DE10112078B4 - Apparatus for radioacoustic remote measurement of meteorological parameters - Google Patents

Abstract

contraption for radioacoustic remote measurement of meteorological variables, which emit electromagnetic waves and acoustic waves into the atmosphere, the electromagnetic waves scattered back on the acoustic waves Waves is received and about the Frequency or phase angle of the received electromagnetic waves determines the sound propagation speed, characterized that at least one electromagnetic antenna two or more sound sources spatial are arranged and the amplitude or the amplitude and phase of the of them emitted acoustic waves in dependence of it lying height profile of the wind vector is varied, in particular that only one depending of the height profile the wind vector changing selection of sound sources is operated.

Description

radio Acoustic Probing systems (RASS) are used to meteorological from the ground To televise sizes, which depend on the propagation speed of the sound. This are essentially the temperature of the air (more precisely, the virtual Temperature), which is the speed of sound within the medium influenced, and the wind speed and direction, which the Movement of the medium opposite describe the fixed system. Besides the means others can statistical or derived variables, in particular for turbulence measurement.

applications for RASS lie u. a. in meteorological research and routine measurement, the Air Quality Monitoring and the flight safety.

in the Operation sends a RASS electromagnetic waves and acoustic Waves in the atmosphere out, receiving the electromagnetic waves scattered back on the acoustic waves Waves and determines their mostly relative frequency or phase shifts. Using the theory of the Doppler effect and taking into account the geometry of the wave radiation becomes the sound propagation velocity, usually based on a spatial direction, determined.

to Measurement of the horizontal or three-dimensional wind vector must be the electromagnetic or the acoustic waves or both in more as a preferred spatial direction (preferred direction) are emitted. To achieve changeable Preferred directions can Phase array antennas or phase array sound sources are used where individual juxtaposed elements with defined radiate towards each other related phase shift.

A spatial resolution Measurement of wind and temperature profiles is over the life of the electromagnetic Waves or the acoustic waves or both waves, to determine the electromagnetic waves or the acoustic Waves or both waves are pulse or frequency modulated (eg electromagnetic pulsed operation or electromagnetic FM-CW operation or electromagnetic CW operation with acoustic pulse operation).

One The prior art RASS is z. By W. M. Angevine, W.L. Ecklund, D.A. Carter, K.S. Gage and K.P. Moran in the journal "Journal of Atmospheric and Oceanic Technology ", Volume 1994, Volume 11, pages 42-49.

A fundamental problem of the RASS is the drifting of the acoustic waves through the wind, as in the 1a and 2a (Vertical section) as well 1b and 2 B (Horizontal supervision) for six measuring heights is clarified. Identical positions of the electromagnetic and the acoustic transmission were assumed here ( 1 ). When Angevine et al. This is approximately achieved by the fact that four sound sources are mounted directly on the sides of a square electromagnetic antenna and operated simultaneously.

The effective beams ( 2 ) are spatially limited by the radiation characteristics of the electromagnetic antenna and the sound source. Due to the almost spherical shape of the transmitted acoustic and electromagnetic wavefronts ( 3 ), especially in the far field, are used in calm weather ( 1a and 1b ) the electromagnetic waves from all heights approximately to the antenna position ( 1 ) backfocused. Atmospheric turbulence easily disturbs the wavefronts, causing the focal spot ( 4 ) is widened.

At not insignificant wind speed ( 2a and 2 B ) focus the beams ( 2 ) from the different heights ( 3 ) not in the same place. The focal spot ( 4 ) is shifted horizontally depending on the measuring height and in the example of the illustration no longer hits the antenna. The size of the displacement vector is in very good approximation the product of the mean horizontal wind vector and the sound propagation time up to the measuring height. The size of the focal spot increases with the measured height due to the growing turbulence effect.

In the previously known RASS, the wind drift of the acoustic waves either leads to a limitation of the wind speed range within which a measurement is possible, or to a limitation of the possible measuring height. Often the Windverdriftung is compensated by the fact that the sound source is carried out spatially and their position of the lettering is offset in opposite directions. G. Peters, P. Thomas and M. Bauer in "Third International Symposium on Tropospheric Profiling", Extended Abstracts, pages 320-322, and D. Engelbart, H. Steinhagen, U. Gorsdorf, J. Lippmann and J. Neisser in the journal "Contributions to the physics of the atmosphere", born in 1996, Volume 69, No. 1, pages 63-80 describe systems in which the position of the sound source can be changed mechanically via a motor-driven adjustment. This Ver Driving has three major disadvantages: First, the technical complexity and the susceptibility of a motor-driven adjustment is considerable. Secondly, the position of the sound source can be optimized only for one measurement height, u. U. can therefore be measured at the same time only in a height range. Third, with an unknown wind profile, especially after a business interruption, the optimal position of the sound source must be determined only time consuming by mechanical adjustments. The invention has for its object to avoid the above-mentioned disadvantages.

The Task is solved by that several sound sources in fixed spatial distance from each other are arranged and a (changing) selection from it at the same time is operated. The selection takes into account that in dependence Windpro fils only a part of the sound sources acoustic waves which emanates to a reflex affecting the antenna electromagnetic Waves lead.

The exclusive Operation of only each required sound sources dictates the Minimization of energy demand, the number of circuit technology required Power components and noise pollution. For further energy optimization and noise reduction, the amplitude individual sound sources are reduced as much as the signal-to-noise ratio at the measurement of the reflex from the assigned altitude range allowed.

meaningful Arrangements of the sound sources, in particular the maximum distances between the sound sources, can from the size of the focal spot, the desired wind speed measuring range (possibly as a function of Wind direction) as well as the measuring height to be achieved according to the above in easy way to be found. When determining the focal spot size are because its turbulence dependence to consider the given microclimatic peculiarities of the place of measurement.

Which Sound sources of an arrangement operated during a measurement respectively should be, can be easily derive from the described geometric considerations, if the wind profile is known. In the realization of the invention can this over an algorithm in which the measured with the RASS itself Wind profile is received. Alternatively or in addition, other information about the Wind profile be used, such as those over a (conventional) Radar operation of the RASS plant can be obtained. When radar operation is the frequency or phase shift of turbulent inhomogeneities or Particles (and not on sound waves) backscattered electromagnetic Waves evaluated.

Of the Algorithm for determining the amplitude or to select the operated Sound sources can take place in the digital computer unit of the RASS, in which the evaluation of the frequency or phase takes place. The further circuit-wise implementation This control within the facility can be based on various simple Wise things are realized so that it needs no further execution here. The Signal-to-noise ratio can be at a distance-resolved Measurement for each distance level also determined separately in the computer unit and get into the control.

3a shows the example of an arrangement of sound sources ( 5 ) around an electromagnetic antenna ( 1 ) in the supervision. For the wind conditions, as in 2 It would be useful to operate the sound sources marked with black circles in the drawing. 3b shows the resulting focal spots ( 4 ). It can be seen that from each of the six height ranges a focal spot hits the antenna. The simultaneous measurement of the wind or the temperature in each of these heights is therefore possible.

Accordingly, in 3c an example of a sensible selection of powered sound sources (black circles) for a wind turning north to northeast. Again, from each of the six altitude ranges, a focal spot would fall on the antenna.

is the wind direction is not known after a business interruption, can be with a concurrent or expiring one after the other Operation of several groups of sound sources (approximately in a radial arrangement) the prevailing wind direction is determined much faster, as would be possible with the mechanical positioning of a sound source.

In the example of 3a and 3c the distance of the sound sources is greater than the wavelength of the sound. Due to a higher packing density, the opposite situation can be realized. Since each sound source is then necessarily smaller than the wavelength, no appreciable preferred direction can be achieved within the sound source more. However, it is then possible to influence the direction of the emitted sound by a coherent control of the phase differences between the individual sound sources.

The above description is not only related to those types of RASS that alternately transmit and receive with the same antenna (monostatic systems, in particular with pulsed operation or alternating operation), but also on sol systems in which different antennas, often simultaneous, transmit and receive (bistatic systems, in particular FM-CW operation or CW operation). The geometric considerations for the arrangement and selection of the sound sources can be analogously transferred to such arrangements.

Claims (11)

Apparatus for radioacoustic remote measurement of meteorological magnitudes, which emits electromagnetic waves and acoustic waves into the atmosphere, which receives electromagnetic waves scattered back on the acoustic waves and determines the sound propagation velocity via the frequency or phase angle of the received electromagnetic waves, characterized in that at least one electromagnetic antenna two or more sound sources are spatially arranged and the amplitude or the amplitude and phase of the acoustic waves emitted by them is varied in dependence on the overlying height profile of the wind vector, in particular that only one depending on the height profile of the wind vector changing selection of the sound sources is operated. Device according to claim 1, characterized that uses an alternating and receiving antenna or at least two antennas are used, the ones of an electromagnetic waves emitted from an antenna other antenna are received. Device according to one of the preceding claims characterized characterized in that a distance resolution of the measurement over the Term of electromagnetic waves or acoustic waves or both waves and that to determine the maturity the electromagnetic waves or the acoustic waves or both waves are pulse or frequency modulated. Device according to one of the preceding claims characterized characterized in that from the measurement of the sound propagation velocity the temperature or the virtual temperature of the air is derived becomes. Device according to one of the preceding claims characterized by characterized in that the electromagnetic waves or the acoustic Waves or both waves in a number of different preferred directions to be sent out. Device according to claim 5, characterized that from the measurement of the sound propagation velocity in the different preferred directions derived information about the height profile of the wind vector become. Device according to claims 5 or 6, characterized that the preferred directions of the antenna by phase differences between individual elements within the antenna, in particular accomplished in the form of a phase array antenna, will be realized. Device according to claims 5, 6 or 7, characterized that the preferred directions of the sound sources by phase differences between individual elements within the sound source, in particular executed in shape a phase array sound source, or by phase differences between be realized the sound sources. Device according to one of the preceding claims characterized characterized in that, in particular simultaneously or via a running change of mode, in a radar mode information about that height profile of the wind vector from the backscatter electromagnetic waves at non - sound inhomogeneities of the the atmosphere be won. Device according to claims 6, 7, 8 or 9 thereby characterized in that information obtained about the height profile of the wind vector for Control of the amplitude variation described in claim 1 or the amplitude and phase of the emitting sound sources, in particular to their selection for the operation can be used. Device according to one of the preceding claims characterized in that the signal-to-noise ratio assigned to the different measurement heights is assigned to Control of the amplitude variation described in claim 1 or the amplitude and phase of the emitting sound sources, in particular to their selection for the operation can be used.