Getting started with the 4NEC2 version 5.7.6 visualization and optimization tool for NEC-2/4.
(latest update: Nov 11, 2009)

Note:	You can push F1 when a certain form/window is active to get context sensitive help for
	the particular window/form.

Content:

1) Create an antenna model using 'Geometry Edit'.
2) Show structure; generate data and view currents and phase distribution.
3) Generate Far-field data and view 2D polar and 3D far field patterns.
4) Generate frequency loop graphical-data.
5) Optimize antenna performance.
6) Sweep antenna variables.
7) Generate and view Near-field data.
8) Generate and use ItsHF Area-Coverage propagation data.
9) Generate and use ItsHF point-to-point propagation data.
	
	Before starting this tutorial, note that there are two different ways of using the 
	4nec2 program. The first way is recommended for the starting modeler and uses the 
	drawing-style 'Geometry editor' to create or modify an antenna model. This method 
	however does not allow the user to directly use the traditional- and/or genetic-
	optimizer functions. The second is a more textual entry of your antenne model using
	X, Y and X coorinates in numeric form.


	To use the optimizer or sweeper it is required that the model includes at least 
	one variable (SYmbol) to optimize. These variables however can only be specified using 
	the 'Notepad' or 'NEC' editors. How to specify and use SYmbolic information is descri-
	bed in the items 2 to 8 below

	For these items 2 to 8 it is helpful if the reader has some basic knowledge about 
	modelling 3-dimensional wire structures, using Nec-2 or Nec-4. Especially the use
	of GW, EX, FR and LD cards. Information's about this can be found in the initial
	pages of the Nec-2 user-manual named 'nec2.doc' available in the ..\4nec2 folder on
	your computer.


1) Create an antenna model using 'Geometry Edit'

	As a starting-point we will create a basic 20-meter dipole fed with 50-ohm feedline.

	To show none-metric unit usage we consider ourselves for a moment as an US-citizen 
	using Inch and Feet as the basic length unit....

	The below specifications apply:

	- antenna height 	70 feet
	- wire length		33.7 feet
	- wire radius		#12 AWG
	- feedline length 	69 feet	(electrical length)

	First we open one of the existing example files (e.g. 36dip.nec). If not already 
	done so, specify 'Geometry Edit' as the prefered Edit method using the 'Settings' 
	menu on the 'Main' window. Furthermore select 'Feet' as the length-unit and 'Inch/Awg'
	as the 'radius-unit' using this same 'Settings' menu.

	When done, select 'Edit -> Input-file' on the 'Main' window or use the <F6> key to 
	start 'Geometry-edit'. A picture of the selected example file is displayed. If not 
	already set, select 'Options -> Set Segmentation -> Medium' on the Edit window to set
	medium segmentation density

	To create a new model, Select 'File -> New' on the Edit-window.

	*) Setting design frequency

	When starting a new model, initially on the lower right,  frequency 'data' is displayed. 
	This because one of the first things we will have to do is specifying the antenna 
	design-frequency. Enter 14.15 (MHz) in the 'frequency' text-box on the right part of 
	the window. When entered, click the 'wire' button on top of the window (the one with
	the single line in it). Notice the grid-size changing from .025 to .5 feet, correspon-
	ding to about half a wavelength for the window-width. Furthermore the default 3D-
	display view is now set to 2 dimensional XZ plane. (The Y-axis is pointing backwards)

	*) Add new wire(s)

	To start adding a new wire, click the 'Add' button. The mouse-pointer changes to a
	cross-hair, indicating 'Add-mode' is activated. The Y-position text-box on the right
	is now highlighted. If required you can specify a certain 'depth' position, but for
	now we will stay in the XZ-plane for an Y-position equal zero.

	When you will try to locate a mouse-pointer position for which the height Z equals 
	70 feet, you shouldn't succeed, because the grid-size is too small to cover a Z posi-
	tion of 70 feet. 
	First increase grid-size to 1 feet by clicking on the left arrow for the 'Zoom' 
	scroll-bar. When done, point somewhere inside the picture-box (that part of the 
	window where the antenna structure is displayed), hold down the right mouse-button
	and move the X-axis to almost at the bottom of the picture-box. Now you should be
	able to locate a position for which Z equals 70 feet somewhere in the upper region
	of the picture-box.

	Because we want to create a line at Z=70 feet with a length of 33.7 feet we will
	have to locate a point for which Z = 70 and X = -33.7/2 = 16.85 feet. However, 
	because the 'Snap to grid' box is checked you won't succeed in this. For now we 
	will locate a position for which X equals -17 feet.

	To start drawing the wire, click and hold down the left mouse-button and drag the 
	mouse-pointer to the second position for which Z=70 and X=17 feet, then release the
	mouse-button. Because this is the first wire added to the model, a pop-up window is
	displayed asking for the initial/default wire diameter. Use the supplied default of
	.05 inch.
	Now the first wire, the dipole itself, is created. On the right of the picture-box
	all data belonging to this wire is listed. You can edit the end-1 or end-2 coor-
	dinates text-boxes to further refine the end positions. You will also notice that
	the number of segments is set to 25, corresponding to 'medium segmentation'.

	The second wire, to connect the other end of the feedline, is done the same way by 
	drawing a line from x=-1 to X=+1 for a height Z=1. This second wire is automatically
	divided into 3 segments. Because we only need this wire to attach one end of the 
	feed-line, manually change the number of segments to 1. 

	Don't worry in case you did not position the wire-ends at the right coordinates. To
	move wire-ends, click the 'pointer' button and place the mouse-pointer on the wire-
	end to move. The mouse-pointer should now change to four-arrows, meaning you can move
	the wire end. Hold down the left-mouse button and move the wire end to the required
	position. As an alternative you can also directly edit the end-1 or -2 XYZ values.

	*) Add feed/transmission-line(s)

	Next we will have to add the feedline. But, before doing so we need some knowledge
	about how wires are identified in Nec-2/4. All wires are assigned a unique tag-nr.
	Mostly the tag-number equals the wire-number. Ater delete, copy or paste operations
	however this sequence may have changed. Tag-numbers should still be unique. You may
	use 'Resequence tag-numbers' in the 'Option' menu to make tagnumbers equal to the 
	corresponding wire-numbers again.  

	Each voltage/current-source, transmission-line or RLC-load (see below) is 'assigned'
	to a wire using this unique tag-number. To specify the position of the source, TR-
	line or load on the specified wire a segment-number between 1 and the nr-of-segments
	for the wire is used.  

	Using Geometry-edit these tag- and segment-numbers are automatically assigned. It is
	allowed to change these number manually. When doing so please note how these tag- and
	segment-numbers are used within Nec-2/4.
	 
	Adding/creating a transmission-line is done by clicking the 'TR-line' button (the 
	one with the ladder picture). If not in 'Add-mode', click the 'Add' button to start
	adding a new Tr-line. Locate the mouse-pointer on the middle of the first wire and
	click and hold down your left mouse-button and move the mouse-pointer to the middle
	of the second wire. When reached release the mouse-button.
	When positioning was not too rude a new transmission-line is now added. If not, try
	again. Note also that we did not take the velocity-factor into account, we just used
	an electrical length of 70-1=96 feet.

	*) Add voltage source

	To prevent loosing the changes, backup the model using 'File->Save as' and choose a
	folder- and file-name for your new model.

	The next thing to do is add a voltage-source. While still in Add-mode, click the 
	'Source button' (right of the 'Wire button'). Next click and hold down your left 
	mouse-button somewhere in the picture-box. At the current mouse-pointer position a
	new source-object is displayed. Drag the source-object to the middle of the second
	wire, just between the two lower wires-ends of the feedline and release the mouse-
	button. When properly positioned a new source is now added. If not try again.

	For now we will set a default voltage-source of 1+j0 volt (1V @ 0 deg.)

	Select the 'pointer' button to switch back to select-mode mode. The mouse-pointer
	changes to the default arrow-pointer indicating 'Select-mode' is active.

	*) Add wire-conductivity

	We use copper wire for our antenna, so we will have to include this in our model 
	(the default is perfect wire with zero losses). To do this, click the 'Loading 
	button' (the one with the RLC symbols), click somewhere in the picture-box and drag
	the new load-object to any place on the first (upper) wire and release the mouse-
	button. The new load-object is now 'connected' to the first wire. 
	
	The default load however is a lumped load. To change this to a distributed/wire-load, 
	change the 'Par-RLC' selection for the Load-data on the right of the screen to 
	'Wire-ld'. The box shape on the first wire should now have changed to a red line-
	segment. The initial conductivity is set to 10000 mho/m. Change this to 'Copper' by
	using the 'G (mho/m)' selection-box on the right of the picture.

	To specify wire-conductivity for the whole structure, first change from 'spot load'
	to 'single-wire' (see lower right) . Notice how the whole wire becomes 'wire-loaded'. 
	Next change to 'Whole struct'. The 'Wire-conductivity' is not visible any more. This 
	would not deliver us additional information because the whole structureis now loaded
	(both wires). To enable wire-loading display for the complete structure use 'Option 
	-> Show wire loading'.

	For now we have added all required objects. Switch back to 'Select-mode'.

	*) Select/move objects

	The attentive user will have noticed that we did not yet explicitely specify our 
	wire radius (half the diameter). We will do so now. While in 'Select-mode', click
	the wire button and select the upper wire (wire 1). The wire color will change to 
	red (if not already set), indicating this wire is selected for modification.  In the
	wire-data on the right part of the screen select #12 as the wire-radius for wire 1. 
	Select wire 2 and change the radius also to #12.

	Also click the 'Trans-line' button to set the 'Char-Imp./Z0' to 50 ohms.

	To move a wire, click the 'Wire' button again and select the required wire. When the
	mouse-pointer is over the selected wire the pointer changes from the default to a
	two-point or four-point indicator. When a two-point indicator is visible one can 
	move the whole wire at once. When a four-point indicator is visible one can move the 
	corresponding wire-end. Move a wire(end) by clicking on the wire(end) and hold down 
	the left mouse-pointer while dragging it to a new position and releasing the mouse-
	button.

	When XY, XZ or XY plane (2D) is selected you can move a wire(end) to any place 
	inside the picture-box. When 3D-view is selected however be careful with this, 
	because a moved wire(end) automatically connects to the another near wire-end. To
	undo the latest move-action use the 'Edit' menu or move the mouse-pointer over the
	wire(-end) till a two/four-point mouse-pointer becomes visible and click the right
	mouse-button. A pop-up window is now displayed in which you can select 'Undo move'.

	The same principles apply for moving sources, loads and transmission-lines. However 
	these objects can only be moved from one wire(segment) to another wire(segment).

	You can textually change/edit XYZ-, wire-, tag- or segment-position by selecting the 
	required object and modify the 'object' data on the right of the screen.

	If required, backup or save your model by using 'File->Save(as)' to be able to 
	restore a previous model in case you made a serious mistake.

	*) Specify ground parameters

	By default a new model is located in 'Free space'. To model an antenna over ground,
	select the right-most 'Ground Params' button and select between Free-space, Perfect-,
	Finite- or SomNec-ground. For now we will use the finite-ground, also know as 'fast-
	ground'. Change from 'User-specified' to 'Average' (Clay/Forest) ground. Conducti-
	vity is now automatically set to 0.005 Siemens and 'Diel-const' is set to 13.

	To view the corresponding NEC-syntax for all wires and other objects we created,
	use 'Options->View Nec data'.

	*) Run NEC-engine and create far-field pattern.

	To run the NEC-engine and evaluate your model, click the 'Run Nec-engine' button 
	(the one with the calculator picture) or push <F7>. A new pop-up window is displayed 
	asking you for additional settings. To create a full 3D far-field pattern, select
	the second option 'far-field pattern', specify 'Full' and a 5 degree resolution. 
	Then click <Generate>.

	If the DirectX based version of 4nec2 is installed, push <F9> to visualize the new 
	antenna-structure Select 'Pattern' or push the 'R' key to see the 3D far-field 
	pattern.

	You can return back to your model by pushing <F6> or clicking the 'Geometry-edit'
	window. You may alter your model (e.g. set to 'Free-space') and recalculate to see
	the results of your changes.

	For another example of creating a T-antenna on a box, see appendix A at the end of
	this document.

2) Show structure, generate data and view currents and phase distribution.

	In this next example it is explained, how to open a NEC antenna model, view/edit
	(4)nec(2) input-file data the traditional way, generate NEC-output, examine and 
	validate structure geometry and display the current- and phase-distribution along 
	the structure. Furthermore some of the more general menu-bar options as available on
	the different 4nec2 forms/windows are discussed.   

	After starting the 4nec2 program by double clicking on the 4nec2 shortcut or on the
	4nec2.exe program-file, a file selecttion window is displayed. This initial window 
	is used to select the (4)nec(2) antenna model file to open and work with. In this first
	example please locate the file ..\4nec2\example1.nec and click the open button.

	If no NEC-output is generated yet for the selected file, the data loaded into 
	4nec2 will be that for the (4)nec(2) input-file. The wire geometry structure specified
	in this file is displayed on the 'geometry' form. You may use the F2 or F3 key's to
	bring the 'Main (F2)' or the 'Geometry (F3)' form to the foreground. 
	To indicate that the you are currently viewing the input-file data, the background
	for the 'Geometry' form is displayed in a none white color. Note also that in this
	case, most of the fields on the 'Main (F2)' form are empty.

	You may use the arrow key's to rotate, shift or zoom the structure, or the Page-up 
	and Page-down key's to zoom-in or -out. To shift the structure up/down or left/right
	you can also use the Control key together with one of the arrow-key's. Use the 'Home'
	key to reset the geometry form. 

	If you have installed the 4nec2X extended version you could use the F9 key to view
	your nec-model using real-time 3D rendering techniques. Use your mouse-buttons (left,
	right or both) to rotate, shift and zoom the model.

	To view the textual contents for the NEC input-file, first check if the default 
	editor is set to 'Notepad edit'. This is done using the 'Settings' menu-bar option
	on the 'Main (F2)' window.
	If set, push the 'F6' button or use the 'Edit->Input-file' menu-bar option on the 
	'Main' window to start the Edit session. The active *.nec input file is loaded in 
	the editor, and you should see something like this:

CM Example 1 :	Dipole in free space    ' Comment cards
CM 		See GetStarted.txt
CE                                      ' End of comment
'
GW 1 9 0 .2418 0 0 .2418 0 .0001        ' Wire 1, 9 segments, halve wavelength long.
GE 0                                    ' End of geometry
'
EX 0 1 5 0 1 0                          ' Voltage source (1+j0) at wire 1 segment 5.
'
FR 0 1 0 0 300 0                        ' Set design frequency (300 Mc).
'
EN                                      ' End of NEC input

	First we see two CM (ComMent) cards, where some explanation is given about the file.
	After these comment cards always a CE (Comment End) card is required. CM cards are
	the original cards used to add NEC comment. 4nec2 also allows you to add comment
	by using a ' character. Everything after this character is treated as comment and 
	ignored by the NEC engine.
	Next we see a GW (Geometry Wire) card, specifying a single dipole wire with a length
	of 2 times .2418 meter. The X, Y and Z coordinates for end-1 are ( 0, -0.2418, 0 )
	and for end-2  ( 0, 0.2418, 0 ). This wire is given a 'tag' number of "1" and is 
	divided into 9 equally long segments. After the GW card(s) always a GE (Geometry End)
	card is required.
	Then we find an EX (excitation) card of type "0", specifying the most commonly used
	voltage-source type. This voltage source is located on the wire with tag 1 and the
	segment with sequence number 5. (seen from end-1). The excitation voltage is spe-
	cified as a default 1 + j0 volts. (1 V at 0 degrees).  
	The (design) frequency for this antenna is specified with the FR card. In the above
	example we specify this as (a single step for a frequency of) 300 Mhz. 
	The end of the input file is marked with an EN card.

	To modify a (4)nec(2) input-file the 'Edit' window is used, but for now we quit this 
	edit session without saving, by clicking the Notepad 'Close' button.

	To start the NEC engine and generate NEC output-data, be sure one of the 4nec2
	forms is on top (has the focus) and push the F7 key. A new pop-up window called 
	'Generate' is displayed. In this window you will be able to specify  different 
	calculation options. Lets start with the first one, called 'use original file'.
	If not already selected, please select this option and push <Enter> or click the 
	'Generate' button.
	When this is done, a black DOS-box is displayed, indicating that the Nec2d.exe
	engine is running. This engine reads the active *.nec input file data, processes the
	given data and writes the calculation results back to the output file. This output
	file is created in the '..\4nec2\out' folder.

	Before starting the engine, the input-file data is pre-processed by 4nec2 to remove
	comment, calculate variables, convert current-sources or perform auto-segmentation.
	The intermediate file with the *.inp extension is sent to the NEC-engine. 
	If NEC errors are reported you can inspect the output-file data using the F8 key 
	or select 'Edit -> Output-file'. To view the 'raw' input-data send to the NEC 
	engine use 'View->Last NEC input' on the 'Geometry (F3)' form.

	When calculations are done, the DOS-box disappears and 4nec2 opens the output-file, 
	reads and displays the generated data on the 'Main' and 'Geometry' form.
	Note that the 'Geometry' background color changes to white and that most fields
	on the 'Main' form are filled with data.

	Before starting the NEC-engine, optionally a 'geometry validation' test is done. 
	If enabled, any geometry errors/warnings are logged. Calculations however are still
	performed. When calculations are done, 4nec2 performs a 'segment validation' test.
	In this test most of the NEC requirements concerning segment-length  and -diameter
	are checked. If errors are detected a message is displayed and the wires/segments
	with errors/warnings are highlighted. Use 'Validate -> run geometry check / run
	segment check' to manually run the tests and/or get more textual information.

	To get more detailed segment info, select the desired segment with the mouse and
	use the left mouse button. With the 'Wire/Segment' menu-bar option you can get the
	same information. Detailed wire information is also available when viewing the 
	input-file structure. The selected wire is highlighted, with an open and a closed
	circle. The closed circle represents end-1, the open circle end-2.

	To view all Segment, use the 'S'(egment) key or select 'Show->Segments'. To view 
	the open Ends, use the 'E'(nds) key or select 'Show->open Ends'. To show the Current
	distribution along the dipole wire use the 'C'(urrent) key or select 'Show->Current'
	To toggle the Phase relationship on and off, enter the 'P'(hase) key or select 
	'Show->Phase'. If detailed segment info is selected (see above), the numerical
	values for the segment current is displayed. With the 'X' key or the 'Wire/Segm->
	Polar/Cartesian' option you can toggle between polar or cartesian notation.

	Another way to show the current distribution along a wire is to select the 'Show->
	single/multi-color' option. This option may be used to evaluate the currents for
	complex structures.
	

3) Generate Far-field data and view 2D polar and 3D far field patterns.

	In this example the Example2.nec input file is used. If 4nec2 is already active,
	please use 'Ctrl+O' or 'File->Open' on the 'main' and select the Example2.nec file.


CM Example 2 :  Loaded dipole in free space
CM              See GetStarted.txt
CE              End of comment
'
SY len=.4836                            ' Symbol: length=wavelength/4
'
GW 1 9 0 -len/2 0 0 len/2 0 .0001       ' Wire 1, 9 segments, halve wavelength long.
GE 0                                    ' End of geometry
'
LD 5 1 0 0 5.8001E7                     ' Wire conductivity for copper
'
EX 0 1 5 0 1 0                          ' Voltage source (1+j0) at wire 1 segment 5.
FR 0 1 0 0 300 0                        ' Set design frequency (300 Mc).
EN                                      ' End of NEC input


	At first the structure looks the same as Example 1, however if you use the F6 key
	you will notice some differences. First of all, special 4nec2 "SY" cards are inclu-
	ded. With this card it is possible to specify symbols(VARIABLES), constants or 
	mathematical expressions (equations). In this example the dipole length is repre-
	sented by the symbol 'len'. It has the value 0.4836. In the GW card this variable
	is used as 'len/2' to specify the Y coordinates for both ends of the dipole wire.

	Furthermore a LD 5 (wire loading) card was added to specify the wire conductivity
	for the dipole. In the 'Geometry' form you can use the 'W'(ire) key of 'Show->Wire 
	loading' to examine all the loaded segments, they are displayed in a orange/brown 
	color. You may also use 'Show->Excitation/Loading info' on the Main form or click
	on or near a wire in the Geometry form to view additional Wire information.
	
	To generate a 3D far-field pattern, press the F7 key and select the second option
	called 'Far-field pattern'. In the lower half of the form, additional fields are 
	displayed to specify a certain pattern-resolution and a check-box to include the 
	surface wave into the combined far-field pattern. 

	The pattern-resolution specified how fine or course the generated pattern is. Fur-
	thermore this affects 4nec2 memory-usage and NEC processing-time. For 'simple'
	antennas like our dipole a resolution of 5 or 10 degrees will be fine. For multi-
	element antennas like the 'emeyagi.nec' a reolution of 1 degree may be needed. 

	For now, the 'surface wave' option should not be selected. The option boxes
	on the right should be set to 'Default pattern'. Experienced NEC-users can use
	one of the other options or even use the 'more' button to get extra options.

	When the 'Generate' button is pushed, the NEC-engine starts and new output data is
	generated. After the calculations are done a third form called the 'Pattern' form 
	is displayed. In this form the 2D horizontal or vertical polar far-field patterns 
	are made available. If this form is on top, with the arrow-keys you can select the 
	pattern for different theta or phi angles. With the 'G'(eometry) key or the 'Show->
	Structure' the geometry structure is displayed on the pattern form. 

	To view the 3D pattern, select the 'Geometry' form (F3) and push the 'R' key or use
	the 'Show->Near/Far-field' option. You may use the mouse-buttons or the arrow- and 
	page-up/down keys to move, rotate or zoom the 3D pattern. If the 3D pattern on the
	'Geometry' form is enabled and the 'Pattern' form is selected (F4), the color for 
	the 3D pattern changes and the 2D pattern for the selected theta (elevation) or phi
	(azimuth) angle is highlighted. This helps you to understand where the selected 2D
	pattern is located in the full 3D-pattern.

	On the 'Pattern' form you can use the 'L' key to switch between linear and (semi)
	logarithmic scaling. By default the pattern is normalized for maximum gain for the
	current Theta(elevation)/Phi(azimuth) angle. The Max-gain value is displayed in the
	upper left corner. To normalize against the overall maximum gain, press the <Home> 
	key. To disable all normalization, press the <Home> key again. A third push will 
	bring you back to the default state.

	To get the gain and angle for a particular point on the pattern it is possible to 
	select a point on the pattern line with the mouse and click the right mouse button.
	Use the 'I'(nfo) key or 'Show->Info' the get additional information about maximum
	gain, front to back ratio and beam-width.  By default the 'total field' is displayed,
	to view the other generated patterns use the ','(<) and '.'(>) key's.	

	Use the 3D-viewer/<F9> (4nec2X only) to view the far-field data in 3D perspective.


4) Generate frequency loop graphical-data

	In this third example the Example3.nec input file is loaded. In this file an
	inverted-V antenna for 80 meter is used. The top of this antenna is brought to
	a height of 20 meters, and a ground specification (GN card) is included.
	For easy reading, Tab characters are used to separate the different NEC card 
	values. If you take a look at the 4nec2 input file (F6), you will see three types 
	of 'GN' cards, two of them are preceded by a " ' " sign, so they are treated as 
	4nec2 comment. The other one (the GN 2) card is 'active', so in this example the 
	high accuracy Sommerfeld-Norton ground is used. A conductivity of 0.006 S/m and a 
	dielectric constant of 14 is used (average ground, see the 4nec2 help)   

CM Example 3 :   Inverted-V over average ground
CM               See _GetStarted.txt
CE 
SY hgh=20                               ' Height
SY len=20                               ' Wire length
SY ang=110                              ' Angle between sloping wires
SY Z=len*cos(ang/2), X=len*sin(ang/2)   ' Get delta-Z and -X distances
'
GW	1	20	-X	0	hgh-Z	-0.1	0	hgh	#12 ' radius for
GW	2	1	-0.1	0	hgh	0.1	0	hgh	#12 ' #12 wire
GW	3	20	0.1	0	hgh	X	0	hgh-z	#12
GE
'
'GN	-1                                              ' Perfect ground
'GN	0	0	0	0	14	.006    ' Finite ground
GN	2	0	0	0	14	.006    ' Sommerfeld ground
'
EX	0	2	1	0	1	0       ' Default voltage source
FR	0	1	0	0	3.680           ' Design frequency
'
EN							' End of file

	In this example the 'sin' and 'cos' mathematical functions are used to calculate
	the delta-X and -Z distances for the outer ends of both sloping wires.

	To generate frequency loop (frequency sweep) data, Enter the F7 key, and select
	'Use frequency loop'. With this calculation-option line-chart graphs are generated
	for Forward-gain, Front-to-Back ratio, Front-to-Rear-ratio, SWR and input impedance.

	When selecting this option additional input-boxes appear. For now we select the
	'Gain' option. Please enter a frequency start-value of 3.5, a stop value of 4 and
	a step-size of .02 Mhz. Enter a value of 90 for the Phi angle and a value of 55 for
	the Theta angle, and click the 'Generate' button.
	When calculations are done a third window is displayed called the 'Line-chart (F5)'
	window. In this window you can switch between "S"(SWR), "G"(Gain) and "I"(impedance)
	display. Use the "L" key to switch between linear and logarithmic Y axis scaling.
	Use the "F" key to change to X-axis scaling. By default the SWR, R-in and Z-in 
	graphs are set to logarithmic, the others default to linear. When linear scaling is
	set you can use the 'Up','Down', 'Page-up' and 'Page-Down' keys to move and zoom the
	graph. Use the 'Tab' key to select one or both graphs.
	
	4nec2 also has the possibility to display the input impedances on a Smith chart. 
	Enter the F11 key to select this option. Use the cursor keys to select a specific
	frequency. More experienced users may use the <Shift> key in conjunction with the
	cursor keys to 'add' a certain length of feedline. Use <Home> to (de)normalize.

	To view the changing for, for example, the vertical far-field pattern when fre-
	quency increases from 3 to 30 Mhz, please enter F7, 'use frequency loop' and select
	the 'Ver'tical option. Enter 3, 30 and .5 for frequency start, stop and step-size. 
	Again enter 55 for the Theta- and 90 for the Phi-angle of our direction of interest.
	Click 'Generate' and when calculations are done, you can 'walk' through the dif-
	ferent vertical far-field patterns on the 'Pattern' (F4) form with the 'Left' and 
	'Right' arrow key's.

	Note: 	Select the Nec2dSX engine for increased accuracy when running a frequency-
		loop using SomNec ground settings.
		
5) Optimize antenna performance.

	In this example again the 'Example3.nec' input file is used, but now we will opti-
	mize antenna-performance. As a first try we will use the traditional hill-climbing
	optimizer and optimize radiator length for resonance. To do this, start the Optimi-
	zer by entering the F12 key. A new window appears with a number of selection- and
	input-boxes. First we set the traditional optimizer by selecting 'Optimize' in the 
	Function-box and 'Default' in the Option-box. After this we select the variable(s)
	we want to optimize, by clicking on the 'len' variable in the list-box with the
	'variables' heading. The selected variable(s) will show-up in the right list-box.
	
	Furthermore you must select one or more antenna properties to optimize, together 
	with their "importance" (weighting factor, contributing in the total result).
	To optimize for resonance, please enter a value of 100 (%) in the 'X-in' box, 
	(all other values must be set to zero) meaning only the Reactive component con-
	tributes for 100% in the total result. (FOM, figure of merit). To get resonance, 
	this property must be minimized. This is the default for the 'X-in' property. (Click
	with the right mouse key on one of the property-boxes to change this default target)

	After clicking the 'Start' button the optimizing process starts and the button 
	text changes to 'Stop'.

	In the upper right box (value sensitivity), the selected variables together with the
	direction and relative amount in which they are changed are displayed. In the lower
	left box (calculated results) the calculated property values are displayed for each
	new optimization step, together with the calculated overall result (Res%) and the 
	step-size used. In the lower right box (variabele values) the corresponding variable
	value(s) is/are listed, so it is possible to follow the optimizing process.

	After some time the process should stop with the message 'Optimized in XX steps',
	indicating the optimization is ready. To premature abort the process, you may click
	the 'Stop' button. It is possible the process is not immediately halted. If so, 
	please wait till the active calculation step is ready. Sometimes it may be necessary
	to click the button once more. After the process is ready/aborted, you may change 
	the variables or properties and continue optimization by clicking the 'Resume'
	button.	

	If the optimization results are OK, you may use the 'Update NEC-file' button to up-
	date your NEC-file with the new variable value(s). Use 'Exit' to quit the optimizer
	without saving.

	In the same way you can optimize for Forward-Gain, Front-to-back- and/or Front-to-
	Rear-ratio. If one or more of these properties are selected, you must also specify
	the Forward- and backward-gain angle(s) for which the Gain has to be calculated for.

	For quick optimizations, a resolution of "0" (zero) could be used. In this case 
	only the Gain for the specified Forward- and backward-angles are calculated and no
	additional Front-to-Rear data is calculated.

	For more precise optimizations, a none-zero resolution (e.g. 5 degrees) could be set.
	Now a complete 3D pattern is calculated for each optimization step, so the difference
	between the Forward lobe and the largest side-lobe in the backward 180 degree part of
	the pattern is calculated and displayed as the Front-to-rear ratio.

	If optimizing for Gain or F/B, one may also specify a delta Theta and Phi for the 
	forward- and/or the backward-angle. If a none-zero value is specified, the gain is
	averaged over the range between Phi-delta_phi and Phi+delta_phi. The same holds 
	for the Theta angle. 

	Mostly optimization is performed for total-gain. If required, however you may opti-
	mize for horizontal/vertical-gain or E-theta/E-phi. Optimization with included sur-
	face-wave is also possible. 

	Variable changes are reflected on the Geometry view. To view them, after starting
	the optimization process, please move and/or resize the optimizer window to the 
	lower left part of the screen. If optimization is done for Gain and a none-zero
	resolution is set, the far-field pattern changes are also reflected on the Geometry
	(if 3D pattern is enabled) and the Pattern form. The optimization steps are logged
	in the optimzer.log log-file. This file can be viewed with 'Show -> Optimizer log'
	in the Geometry window.

6) Sweep antenna variables.

	With version 5.3 and later it is possible to evaluate and graphically visualize the
	effect of antenna variable changes. To make this possible a variable-sweeping func-
	tion has been added in the Optimizer function box. If, after enabling the optimizer 
	window (F12), this Sweeper function is selected, the optimizer window changes a bit.
	For each selected variable the minimum (start) and maximum )stop) values to sweep
	between is displayed. YOu can manually change these min/max values. Furthermore a 
	'Nr of steps' input-box is displayed, with a default value of 10. 
	Using the 'Options' selection box ypou are able to select between the vertical of 
	horizontal or 3D far-field pattern.

	To evaluate the effect of changing antenna height from 20 to 30 meters, we use the
	'3el-inverted-V.nec' file. After loading this input file, start the optimizer/sweeper,
	select 'Sweeper' and select 'hgh' as the variable to sweep. This variable is now 
	added to the 'selected' list', default values of min = 10.5 and a max = 42 meters is
	set and a default number of 10 steps displayed. To sweep a height change from 20 to 
	30 meters select the 'hgh' value in the 'selected' list (click again if the variable
	is removed) and change the min and max values to 20 and 30.  

	Set the Theta- and Phi-values to 55 and 90 degrees to specify the angle for which
	Gain is calculated. Specify a resolution of 10 degrees. (If resolution equals zero,
	this will increase sweeping speed, however no pattern is calculated and displayed)

	Click the Start button to start the sweeping process. First of all an initial 
	step is made with the default height of 20 meters. After that 10 incremental steps
	are made in which each step the height is incremented by 1 meter.

	The resulting SWR, Gain, F/B, F/R, R-in, X-in and efficiency values for each step 
	are reported in the 'Calculated Results' box. The resulting horizontal far-field 
	pattern for each step is updated on the 'Pattern (F4)' and 'Geometry (F3)' window.

	If all steps are done, you may use the 'Exit' button to close the optimizer/sweeper
	window or change/add/remove variables, change settings and/or proceed with another
	range of steps, by clicking the 'Restart' button.
	
	After closing the window, all results for the last sweep are reported in the line-
	chart graphs on the 'F5' form. The horizontal or vertical patterns (according your
	selection) for the different calculation steps composing the sweep are available on
	the 'Geometry (F3)' form. Use the Right- and Left-arrow-key's to switch between 
	steps. Use the 'Show Log' button to view or print the last sweeper results.

	Note however that as distinct from the default 4nec2 operation, the sweeper
	results are only stored in memory, and not in a NEC output-file. So, if 4nec2 is
	left or the input file is viewed or another 4nec2 file is selected. The sweeper
	results are lost. The log-file is kept as long as a new optimization or sweep is 
	done. 

7) Generate and view Near-field data

	As an example to generate near-field data, the file NearFld.nec is included in
	the package. To use this example, please load this file and push the F7 key to
	get the 'Generate' window. Select 'Use original file', to start the calculation.
	This input-file already contains the required NE card is, so it is not yet 
	necessary to specify any near-field parameters. Calculations will take some time,
	because almost 30.000 near-field points are calculated. 

	When calculations are done, the Pattern windows is displayed with the 'Near-field'
	lay-out. Initially you mostly will see a blue plane with on the left a color-bar
	telling on the left, telling you what field-strength is represented by a certain 
	color. The maximum value will be in the range > 1e+4 volts/m. This is due to the
	fact that one or more of the calculation points will be very close (or maybe on) a
	geometry wire with high RF-voltage/current.

	To get rid of these 'unusable' high values, please use 'Near-field -> Ignore high 
	values" or push the <Del> key. You are asked for maximum field-strength. Please
	enter a value of 250 (V/m). The display should now change to a more colorful
	view. The color-bar on the left is also updated.
	Another way to change the color-resolution, is to use the <Alt> together with the
	<Page-up> or <Page-down> keys. This will change the linear scale to a more logarith-
	mic scale. Use 'Show -> Geometry' or the "G" key to display the geometry- structure.
	
	Initially the field-strength on the XY plane for a certain Z value is displayed.
	To change the Z-value use the cursor-left or -right key's. To change between
	XY, YZ and XZ plane, use the spacebar.
	
	On the Geometry form you are also able to display the Near-field points. Use
	'Show -> Near/far field" or push the "R" key. Use the spacebar to switch between
	3D view, or 2D XY, YZ or XZ view. Use <Shift> plus the arrow-keys to change the
	2D plane coordinates. Use <Page-up>/<Page-down> to change the dot-size.

	On the 'Pattern' form on the left and on the right of the 2D plane, two black
	indicator lines are displayed. These indicators are used to select a certain Y- or
	Z value for displaying the field-strength using a line-chart. Use the Up/Down arrow
	keys to change position, use <Page-Up>/<Page-down> to switch between 2D and line-
	chart viewing.

	Use the 3D-viewer/<F9> (4nec2X only) or the "Plot -> 3D" menu-bar command (if 
	gnuplot is availle) to view the far-field data in 3D perspective.


8) Generate and use ItsHF area-coverage propagation data.

	This feature works in co-operation with the NTIA/ITS HF propagation software using
	the VOACAP, ICEPAC or REC533 model. This software is freely available on the internet.

	After installing this software, you should check the ItsHF 'main' folder setting 
	under 'Settings -> Folders -> ItsHF folder' on the Main (F2) window. Also check if
	all 6 options under 'Settings->ItsHF settings->Area Coverage/Point-to-Point' are 
	checked and if VOACAP is selected as the model to use.

	With this first try, we use the 3el-inverted-V.nec as our input file. First we run a
	standard 3D far field calculation, to determine the Phi angle for the main lobe. For
	this antenna this is 90 degrees (positive theta).

	After pushing the <F7> key again, we now select the 'ItsHF 360 degree gain table'
	option. If not already set, specify 90 degrees for the main beam angle (Phi-max) and
	select 'Map' as the plot-type you would like to see. Also check if the 'Span' selec-
	tion-box is set to 'Single-step'. Then click <Generate>.
	After running the nec2d(xs) engine and creating an ItsHF antenna-file, the ItsHF engine
	is automatically started (characterized by the counting number sequence). 

	When done, a color-full map is displayed, indicating propagation performance over 
	Europe for the antenna under test and for the specified parameter ('Param' control),
	or other region as specified by the 'Xmtr location' and 'Map' controls). In the ItsHF
	plot-window you can manually move and click the mouse to get specific distance and 
	param-values. Use the 'Parameter'menu-option to create a map for one of the other para-
	meters.

	The plot settings to create the map are saved in the '3el-inve.voa' file (truncated to
	eight char's) located in the '..ItsHFbc\areadata\4nec2' folder. You may start the ItsHF
	Area coverage program ('Run -> ItsHF area-coverage' on Main (F2) window) to open, view
	or modify this file and/or to run and create other user-specific Area-Coverage plots.

	In the '3el-inve.voa' file you will see that for the TX-antenna, '3el-inve.n13' is 
	set, indicating our NEC based antenna. This type-13 antenna-file is located in the 
	'..\ItsHFbc\antenna\4nec2' sub-folder. You may use 'Run -> ItsHF antenna view' to 
	check the pattern using the ItsHF antenna viewer 'HFant'.

	Each time a 'Area-Coverage' calculation is done by 4nec2, a new *.voa input file is
	created. This file is based on the information included in a default/template ItsHF
	input-file called 4NEC2.VOA placed in the ..\ItsHFbc\antenna\default folder.
	Most of the important ItsHF settings are available through the controls on the 
	'Generate (F7)' window. when <def> or <default> is selected, to settings as specified
	in the template-file are used. You may modify this template file for specific needs.

	When using the '360 degree Gain-table' option, a type-13 antenna file (*.n13) is pro-
	duced containing a 360*90 degree gain-table for a single frequency. This type of an-
	tenna-file is especially suited for Area-Coverage plots.

	When a Point-to-Point Graph type of plot is needed, one could better use the 'Gain @
	30 frequencies' option. This will produce  a 90 degree gain-table for the specified
	antenna direction (bearing) for all integer frequencies from 2 to 30 Mhz. The required
	direction is specified using the 'Xmtr' and 'Rcvr' location buttons.

	For Time- and Distance (point-to-point) plots you may use both '360 degree gain-table'
	(type 13) or 'Gain @30 freqencies' (type-14) antennas. When a type-13 antenna is used,
	howevert you are able to more precisely specify the working/design frequency for the
	antenna under test. 

	SWEEP area-coverage:

	With the 'Sweeper' function it is possible to let 4nec2 automatically generate a 
	specified range of area-plots for you. For instance, representing the area-coverage
	change when increasing the antenna height from 15 to 30 meters.

	To do this, again select the 3el-inverted-V.nec file as our antenna of interest and
	push <F12> to start the optimizer/sweeper. Select 'Sweeper' using the 'Function' 
	box and select 'Area-coverage' using the 'Option' box. Select 'hgh' as the variable
	to sweep and specify min=15 and max=30 (meters). Set 90 degrees as the Phi angle for
	the main-beam and specify 10 steps of 10% variable change, and click <Start>.

	During all the calculations, which will take some time, you will see the windows
	popping on and off the screen. During all these window flashing the ItsHF area-plots
	are automatically cut and pasted into the 4nec2 software. After some time a message-
	box shows up showing 'Sweep ready'.

	Clicking <OK> will show-up the so called 'picture-viewer' window in which all ItsHF
	plots have been copied. Using the scroll-bar, the left and right-arrow keys or the
	'1' to '9' number keys, you can scroll through or switch between all created plots.

	You are now able to evaluate the effect of changing antenna height on area-coverage.
	You will notice that for a height of around 21 meters the optimum F/B ratio is reached.
	This was the original height the antenna was optimized for.

	This 'picture-viewer' window is also used if, for a Map type of plot, the 'Span' se-
	lection box is set to a setting unequal '<def>' or 'single-step'. With these settings,
	multipe plots are generated which in turn are copied into the picture-viewer. When all
	calculations are done, you can use the scroll-bar to scroll through all the plots.

	Latest test-results on different systems show that this automatic cutting and pasting
	appears to be sensitive. If you should experience difficulties during this process,
	please contact me so I can deliver you an alternative.

9) Generate and use ItsHF point-to-point propagation data.

	Point-to-point propagation plots are automatically created if you select a 'Time',
	'Dist(ance)' or 'Graph' type of plot on the 'Generate (F7)' window. Its recommended
	to use the 'ItsHF Gain @30 frequencies' option when running (multi-frequency) point-
	to-point plots.
	When <Generate> is clicked, if required, the Nec engine is started and (new) ItsHF
	antenna and point-to-point files are created. Next, the ItsHF engine is automatically
	started to create the requested plot. 
	When the plot is visible you can use your mouse-pointer to click on the plot and see
	specific time/distance/frequency values. For Time- and Distance plots use the 'New 
	plot' menu-bar function to select an alternate time, frequency and/or parameter. 
	The number of time values to select between is determined by the 'Span' selection on
	the 'Generate (F7)' window.
	When running a 'Graph' type of plot, you must manually select the parameter to plot
	just before the plot is visualized on the screen.  Use the 'Parameters' menu-bar op-
	tion on the plot-window to select another parameter to plot.
 
	
	To be continued.....

	(it is suggested to periodically check the 'unofficial Nec-page' for new versions)


p.s.	I apologize for my English which is far from perfect, but nevertheless I hope this 
	document, including all the syntactical- and other errors, does deliver some usefull
	information.


Appendix A: 

	Example: Creating a T-antenna on a box using the Gometry editor

	The second example will give a brief description about one of many possibilities how 
	to create a much more complex 3D-model consisting of a T-antenne on a grid-type box.

	The below might seem as a lot of work, but once you 'get the point' you will see
	the rather straightforward use of available possibilities.

	a) 	Create a new design using'New' in the Geometry-editor 'File' menu.
	b) 	Change default frequency of 299.8 to 299.9 Mhz, indicating frequency is set.
	c) 	Select 'Rect-grid' from the 'Create' menu and specify a (highlighted) 'Y'-
		coordinate of 0.2 to create the back-side of the box (Y-axis pointing backwards)
	d)	Draw a rectangle from X=-0.2 and Z=+0.2 to X=+0.2 and Z=-0.2 meters, using 4 
		sections per side.

	e) 	One by one select left- and right outmost-wires and delete them, to avoid over-
		layed wires when attaching grids representing left- and right-side of the box.
	f) 	Select all left-over grid-lines again using the 'selection-box' method.

	g) 	Switch to XY-plane (view from above) and use <Ctrl>+C and <Ctrl>+V to copy and 
		paste selected wires to create a second (front) side of the box. 
	h) 	Move the new red-line, representing the new pasted 'grid' to an Y coordinate 
		of -0.2 meters and an X coordinate from -0.2 to +0.2 meters.
	i)	Switch to 3D-view, inspect structure and use 'File->Save as' to back-up the 
		new structure as for instance 'try1.nec'.

	j) 	Switch to YZ-plane, select 'Rect-grid ' in the 'Create' menu and set a (high-
		lighted) X-coordinate of 0.2 meters to create the right side of the box.
	k) 	Now draw a rectangle from Y=-0.2 and Z=0.2 to Y=+0.2 and Z=-0.2 meters, using 4 
		sections per side.
	l)	Switch to XY-plane (view from above) and use copy/paste to create the left side
		of the box and move the new 'grid' to an X-coordinate of -0.2 meters.
	m)	Switch to 3D view, inspect structure, if okay, backup using 'File->Save'

	n)	In 3D view, unselect by clicking anywhere near the structure while holding down
		the <Shift> key.
	o)	One by one select and delete all upper and lower wires to avoid overlayed wires 
		when adding the top- and bottom-sides of the box.
	
	p)	Switch to XY-plane, Use 'Create->Rect-grid' and set an Z-coordinate of 0.2 meter
		to create the upper side of the box and draw the required rectangle.
	q)	Switch to 3D-plane, use copy/paste to create the bottom side of the box and
		move the grid to the correct position.
	r)	Our box is now ready, backup it using 'File->Save'.
	
	s)	Set XZ plane and use Right mouse-button to shift structure down to lower half
		of the window.
	t)	Switch to 'Add-mode' and draw a wire from X=0 and Z=0.5 to X=0 and Z=0.2
	u)	Switch back to default 'Select-mode', select 3D-plane and locate mouse-pointer 
		on connection between wire and box.
	v)	Click right mouse-button for 'Edit' pop-up menu and use 'Disconnect end' and move
		end-2 to center of the upper-side of the box.	
	
	w)	Switch to 'Add-mode' and select XZ-plane to create two wires from X=-0.2 to X=0 
		and from X=0 to X=+0.2, both for a Z value of 0.5 meter. 
	x)	Select the 'Source' button and add a voltage source just above the connection
		for the vertical wire to the center of the box.
	y)	Our T-antenna on a box is now ready, save it or use <F7> to generate a far-field
		pattern. 
	
	As a check, compare your model with the T-box.nec file.
	
