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C00002 00002	{[C<NαRESULTS AND CONCLUSIONS.λ30P100I425,0JCFA}   SECTION 10.
C00004 00003	[10.0	Summary.]
C00006 00004	[10.2	Suggestions for work in the near future.]
C00007 00005	{Q}11.0	REFERENCES.
C00009 00006	{Q}References:
C00012 ENDMK
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{[C;<N;αRESULTS AND CONCLUSIONS.;λ30;P100;I425,0;JCFA}   SECTION 10.
{JCFD}  RESULTS AND CONCLUSIONS.
{λ10;W250;JAFA}
	10.0	Summary.
	10.1	Accomplishments and original contributions.
	10.2	Suggestions for future work.
{λ30;W0;I950,0;JUFA}

[10.0	Summary.]
[10.1	Accomplishments and Original Contributions.]
	As a  regular feature in a PhD thesis,   it is required  to
explicitly  state what  has been accomplished  and what  is original.
Some of what has been accomplished is itemized in Box 11.2;  with the
so called <original contributions> marked by an asterisk.
{|;λ10;JAFA}
BOX 11.2{JC} Accomplishments and Original Contributions.
	0. The Vision Theory.
      *	1. The Winged edge polyhedron representation.
      *	2. The Euler Primitives for polyhedron construction.
	3. The Iron  triangle camera locus algorithm.
      *	4. The OCCULT hidden line elimination algorithm.
      *	5. CRE polygon nesting algorithm.
	6. CRE dekinking.
	7. CRE polygon segmenter.
	8. CRE polygon comparing.
{|;λ30;JUFA}
[10.2	Suggestions for work in the near future.]

	Newtonian Mechanics
	Higher Dimensionality, 4-D GEOMED.
	Curved patchs

Better computer hardware, better I/O hardware,
cameras, dynamic range, larger practical job sizes.
better systems software: editor, assembler, loader and debugger;

	Computer vision and geometric modeling 
	
A.I. in general and vision in particular requires number crunching,
assume a foundation 

Higher Dimensionality: 4-D GEOMED.

	
{Q}11.0	REFERENCES.

GRAPE, GUNNAR R.
	Model Based (Intermediate-Level) Computer Vision.
	Standford A.I. Memo AIM-201. 1973.

FALK, GILBERT.
	Computer Interpretation of Imperfect Line Data as a 
	Three Dimensional Scene.
	Standford A.I. Memo AIM-132. 1970.

AGIN, GERALD J.
	Representation and Description of Curved Objects.
	Standford A.I. Memo AIM-173. 1972.

FIEGENBAUM, EDWARD A.

EARNEST, L.

TENENBAUM, M

SCHMIDT, R

DUDA & HART

MC CARTHY & HAYES

SWINEHART et al.		SAIL MANUAL

FELDMAN	et al.			LEAP PAPER

FALK, FELDMAN & PAUL.		Hand/Eye Polyhedron Representation Paper.

ROBERTS

SOBEL

QUAM
{Q}References:

1. AGIN
	Representation and Description of Curved Objects
	Stanford Artificial Intelligence AIM-172, 1972.

2. COXETER
	Introduction to Geometry
	John Wiley & Sons, Inc. New York. 1961.

3. EVES
	A Survey of Geometry.
	Allyn and Bacon, Inc. Boston. 1965.

4. FALK
	Computer Interpretation of Imperfect Line Data
	as a Three Dimensional Scene.
	Stanford Artificial Intelligence AIM-132, 1970.

5. FELDMAN, FALK & PAUL
	Computer Representation of Simply Described Scenes.
	Stanford Artificial Intelligence SAILON-52, 1969.

6. GUZMAN
	Computer Recognition of Three Dimensional Objects.
	Project MAC Technical Report, 1968.

7. KNUTH
	The Art of Computer Programming.
	Volume 1 - Fundamental Algorithms.
	Chapter 2 - Information Structures.
	Addison-Wesley. Reading,Mass. 1968.

8. ROBERTS
	Machine Perception of Three Dimensional Solids
	Lincoln Laboratory Technical Report #315, 1963.

9. SOBEL
	Camera Models and Machine Perception.
	Stanford Artificial Intelligence AIM-121, 1970.