DE19941157A1 - Ultralight aircraft in composite construction can mount magnetic sensors directly avoiding position measurement errors - Google Patents

Abstract

The ultralight aircraft has a composite construction with ferromagnetic fixings avoided and carries differential GPS and magnetic sensors attached to aluminum struts (3,6,7) and (5) tubes fixed below the wings (2) and undercarriage (4).

Description

The invention relates to a method and Device for extracting soil data from the air with a missile moving close to the ground, its current Position during a probe flight by one differential satellite positioning system determined and synchronized in time with the measured soil data is recorded.

There are different types of missiles installed on them Systems known for exploring soil data with which data obtained using imaging or other methods become.

In particular, the acquisition of data on anomalies of the electromagnetic field on the earth's surface, the means data about near-surface, hidden ferromagnetic bodies such as duds, mines or other ferromagnetic contaminated sites, pipelines or Mineral deposits and underground watercourses, requires an investigation as close to the ground as possible  measurable field change only within a small Distance from the object to be located occurs.

DE 43 14 742 C2 discloses a method according to a rotary wing at a height of 40 to 50 meters an arial flies, its position from one differential satellite positioning system (DGPS) is determined. A magnetic field measuring probe is close to the ground on a towline at a distance under the rotary wing, in which the through the Missile-related field distortion is only low.

The location of the rotary wing aircraft is said to be differential satellite positioning system be accurate to the decimeter. But as in the patent specification has already been expressed, it comes in the case of surface probing too unwanted Relative movements between the rotary wing and the Sensors, that is, the tow rope, the depending on the function, a length of at least 35 meters has, comes from the flight movements and in addition vibrating through air movements so that the Position of the rotary wing aircraft no longer with the position the sensors can be correlated. The The speed of the rotary wing aircraft must therefore be limited accordingly. Already at relative low wind speeds can be a measurement can no longer be performed at all.

Also change the tilting and lowering movements of the rotary wing aircraft the relative position between sensor and Position measuring device. Attaching a GPS antenna directly at the sensor, i.e. at the lower end of the tow rope can the accuracy of the location of the Increase sensors, but in turn has a disruptive effect  the sensors. The arrangement also allows one Sensor on a tow rope only a punctiform Sensor technology with which the measuring speed of is limited in advance.

The measuring accuracy and the measurable measuring range in The depth direction of the soil is strongly dependent on that Distance of the sensor from the earth's surface, which is at an altitude of 40 to 50 meters and a swinging and swinging tow rope also with high flying experience is not exactly constant holds and for safety always at least 5 meters must be. The measurement data therefore scatter in one wide area.

The measurement sets accordingly good Weather conditions ahead and is even on one low measuring speed and a limited Measurement accuracy limited, moreover, the use of a rotary wing aircraft is associated with considerable costs.

The invention has for its object a method and specify a facility with which soil data with greater measuring speed and still with great measurement accuracy and high spatial correlation can be won.

According to the invention the object is achieved by Features of claims 1 and 2. Appropriate Refinements are the subject of the dependent claims.

Then the data is overlaid by means of a near ground level surface of flying fixed-wing aircraft to be probed, preferably a fixed-wing aircraft in ultralight Construction method, or one over the surface to be probed  floating hovercraft by at least one Won sensor, which (the) at the bottom of the Fixed wing or hovercraft is (are) attached.

Ultimate light aircraft can be at a very low altitude flown are easy and still efficient and form due to their composite construction the requirement that sensors directly on their Bottom can be fixed without ferromagnetic parts of the missile to be measured significantly distort magnetic field. Outside on Missile still existing ferromagnetic sheet metal parts and axes, bolts, etc. can also easily counteract Parts made of non-magnetic material are replaced, as well as components within the missile. The Sensors can be suspended from the wings and / or be attached to the landing gear in the case of low-wing aircraft also directly on the wings. With air cushions they will be vehicles just below the platform appropriate.

Ultralight aircraft are also cheaper than Rotary wing aircraft and also environmentally friendly. For your Use is only a low flying permit for required the pilot.

The extremely close-to-ground data acquisition enables this Use highly sensitive sensors for both recording electromagnetic field data as well as others to Example of gas sensitive sensors. Gas sensors could be used for Example of mine exploration can be used that have no ferromagnetic housing body and therefore not by electromagnetic field measurement are tracked down.  

Data acquisition can take place at high airspeed take place, with the possible multiple arrangement of sensors side by side a large working width and not just a much higher area coverage per flight, but also high data security is achieved because the measuring ranges of the sensors are different can partially cover. The resolution of the measurement is a multiple of the previous data extraction process. Not just the detectability smaller objects, but also the measuring range depth in the ground is increased.

Since the sensors are attached to the missile, exists in every flight or hover phase a clear correlation between the measured Data and the position, so that from the recorded data without any subsequent Correction of an area image with the found Obtained objects and on cartographic material can be transferred.

The probing is carried out in a known manner meandering or row-shaped Overfly the area to be examined, all Data measured by the sensors together with the associated position data constantly to be recorded.

The position data are indicated by a differential satellite-based positioning system (DGPS) won at over the position determined by GPS receiver a reference station at a fixed location in the The proximity of the area to be probed continuously corrected  is, so that accuracy of positioning of ± 0.2 m can be reached:

The procedure is described below using a Embodiment are explained. In the show associated drawings

Fig. 1 is a furnished for performing the method ultralight aircraft in front view,

Fig. 2 shows the ultralight aircraft according to FIG. 1 in side view

Fig. 3 is a block diagram of the measurement and location system.

In Fig. 1, 2, the side view of an ultralight aircraft 1 is the front view shown in Fig., Which is equipped for magnetic field probe with an appropriate sensor system. On an aluminum tube 5 suspended from struts 3 , 6 and 7 on the wings 2 and on the landing gear 4 , six magnetic field sensors, not shown here, are attached at a distance of approximately 2 m.

The ultralight aircraft 1 is constructed from a non-field-distorting aircraft body in a composite construction and has a total mass of approximately 450 kg. To carry out the measuring process, equipment provided from the factory made of a ferromagnetic material or those containing ferromagnetic parts are used against plastic parts or non-ferromagnetic metal parts, e.g. B. exchanged from aluminum or V2A steel. For example, they are. Bearing of the flaps and all rudders, the axles and axle supports on the landing gear, wheel bolts and brake discs have been replaced with non-magnetic parts. Except for the motor, the ultralight aircraft 1 can thus be almost completely cleared of ferromagnetic parts. Remaining ferromagnetic parts no longer interfere with the measurement or can be included in the calibration of the magnetic field sensors.

The magnetic field sensors are Total field magnetometer, which has a recording rate of have several hundred recordings per second, which means flying at speeds above probing area up to 150 km / h can.

The ultralight aircraft 1 can be flown at a height of up to 1 m. The flight direction and the flight altitude can be adhered to more precisely than with a rotary wing aircraft, since the directional stability is much higher. The flight altitude can be maintained with a tolerance of ± 0.5 m and the flight direction can be measured with a tolerance of ± 0.2 m.

Through variable distances between the magnetic field sensors on the aluminum tube 5 , in addition to the setting of the working width, the number of sensors can also be selected. Attachment and removal are straightforward with fixed connections. The fixed connections are designed in such a way that the sensors can also be changed in position (rotation, angular adjustment).

Due to the low flight altitude, a high resolution is the Measurement achievable, so that even small ones  ferromagnetic objects can be reliably recognized. So are z. For example, bullets with a caliber of 8.8 mm are safe to locate.

The measured data can be correlated exactly with the position of the magnetic field sensors, since there is only a negligible relative movement between the magnetic field sensors and a DGPS receiver on board the ultralight aircraft 1 .

As is known, the associated location data are determined by means of a differential satellite-based positioning system (DGPS). Here, a DGPS receiver on board the ultralight aircraft 1 works together with a DGPS reference station, which is placed, for example, at the edge of the area to be probed and can send signals to the DGPS receiver in the ultralight aircraft 1 . The reference station as well as the DGPS receiver on board the ultralight aircraft 1 receive the location signals from several satellites, which are compared with one another. Correction values are continuously formed from the comparison and are taken into account in a central computer on board the ultralight aircraft 1 when recording the position.

With the reference station, the DGPS receiver is also able to determine not only the exact position data in the xy plane above the terrain to be probed, but also the exact height above the ground (z direction). This is done by evaluating the angular position of the ultralight aircraft 1 relative to the reference station. A separate altimeter can therefore be dispensed with.

Fig. 3 shows a block diagram of the measurement and positioning system that manages the flight guidance data simultaneously. All data is processed by a central computer, which then also records the flight data, the measurement and the position data, which can then be output and evaluated in graphical form after the end of a probing flight.

Reference list

1

Ultralight aircraft

2nd

Wings

3rd

strut

4th

landing gear

5

Aluminum tube

6

strut

7

strut

Claims (7)

1.Procedure for obtaining ground data from the air with a missile moving close to the ground, the current position of which is determined by a differential satellite-based positioning system (DGPS) during a probing flight and is recorded synchronously in correlation with the measured ground data, characterized in that the data are recorded using a close to the ground above the surface to be probed flying fixed-wing aircraft, preferably a fixed-wing aircraft in an ultralight design, or an air cushion vehicle floating above the surface to be probed can be obtained by at least one sensor which is (are) firmly attached to the underside of the fixed-wing aircraft or the air cushion vehicle ). 2. Device for obtaining ground data from the air with a missile and a differential satellite-based positioning system (DGPS) characterized by at least one sensor permanently attached to the underside of a fixed-wing aircraft ( 1 ), preferably a fixed-wing aircraft in an ultralight design, or a hovercraft. 3. Device according to claim 2, characterized in that ferromagnetic parts of the fixed-wing aircraft ( 1 ) or the hovercraft are largely replaced by plastic or non-magnetic metal parts. 4. Device according to claim 2 or 3, characterized in that the sensor or sensors Magnetic field sensors are. 5. Device according to claim 2 or 3, characterized in that the sensor or sensors Are chemical sensors. 6. Device according to one of claims 2 to 5, characterized in that the sensor or sensors under the wings ( 2 ) and / or on the landing gear ( 4 ) of a fixed-wing aircraft ( 1 ) are attached. 7. Device according to one of claims 2 to 5, characterized in that the sensor or sensors under the platform of a hovercraft are attached.