FR2689980A1 - Moving object detector for vehicles - has modulated laser rays for reflection which are amplified and demodulated and the doppler offset extracted - Google Patents

Abstract

Modulated laser radiation (S1) is emitted from a laser diode (1) modulated by an integral photodiode (3). Reflected signals (E1) from the target (2) pass through a collimation lens (4) and are amplified in the laser cavity. The beat frequency from the moving target is extracted by the photodiode (3) producing the doppler return (homodyne system) (6). The return passes through a high pass filter (7), smoothing circuit (8) and then to a processor (9) which outputs the distance (D) and speed (V) of the vehicle. ADVANTAGE- Allows weak signals to be received without interference from car lights or sunlight thus making the system more secure.

Description

The subject of the invention is a method for detecting obstacles, intended in particular for measuring the distance and the speed of moving targets, of the type using optical homodyning of a frequency modulated laser beam.

The subject of the invention is also an obstacle detection device, using the method according to the invention, intended in particular to be installed on a motor vehicle, for detecting moving targets and measuring their distance and their speed relative to the vehicle team.

Currently known optical radars or lidars use either direct or inconsistent detection, or indirect or coherent detection.

In the first case, the distance from the target is measured by modulating the power of the laser by a train of pulses whose delay is measured. This technique leads to a large blind distance if the pulse length is not reduced, which requires rapid modulating circuits. In addition, there is the problem of ambiguity of the position of the target if the latter has a high reflection power and is located at a distance greater than the maximum distance determined by the choice of the frequency of recurrence of the pulses. In addition, the direct detection lidar is very sensitive to ambient noise and that of electronic processing. The power of the pulses emitted must therefore be high and despite this, the lidar may be dazzled by the sun.Finally, the speed of the target cannot be measured.

In the case of a homodyne-type coherent detection lidar, the beam emitted by the laser is split in two, generally by a separating blade. Part of the wave is directed towards the target, the other part towards a detection device, for example a photodiode, to be mixed with the wave diffused back by the target.

As a result, the current delivered by the photodiode carries all the information of the wave emitted both in amplitude, in frequency and in phase. The target speed can therefore be directly detected by this type of lidar.

To measure the distance and the speed of the targets, one can adopt either pulse modulation or frequency modulation.

In the case of pulse modulation, the distance is measured, as in the case of direct detection lidars, by the delay of the received pulse compared to the transmitted pulse, while the speed is measured by the Doppler frequency within the received pulse. For this measurement, the processing electronics must be very fast since the pulse length must be short.

In the case of frequency modulation, an indirect modulation of the laser is usually used with the use of an external acousto-optical or electro-optical modulator interposed between the laser and the separating plate. This complicates the optical and electronic production.

The known direct detection methods and devices do not make it possible to detect very low powers scattered back by the targets. We must therefore have recourse to powers of resignation incompatible with security standards. In addition, in use on a motor vehicle, they do not make it possible to obtain high selectivity and their detection capacity can be disturbed by the presence of solar rays or of the headlights of vehicles traveling in the opposite direction.

The object of the invention is to remedy these drawbacks and also to allow the detection of even poorly reflecting targets such as those which may be encountered in motor traffic.

The invention also aims to use for this purpose a very compact opto-electronic component in which a laser diode and a receiving photodiode constitute a single component.

The method according to the invention is therefore of the type using the optical homodyning of a frequency modulated laser beam and it is characterized in that the beats between the wave emitted by the laser and the echo of this wave diffused by the target, this echo being amplified beforehand by the passage through the cavity of the laser before being mixed with the emitted wave.

In this way, optical amplification of the echo is combined with optical homodyning, which makes it possible to obtain a very favorable signal to noise ratio and therefore to detect poorly reflecting targets.

Preferably, the emitted laser beam is modulated according to a double ramp law, each ramp being linear and of slope opposite to the associated ramp.

In this case, the modulation law may include portions at constant frequency interposed between the double ramps.

A device for implementing the method according to the invention is essentially characterized in that it comprises a laser emitting by its two faces and means modulating in frequency the laser current.

It is particularly advantageous to use the photodiode for controlling a laser diode to detect the beats between the wave emitted by the rear face of the laser and the echo, returned by the target, of the wave emitted by the front face. of the laser.

The device is therefore also characterized in that it comprises a single electronic component for transmission and reception, this component comprising in the same housing a laser diode and a photodiode, the laser diode emitting from its front face in the direction of the target and by its rear face towards the photodiode.

The device may comprise only a single lens, for example with an index gradient, collimating towards the target the wave emitted by the front face of the laser diode and towards the cavity of the wave laser diode diffused in return by target.

It is also important to provide a temperature regulation device.

This temperature regulation device may include a radiator connected by thermoelectric elements using the Peltier effect to a laser support plate, the current of - these elements being controlled by the difference between the temperature of the support plate and a temperature of instructions.

Other characteristics and advantages of the invention will appear more clearly in the detailed description which follows and refers to the appended drawings given solely by way of example, and in which
- Figure 1 is a schematic view of a device
according to the invention;
- Figure 2a shows the law of modulation of the current of the
laser as a function of time t;
- Figure 2b shows the corresponding modulation law
the length of the emission diode;
- Figure 3 shows the mounting of the laser diode on a
thermal regulation device.

As shown diagrammatically in FIG. 1, the device according to the invention comprises a single-mode laser diode 1, the wavelength of which is in the near infrared. The diode 1 transmits continuously and by its two faces signals S1 and S2 of the same wavelength, the front face being directed towards a target 2 and the rear face towards a receiving photodiode 3.

The laser diode 1 and the photodiode 3 are integrated within the same component of known type in which the photodiode is usually used to control the emission power of the laser diode.

The wave S1 emitted by the front face of the diode 1 and the El wave scattered back by the target are collimated by a lens 4 with an index gradient of the type known for example under the trade name "Selfoc"
The laser diode 1 is current controlled by a modulation device 5 according to a double ramp modulation principle which will be explained later.

According to the invention, the echo El of the target 2 is amplified by crossing the cavity of the laser diode 1. The photodiode 3 detects the beat of the wave S2 emitted by the rear face of the laser and of the amplified echo E2.

The voltage taken at 6 at the base of the diode connected to a bias voltage by a resistor R is processed by a high-pass filter 7, a shaping circuit 8 and a computer 9 delivering the signals D and V representing respectively distance and speed of the target from the vehicle.

We will now describe the modulation process and the operation of the device.

It is known that the laser diodes exhibit both a variation in the emitted power and a variation in the emission spectrum as a function of the intensity of the operating current.

Whatever the laser, there is an area of the spectrum of the emitted wave that does not have a mode jump and in which the variation of the wavelength is a linear function of the intensity of the operating current.

The current of photodiode 3 and therefore the voltage taken at 6 will therefore have two components:
- One, due to the modulation of the power, is without
useful for obstacle detection. She is eliminated
by the high-pass filter 7 whose cut-off frequency
is greater than the modulation frequency.

- The other, due to the frequency modulation of the diode
laser, contains speed and distance information between
the target and the equipped vehicle.

The laser current is modulated by a flat part P and a double ramp r1, r2 as shown in FIG. 2a, which induces a diode length modulation X of the same shape shown in FIG. 2b.

On reception, the following beat frequencies are detected:
Flat part: tdoppler
rising ramp:
Qdis - pdoppler (when the target moves away) =
redis + pdoppler (when the target approaches)
descending ramp:
pdis + doppler (when the target moves away)
=
idis - doppler (when the target approaches)
with:
Qdoppler = 2V / # dis = 2D # / C where ::
D = laser diode / target distance
V = speed of the target in the axis of the laser
D = slope of the laser frequency modulation
= laser wavelength
C = speed of light
# dis = distance frequency
The computer 9 from, O + or Q- or # doppler can determine the distance and the speed of the target in all cases. So when the target speed is very low, we cannot measure the Doppler frequency on the flat part.

The Doppler frequency is then deduced from the measurements of t + and
When the Doppler frequency is close to the distance frequency #dis, you can access either $ + or # - depending on the direction of movement of the target relative to the laser.

This process therefore makes it possible to directly obtain the speed and the relative distance between the laser and the target.

We also know that the spectrum of laser diodes evolves as a function of temperature. This development is detrimental to the processing of the signal collected by the photodetector. For this reason, it is necessary for high measurement accuracy to regulate the temperature of the laser diode so as to obtain a current ramp producing ramps of emission wavelength as linear as possible.

As shown in Figure 3, where the circuits of Figure 1 are shown schematically by the rectangle C, the thermal regulation device comprises, in a conventional manner, two thermoelectric elements Peltier II and 12 connecting an aluminum radiator 13 to a plate of copper 14 on which is fixed, for example by screws not shown, the base 10a of the housing 10 containing the laser diode 1 and the photodiode 3. The housing 10 is of revolution around the optical axis XX of the laser.

Two thermistors 15a, 15b embedded in the plate 14 symmetrically with respect to the axis of the housing 10 provide a signal representative of the temperature of the laser.

An electronic circuit 16 elaborates in an known manner an error signal by comparison of the measured temperature with a set value and uses this signal to regulate the current passing through the Peltier elements II and 12 to heat or cool the plate 14 according to the sign of the signal error.

The method and the device according to the invention have been tested with the lasers below:
- the HITACHI HL7806 laser diode with which the
maximum measurable distance is 1 meter;
- the SDL5400 laser diode from SPECTRA DIODE LABS which
comes for a maximum distance of 50 meters;
- a multi-electrode DFB laser, of equal diode length
at 1500 nm and a line width close to 1 MHz, per
putting to measure distances greater than 100 meters.

This latter laser has the advantage of presenting an area where the wavelength is tunable without the emission power varying. Therefore, the current of the detector photodiode is no longer affected by the image of the modulation of the laser current.

The measurement accuracy can reach the micrometer for distance - and 0.5 mm / s for speed. These measurement accuracies are independent of the absolute distance measured.

The above experiments show that the implementation of the device is independent of the structure of the laser and that a maximum measurable distance greater than 100 meters can be reached with lasers with a line length less than 1 MHz.

Claims (10)

1. Obstacle detection method intended in particular to measure the distance and the speed of moving targets, of the type using optical homodyning of a frequency modulated laser beam, characterized in that it consists in detecting the beats between I wave emitted (Sî, S2) by the laser (1) and the echo (Eî, E2) diffused by the target (2) and previously amplified by the passage through the laser cavity before being mixed with the wave issued. 2. Method according to claim 1, characterized in that the emitted laser beam is modulated according to a double ramp law, each ramp being linear and of slope opposite to the associated ramp. 3. Method according to claim 2, characterized in that the modulation law comprises portions at constant frequency interposed between the double ramps. 4. Method according to I "any one of claims 1 to 3, characterized in that it consists in using the photodiode of control (3) of a laser diode (1) to detect the beats between the emitted wave (S2) by the rear face of the laser and the echo (E2), returned by the target (2), of the wave (S1) emitted by the front face of the laser. 5. Device using the detection method according to any one of the preceding claims, characterized in that it comprises a laser (1) emitting by its two faces and means (5) frequency modulating the laser current. 6. Device according to claim 5, characterized in that it comprises a single electronic component for transmission and reception, this component comprising in the same housing (10) a laser diode (1) and a photodiode (3), the laser diode emitting from its front face towards the target (2) and from its rear face towards the photodiode.  7. Device according to claim 6, characterized in that it comprises a single lens (4) collimating towards the target (2) the wave (S1) emitted by the front face of the laser diode as well as the wave (El) diffused in return by the target towards the cavity of the laser diode. 8. Device according to claim 7, characterized in that the single lens (4) is of the index gradient type. 9. Device according to any one of claims 5 to 8, characterized in that it comprises a device (11-16) for temperature regulation. 10. Device according to claim 9, characterized in that the temperature regulation device comprises a radiator (13) connected by thermoelectric elements (11,12), using the Peltier effect, to a support plate (14) of the laser, the current of these elements being controlled by the difference between the temperature of the support plate and a set temperature.