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ABBYNormal (1.2051014)

The ABsorption BY the D and E Region of HF Signals with NORMAL Incidence (ABBYNORMAL) model

Model Description 

The ABsorption BY the D and E Region of HF Signals with NORMAL Incidence or the ABBYNORMAL Model calculates the D and E region (60-150 km) ionization sources and ion-neutral chemistry to obtain an electron density profile. The physics-based models within AbbyNormal are identical to the Data-Driven D-Region model (DDDR), which was created under NASA/Living-with-a-Star funding (NASW-02108). The AbbyNormal Model (DDDR) has simplified D region chemistry. The number of minor neutral and ion species used within the DDDR is small compared to the enormous number generally present. However, the goal of the DDDR is to provide an electron density profile for the HF absorption calculation. Thus, much of the detail of the ion chemistry is ignored, but enough remains to include all important source and loss processes to obtain a good electron density profile.

The AbbyNormal electron density profile and MSIS neutral atmosphere are used to calculate HF signal loss in decibels per kilometer (Figure 1). The loss per kilometer is the integrated for the vertical transit. The E region is included because approximately 10% of the non-deviative absorption occurs in the E region.

More Detail:
The AbbyNormal model is a multi-level model, which includes the following components:

1) An empirical neutral atmosphere model (MSISE00)
2) Physics-based model of the electron-ion densities through the D and E region altitudes
3) High Frequency (HF) signal absorption calculation for HF ray paths through the ionosphere
4) Ionospheric conductivity calculation for vertically integrated Pedersen and Hall conductivities.

AbbyNormal combines these 4 components to predict the attenuation of an HF signal in transit through the earth's ionosphere. The attenuation depends on the electron and neutral density in the D and E regions. The electron gas of the ionosphere 'sees' the electromagnetic wave and damps the signal magnitude if the electron-neutral collision rate is similar to the signal frequency. The electron-neutral collision rate is near HF frequencies (1 to 30 MHz) at D and E region altitudes (60-105 km). Most HF signal propagation codes include this 'non-deviative' signal absorption by treating the D region as a thin shell, which attenuates a trans-ionospheric signal. The D-region absorption is often determined through empirical relations with solar angle dependence (1/cos c), HF frequency (1/f 2), and solar indices (F10.7). AbbyNormal uses physics-based models and formulate to calculate the attenuation.

We assume straight-line propagation within AbbyNormal for the HF frequencies of interest (3-50 MHz) because the low densities of the D region do not affect the HF propagation direction. The absorption calculation is performed for a single vertical transit of the HF signal, which is then adapted to non-vertical propagation by using the angle of incidence (1/cos I) for oblique transit absorption.

Model Figure(s) :

  • ABBYNormal Absorption Profile

    • Model Inputs Description 

    Remote sensing SMEI data from CASS/USU (Space Environment Corp.)

    Model Outputs Description 

    Vertically integrated absorption values in decibels for 5, 10, and 15 MHz HF signals.
Vertically integrated of Hall conductivity in mhos.
Vertically integrated of Pedersen conductivity in mhos.

These outputs are two-dimensional global maps. These are provided for the whole day requested at 30 minute intervals. The format of each files provides the geo-latitude and geo-longitude node information with the global output values. The files can be read using FORTRAN code:

READ(1,'(8X,I6)')NX 
READ(1,'(1P,6E12.4)')(GLON(I),I=1,NX) 
READ(1,'(8X,I6)')NY 
READ(1,'(1P,6E12.4)')(GLAT(J),J=1,NY) 
READ(1,'(8X,2I6)')NX,NY 
READ(1,'(1P,6E12.4)')((VALUE(I,J),I=1,NX),J=1,NY)

    Model Caveats 

    
	
	
	
	
    Change Log
		
	
    
	
    
	
	 
	
    Model Acknowledgement/Publication Policy (if any)
		
	
    
	
    
	
	
	
    Model Domains:
		
	
    
	
		Global_Ionosphere
    
	
	
	
    Space Weather Impacts:
		
	
    
	
	
	
    Phenomena :
    
	
		HF_Signal_Absorption
    
	

	
    Simulation Type(s):
		
	
    
	
		Physics-based
    
	
		
	
    Temporal Dependence Possible? (whether the code results depend on physical time?)
		
	
    
		true
    
		
    
    Model is available at? 
    	
	
    
		CCMC
    
		
	
    Source code of the model is publicly available?
    
		false
    
		
	 
    CCMC Model Status (e.g. onboarding, use in production, retired, only hosting output, only source is available): 
    	
	
    
		retired
    
	
	
    Code Language: 
		
	
    
		Fortran
    

	
    Regions (this is automatically mapped based on model domain):
    
	
		Earth.NearSurface.Ionosphere
    
	
	
	
    
		Contacts
		
		:
	
    
	
		J.Vincent.Eccles, ModelDeveloper 
		
    
	
		Jia.Yue, ModelHostContact 
		
    
	
		Katherine.Garcia-Sage, ModelHostContact 
		
    
	
		Masha.Kuznetsova, ModelHostContact 
		
    
	

	
    
		Acknowledgement/Institution
		
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		Relevant Links
		
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		Publications and Reports by Vince Eccles: http://www.spacenv.com/publications/eccles/index.html
		
		
    
	

	
    
		Publications
		
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		Model Access Information
		
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		Access URL: https://ccmc.gsfc.nasa.gov/requests/RunAbby/abby_local.php  
    
		
		Access URL Name: Instant Run
    
		
		Repository ID: spase://CCMC/Repository/NASA/GSFC/CCMC
    
		Availability: online
    
		AccessRights: OPEN
    
		Format: HTML
    
		Encoding: None
    		  
		
    
	
	
	
    
		Linked to Other Spase Resource(s) (example: another SimulationModel)
		
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