Abstract:
Systems and methods for improving output of weather information. A weather radar system receives weather reflectivity values. A processing device stores the received weather reflectivity values into a three-dimensional buffer, calculates a sum of the reflectivity value stored in a column of cells within the three-dimensional buffer, and assigns a first hazard indication to the cells of the column when the result of the calculation is above a first threshold. A display device generates a weather display based on data stored in the three-dimensional buffer. The weather display includes a display icon associated with the hazard indication when a cell from the three-dimensional buffer has been selected for the weather display.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    Airborne weather radars are used to identify convective weather that generates turbulence that can be hazardous to aviation. The detection is typically based only on radar reflectivity of the weather that exists at a selected part of a storm. The degree of hazard is assumed to be related to this reflectivity. However, this is not always a valid assumption to make. 
       SUMMARY OF THE INVENTION 
       [0002]    An assessment of whether a convective weather cell is a hazard is more properly made by an evaluation of the amount of vertical development of the cell. The greater the vertical extent and amount of precipitation maintained aloft, the greater is the vertical air velocity, which then produces turbulence that is hazardous to aviation. Therefore, to improve the assessment of the degree of hazard resulting from convective weather, there is a need to include the amount of vertical development of convection. 
         [0003]    The present invention provides systems and methods for improving output of weather information. A weather radar system receives weather reflectivity values. A processing device stores the received weather reflectivity values into a three-dimensional buffer, calculates a sum of the reflectivity value stored in a column of cells within the three-dimensional buffer, and assigns a first hazard indication to the cells of the column when the result of the calculation is above a first threshold. A display device generates a weather display based on data stored in the three-dimensional buffer. The weather display includes a display icon associated with the hazard indication when a cell from the three-dimensional buffer has been selected for the weather display. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0004]    Preferred and alternative embodiments of the present invention are described in detail below with reference to the following drawings: 
           [0005]      FIG. 1  is a schematic block diagram of a system formed in accordance with an embodiment of the present invention; 
           [0006]      FIG. 2  is a flowchart of an exemplary process performed by the system shown in  FIG. 1 ; and 
           [0007]      FIG. 3  is a conceptual perspective view of a portion of a three-dimensional buffer used by the system shown in  FIG. 1 . 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0008]      FIG. 1  illustrates an aircraft  20  that includes a weather display system  30  for providing an improved radar return. The exemplary weather display system  30  includes a weather radar system  40  and a display/interface front-end  38 , and receives information from other aircraft systems  46 . The display/interface front-end  38  includes a processor  42 , memory  43 , a display device  44 , a user interface  48 , and a database  32 . An example of the radar system  40  includes a radar controller  50  (configured to receive control instructions from the user interface  48 ), a transmitter  52 , a receiver  54 , and an antenna  56 . The radar controller  50  controls the transmitter  52  and the receiver  54  for performing the sending and receiving of signals through the antenna  56 . The weather radar system  40  and the display/interface front-end  38  are electronically coupled to the aircraft systems  46 . 
         [0009]    Radar relies on a transmission of a pulse of electromagnetic energy, referred to herein as a signal. The antenna  56  narrowly focuses the transmission of the signal pulse. Like the light from a flashlight, this narrow signal illuminates any objects in its path and illuminated objects reflect the electromagnetic energy back to the antenna. 
         [0010]    Reflectivity data corresponds to that portion of a radar&#39;s signal reflected back to the radar by liquids (e.g., rain) and/or frozen droplets (e.g., hail, sleet, and/or snow) residing in a weather object, such as a cloud or storm, or residing in areas proximate to the cloud or storm generating the liquids and/or frozen droplets. 
         [0011]    The radar controller  50  calculates the distance of the weather object relative to the antenna based upon the length of time the transmitted signal pulse takes in the transition from the antenna to the object and back to the antenna  56 . The relationship between distance and time is linear as the velocity of the signal is constant, approximately the speed of light in a vacuum. 
         [0012]    The present invention uses the system  30  to obtain the three-dimensional distribution of radar reflectivity of weather using an airborne radar, perform integrations of the reflectivity in vertical columns, and evaluate the integrations. The result provides a degree of turbulence hazard information to the aircraft. Because of the nature of radar detection of weather, the present invention also identifies areas above and below the analyzed column that might present a turbulence risk. A top of the convective storm might actually be above the detected top because the reflectivity might drop below what can be detected by the radar at that range. Because of this, one embodiment allows for some margin above and below the column to account for the possibility that the hazard extends somewhat beyond the detected column because of radar limitations. 
         [0013]    The present invention uses a radar system capable of measurement of the three-dimensional distribution of weather reflectivity from which vertical integrations of reflectivity can be performed. An example radar system capable of measurement of the three-dimensional distribution of weather reflectivity is the IntuVue™ made by Honeywell International, Inc. 
         [0014]      FIG. 2  is a flowchart of an exemplary process  80  performed by the system  30 . First, at a block  84 , radar reflectivity values are received and stored by the processor  42  into a three-dimensional buffer located in the memory  43 . Next, at a block  86 , the sum of reflectivity values stored in a column of cells in the three-dimensional buffer is calculated. In another embodiment, an integration of the values in the column is performed. The system  30  vertically integrates the product of reflectivity values and altitude, each raised to some power. 
         [0015]    In one embodiment, an approximation of that integral is performed by 
         [0000]    
       
         
           
             
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         [0016]    where Z i  is the reflectivity of the i-th cell in the column, h i , is the altitude of the i-th cell in the column, N is the number of cells in the column in the 3D buffer, and Ah is the vertical size of the buffer cell. If a=1 and b=0 are used as the power values, then this is just a straight vertical integration of reflectivity (i.e., VIR). To compute vertically integrated liquid (VIL), which is a quantity that has been generated in the past using ground-based radar data, b=0, a= 4/7 are used, and the result is multiplied by a factor of 3.44e-6. This factor and the 4/7 exponent are taken from a power law relationship between weather reflectivity and liquid water content (LWC), which has units of kg/m 3 . 
         [0017]    In another embodiment, a= 4/7, b=1 are used as the power values. This turns the result into something like a potential energy. Potential energy of a mass (m) lofted to a height (h) is given by PE=mgh, where g is the gravitational acceleration. So if the reflectivity is converted to LWC (which is a mass-like quantity), times an altitude, the result is proportional to the energy that the vertical motion has expended to loft the water up into the atmosphere. More energetic vertical motion is expected to generate more energetic turbulence. 
         [0018]    At a decision block  88 , the processor  42  determines whether the result of the action performed at the block  86  is above a first threshold. If the result is above the first threshold, a hazard icon in a first format is generated and displayed on the display device  44 , see block  90 . After block  90 , the process  80  goes to a next column for analysis, see blocks  94 ,  86 . If the result is not above the first threshold, the processor  42  determines whether the result is above a second threshold, see decision block  98 . The actions after the decision block  98  are similar to those after the decision block  88 , except a hazard icon in a second format is outputted if the second threshold is exceeded. 
         [0019]    In one embodiment, the first and second formats indicate whether the hazard is a “moderate risk” (e.g., amber) or a “high risk” (e.g., magenta) hazard. Other hazard indications (color, geometric) may be used as well as more than two types of hazards. 
         [0020]      FIG. 3  is a conceptual perspective view of a portion of the three-dimensional buffer  120 . The buffer  120  includes a column  126  of cells that have been analyzed, as described above, and determined to be greater than the first threshold. The cells in the column  126  are associated with a corresponding hazard indicator. When any of the cells of the column  126  are selected for display, a hazard icon associated with the hazard indicator is displayed based on the cell location on the display device  44 . 
         [0021]    In one embodiment, the three-dimensional buffer is replaced with a conventional buffer for storing values from various radar sweeps at a particular latitude/longitude location or just adding a value from a radar sweep at a particular latitude/longitude location to a previous summation of values at that location. 
         [0022]    While the preferred embodiment of the invention has been illustrated and described, as noted above, many changes can be made without departing from the spirit and scope of the invention. For example, the reflectivity values can be obtained from off-aircraft sources (e.g., other aircraft, ground weather systems, etc.) Accordingly, the scope of the invention is not limited by the disclosure of the preferred embodiment. Instead, the invention should be determined entirely by reference to the claims that follow.