DE3710789A1 - Method for passive measurement of liquid films and/or foam layers on water - Google Patents

Abstract

A method for passive measurement of liquid films and/or foam layers on water by measuring the radiation temperature by means of at least one radiometer is proposed, in which in order to determine unambiguous values relating to the type and thickness of the oil film the measurement is performed from two different angles of view. <IMAGE>

Description

The invention relates to a method for the passive measurement of rivers liquid films and / or foam layers on water by measuring the Radiation temperature using at least one radiometer.

The measurement of liquid layers on water with microwave devices ten has grown in importance in recent years. Linking active and passive sensors (radar systems / radiometers) showed that Presence, expansion and oil thickness (assuming a maximum thickness) are determinable. More on this is the literature references

• (1) K. Grüner
  "Measuring Oil of Sea by Means of an airborne 90 GHz Microwave Radiometer"
  IRS ISPRA, report EUR EN 1985 and
• (2) K. Grüner, F. Witte, H. Schreiber, W. Keydel
  "Contribution to Oil Spill Detection and Analysis with Radar and Microwave Radiometry Results of the Archimedes II Campaign"
  Proc. of IGARSS '86, Zurich, 1986,

refer to. The high-resolution active systems (e.g. X-Band SLAR or L-band SAR) enable the discovery of oil films, their position and Shape (extension). The passive systems (radiometers) can do better Determination of the layer thickness and possibly the type used will. These systems are particularly suitable for the measurement of Films of oil on sea water.

Since the passive measurement of layers on water is a Two-layer problem (air-oil, oil-water) negotiates (see Fig. 1)

• (3) Ulaby, FT Moore, RK Fung, AK
  "Microwave Remote Sensig", Vol. III "From Theory to Applications"
  Artech House, 1986),

passive measurements are ambiguous. Different thicknesses result namely the same radiation temperatures and additionally for the same thickness depending on the type of oil different radiation temperatures measured.

It is the aim of the invention to provide a method of the type mentioned at the beginning to create, which makes it possible to take clear measurements.

According to the invention this is achieved by the in the characterizing part of Claim 1 measures achieved.

This makes both a measurement of the oil film thickness and a determination oil type. There is a provision for other liquids the dielectric constant and the layer thickness possible.

Details of the invention emerge from the subclaims and Description in which the basis of the drawing is discussed and Applications are described. It shows

Fig. 1 is a schematic representation of the boundary layer conditions in a film of oil on water,

Fig. 2, the difference between the radiation temperature of the sea water, and an oil film at 35 GHz,

Fig. 3, the difference of the radiation temperature of the water and oil film at different viewing angles at a Radiometer frequency of 35 GHz,

Fig. 4 is a further illustration of the difference of the Strahlungstemperatu ren of water and oil film at different angles Betrachtungswin at a radiometer frequency of 35 GHz,

Fig. 5 is an illustration of the difference in brightness temperatures of the water and oil film at different viewing angles for a radiometer frequency of 90 GHz,

Fig. 6 shows schematically the arrangement of two "pushbroom" -Radiometern for performing the method according to the invention,

Fig. 7 is a block diagram of the individual receiver used in the subject of Fig. 6.

Fig. 1 shows a schematic representation of the boundary layer relationships in an oil film on water, as are known from the literature mentioned. The nadir angle with R ₁ and the Dielectric constant with ε 'and ε ''respectively.

The following factors must be taken into account when selecting the frequency for the measurement be viewed:

• a) the least possible influence of the atmosphere
• b) Highest possible frequencies (better geometric resolution)
• c) low ambiguity, d. H. the wavelength must be greater than that Be oil film thickness,
• d) the existence of other radiometers for performing comparisons measurements.

The factors b) and c) contradict each other - a high frequency means low wavelength, what z. B. Uniqueness only for thin oil films results.  

It has been shown that an acceptable compromise between the four factors are the frequencies of 35 GHz and 90 GHz. The radiometer can then by using two viewing angles and the two frequencies of oil thickness dissolve to about 3 mm. For thicker films the combination is 10 GHz / 35 GHz cheap; this means that oil thicknesses between 3 mm and 7 mm can be resolved. The radiometric resolution must be approximately for both types of radiometer 1K or better.

The system according to the invention focuses on thin oil films; therefore, the frequencies 35 GHz and 90 GHz selected.

Fig. 2 shows the difference between the radiation temperature of the sea water and an oil film. The measuring frequency is 35 GHz. The parameter is the observation angle measured to the nadir. The polarization is horizontal. The coherent emissivity model as described in (3) on page 1470 ff. And with the results of

• (4) Hollinger, JP
  "The Determination of Oilk Sticks by Means of Multifrequency, Passive Microwave Techniques"
  Dept. of Transp. Report, No. CG-D-31-75, U.S. Coast Guard, Office of Research & Development, Washington DC

matches.

The function shown is dependent on the oil type, since the dielectric constant and thus the reflection factor of the oil change with the oil type. (3) indicates that mainly the real part ε ′ of the dielectric constant changes for the majority of the oil types. In addition, the imaginary part ε '' is generally very low (0.01, compared to a real part between 1.8 and 2.6).

In Fig. 3 radiation temperatures for three different ε 'are shown, the coordinates indicating the radiation temperatures for the nadir angle 0 ° (perpendicular to the surface) and 50 °. In addition, the film thicknesses are entered in FIG. 3.

If the radiation temperatures for curves of the type, as shown in FIG. 3, are available from calibration measurements or calculations, the oil thickness in a range from 1 mm to 3 mm and the oil type can be clearly determined with two temperature measurements. To simplify this, the different temperature values for the same thickness and different ε 'values are combined. The result of a model calculation shows Fig. 4.

Thickness measurement is possible in the range 0 mm to 1 mm, however not a determination of the oil type. For this, the second frequency, 90 GHz, used, which provides clear values for the range 0 mm to 1 mm.

Fig. 5 is a representation of the temperature pairs for the frequency 90 GHz with ε 'between 1.8 and 2.6 ( ε ''= 0.01), and thicknesses in 0.1 mm steps.

In summary, oil film thickness and oil type can be determined by measuring four radiation temperatures (two frequencies, two observation angles) and using contour lines ( FIGS. 4 and 5).

As is well known, the "pushbroom" method enables

• (5) Künzi, K., Skou, N., Pontopiddan, K.,
  "Study of Push-Broom Radiometer Systems",
  Final report ESTEC Contract No. 5792/84 / NL / GM (SC)

an increase in integration time without a reduction in geometric Triggered by replacing the antenna swivel with a series of Radiometers.  

Embodiment Imaging system

The following table summarizes the most important parameters of a system for an altitude of 500 m (approx. 1500 feet). According to FIG. 6, it consists of two “pushbroom” radiometers, one installed in the plane transversely to the direction of flight, the second installed with a nadir angle of 50 °. Each radiometer consists of an array of two-frequency receivers. Fig. 7 shows a block diagram of the single receiver. The use of a two-frequency horn enables the construction of compact "pushbroom" systems.

Frequency35 GHz Number of Radiometers21 "Swath range ± 25 ° opening angle of the
Single radiometer 1.7 ° noise temperature
"System noise temperature" 2000 K noise figure 9 dB For flight altitude 500 m, flight speed 200 km / h Geometric resolution
(middle radiometer) 14.8 m integration time 0.25 seconds radiometer resolution 0.125 K

Claims (8)

1. A method for the passive measurement of liquid films and / or foam layers on water by measuring the radiation temperature by means of at least one radiometer, characterized in that the measurement is carried out from two different angles in order to determine clear values with regard to the type and thickness of the oil film. 2. The method according to claim 1, characterized in that two different frequencies are used. 3. The method according to claim 1 or 2, characterized in that by comparing the measured values with specified calibration measured values type and thickness of the film or layer can be determined. 4. The method according to claim 2 or 3, characterized in that the two frequencies are around 35 and 90 GHz. 5. The method according to claim 2 or 3, characterized in that the two frequencies are around 10 and 35 GHz. 6. The method according to any one of the preceding claims, characterized characterized in that for viewing angle variation at least two under radiometers rigidly arranged at different angles can be used. 7. The method according to claim 6, characterized in that the Radiometer in an airplane or spacecraft at a nadir angle (Angle to the vertical) of 50 ° and 0 °. 8. The method according to claim 7, characterized in that as Radiometers so-called "Pushbroom" radiometers, each with two frequencies Receiver arrays are used.