sensors the time profile of the respective amplification. This active

Variant can be preferably used when the acoustic interferers are not even statistically a stationary size. In this method of amplifier calibration, it must be ensured that, in principle, the signals of the

Continuous sounder are stronger than any echoes that may occur. Rarely occurring

Echoes that are noticeably stronger than the continuous tone signal can be filtered out.

Preferably, at least one of the gain quantities, namely the fundamental gain V ₀ and / or the maximum gain V _{∞, may have} a value known to the central signal processing. Thus, the cost of the self-calibration can be limited by this fixed reference to the determination of the relative change to this reference.

The calibration may be performed by the gain driver shown in FIG. To this end, the gain driver may receive a calibration signal from the central signal processing shown in FIG. The central signal processing can determine the calibration signal based on a reference echo signal. The echo signal serving as a reference can represent a reflection of a reference transmission signal that, according to the exemplary embodiments described, can be a continuous tone signal with a predetermined reference value. The predetermined reference value may also be a zero value, so that no reference transmission signal is transmitted. In this case, the receivers can still be controlled as if a transmission signal were sent out. Instead of an echo signal, the receive Receiver in this case, however, interference signals. The interference signals can be forwarded to the central signal processing for evaluation.

If the dynamics of a simple, propagation-time-dependent amplification do not suffice to compress both small signals and large signals onto the transmission path, the propagation-time-dependent amplification can preferably be designed for the optimum transmission of the small signals. Too large signal strengths of large signals can be compressed in this case with the amplitude compression shown in Fig. 2.

The present invention provides a system for vehicle surroundings detection by means of pulse echo modulation which decentrally amplifies the strength of a received signal before being transmitted over a transmission link, e.g. a line or a radio link is transmitted analogously to a central signal processing. In this case, at least the gain of one of the decentralized amplifying receivers can be dependent on a time interval between transmission of a transmission pulse up to arrival of a reception echo.

In this case, the amplification can start from a basic gain VO and end with a maximum gain V∞.

A transition from the basic gain V ₀ to the maximum gain can V∞ a potency similar to formula V _P (τ) = k (T - T _D - T _P) corresponding to ^X + V _0th Alternatively, the receiver may have another continuously increasing gain, such as an exponential characteristic V _P (τ) = ki (T - Tp - T _D ) ^X + V ₀ or a linear characteristic V (τ) = k ₂ (T - T _P - T _D ) + V ₀ . Like the power curve, the gain can also increase with the transit time T and be approximated by sections of curve pieces.

A variation of the gain in time or gain value can by means of

Reference signal calibrated, preferably at least one of the gain values base gain V ₀ and / or maximum gain V∞ require no calibration during the operating time. As a calibration reference of the reception gain, a strength of a stochastic stationary noise signal can be used. The calibration reference of the receive gain can be a from the System self-generated reference signal, such as a continuous tone used.

The amplification can be switched over in a jump, whereby preferably the times and the respective amplification values of the central signal processing are known. Also, the gain can be jumped over, with the course of the sudden gain change must be calibrated by the central signal processing.

In addition to runtime-dependent amplification, as usual,

Large signals are compressed by means of amplitude compression.

The described embodiments are chosen only by way of example and can be combined with each other. In particular, the circuits described may be comparable to other or similar circuits

Switching elements and different circuit architecture can be replaced. In addition to the described ultrasound signals, the method according to the invention can also be used with other suitable signal types. Also, individual process steps can be performed in different order or multiple times.

Claims

claims

1 . Method for amplifying an echo signal suitable for vehicle surroundings detection, comprising the following steps:

Amplifying (101) the echo signal with a gain dependent on a transit time of the echo signal amplification factor; and

Providing (102) an amplified echo signal to an interface (212).

2. A method according to claim 1, wherein the amplification factor has a greater value for a longer transit time than for a shorter transit time.

3. A method according to claim 1 or 2, wherein a value of the gain factor between a first time (T _P + T _D ) and a later second time according to a predetermined gain function (321, 322, 323, 424, 625, 626 ) elevated.

4. The method of claim 3, wherein the echo signal represents a reflection of the transmission signal and wherein the first time (T _P + T _D ) is a predetermined time after a transmission time of the transmission signal.

5. A method according to any one of claims 3 or 4, wherein the predetermined gain function (321, 322, 323, 424, 625, 626) is defined by a linear function, an exponential function, a power function or a jump function.

A method according to any one of the preceding claims, comprising a step of calibrating the gain based on a reference echo signal, the reference echo signal representing a reflection of a reference transmit signal.

A method according to claim 6, wherein the reference transmission signal is a static signal having a predetermined reference value.

A method according to any one of the preceding claims, including a step of amplitude compression (216) of the echo signal.

A method according to any one of the preceding claims, comprising a step of transmitting the amplified echo signal to a central signal processing interface (809) adapted to detect a vehicle environment based on a plurality of echo signals.

10. A method of vehicle environment detection based on a plurality of echo signals, comprising the steps of:

Amplifying at least one of the plurality of echo signals according to one of claims 1 to 9; and

Evaluating the at least one amplified echo signal and the remainder of the plurality of echo signals to detect a vehicle environment.

1 1. Device for carrying out all steps of a method according to one of claims 1 to 10.

12. Computer program product with program code, which is stored on a machine-readable carrier, for carrying out the method according to one of claims 1 to 10, when the program is executed on a control unit.