Illustrations for Monograph 2E (ISBN 0-9583380-0-0)

Appendix Z3.

Illustrations for monograph [2e] (ISBN 0-9583380-0-0)

their descriptions and filenames with their scans

(prepared Dr Jan Pajak, on 12 November 2000)

Explanations:

- To all illustrations published in monograph [2e] apply the same copyrights as for the whole monograph [2e].

- Illustrations which in monograph [2e] were marked as a single Figure, in practice can be combined from more then one separate illustrations which were produced with different techniques (e.g. photographs, drawings, etc.) and scans of which are stored in several separate files.

- Only some of illustrations for treatise [2e] are unique for this publication. The majority of illustrations from treatise [2e] is also published in the monograph [1/3] (published in the Polish language) which at the moment is the base for all other publications by the author.

- Apart from this document, each illustration from monograph [2e] is thoroughly described at the end of chapter to which it belongs, and the symbol (a letter) of which proceeds the number of that illustration.

- Computer files which contain scans with illustrations for monograph [2e] are named with symbols which include the following segments:

-- subsequent number of a given illustration in monograph [2e] (this number is composed of a latter which symbolises the chapter in which a given illustration is explained or used, and a number which represents the subsequent position of this illustration in a given chapter),

-- the location of this illustration on the Figure from monograph [2e] (this location is expressed with the following symbols: h = higher row, l = lower row, l = left position in a given row, m = middle position in a given row, r = right position in a given row),

-- full-stop,

-- symbol of the monograph (i.e. 2e for monograph [2e], or 1_3 for monograph [1/3]),

-- full-stop,

-- format of the file containing a given illustration (i.e. symbol "gif" for hand drawings type "linart", and symbol "jpg" for photographs).

Sometimes, after the number of drawing a word "framed" appears. This work means "an illustration surrounded with a separate frame and added to a main illustration".

It should be indicated that for Figures which are combined from several separate illustrations and for which individual illustrations are not marked with symbols (a), (b, (c), ... or (1), (2), (3), ... a system of indicating the position of a given illustration is used. This system uses the following symbols:

h = high,

l = low,

hl = high-left,

hm = high-middle,

hr = high-right,

ll = low-left,

lm = low-middle,

lr = low-right.

Of course, when the subsequent illustrations are located in the order of their reading, then their location is clearly indicated with the alphabet letters: a, b, c, etc.; or subsequent numbers: 1, 2, 3, etc. In some circumstances, in stead of position on Figure, a view of a given illustration is indicated. This view was marked with a symbol "s" from "side view", or with symbol "t" from "top view". In some cases before the symbol "s" or symbol "t" a digit "1", "2" or "3" can be used. In such cases the digit indicates the generation (thus the marking "3t" indicated the top view of the 3-rd generation).

- On the list below each subsequent illustration is listed in a separate row (if a given Figure includes several illustrations, the first row with the general title of this illustration does not include any computer file with a scan);

- Symbol & placed in front of some illustrations indicates photographs scanned in colours.

List: Below subsequent illustrations included into the content of monograph [2e] are listed together with filenames which are storing scans of these illustrations. Filenames are given in two columns. The first of these columns, marked as "filename in [1/3]", provides the name of file with this illustration in the list of illustrations published in monograph [1/3]. In turn the columns "filename in [2e] indicates the name of file with this illustration supplied with the monograph [2e]. Symbol ~ marks illustration very similar but not identical.

------

Fig. No. Description - what is on this illustration- filename in [1/3]- filename in [2e]

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Tab B1. The Periodic Table for propulsion systems.~ b1_tab.1_3.gif- b1_tab.2e.gif

Fig. B1. A side view of the smallest Magnocraft K3 type - f1a.1_3.gif- b1.2e.gif

Fig. B2. The Magnocraft above the equator.- f21.1_3.gif- b2.2e.gif

Tab C1. Periodic Table showing power producing devices~ k1_tab.1_3.gif- c1_tab.2e.gif

Fig. C1. A photo of the "extraction glow" (Vshaped rod)- j1.1_3.jpg- c1.2e.jpg

Fig. C2. The temperature drop in the hands of a healer.

(a) Distribution of temperatures at 10:12- j3a.1_3.jpg- c2a.2e.jpg

(b) Distribution of temperatures at 10:14- j3b.1_3.jpg- c2b.2e.jpg

Fig. C3. An elementary Telekinetic Effect (P).~7.6e.gif- c3.2e.gif

Fig. C4. The operation of the Johnson telekinetic motor.- k1.1_3.gif- c4.2e.jpg

Fig. C5. A photo of a telekinetic generator "NMachine".- k2.1_3.jpg- c5.2e.jpg

Fig. C6. The design and operation of the NMachine.- k3.1_3.gif- c5.2e.gif

&Fig. C7. Photograph of the INFLUENZMASCHINE.- k4.1_3.jpg- c7.2e.jpg

Fig. C8. The operation of the INFLUENZMASCHINE. ~13.6e.gif- c8.2e.gif

Fig. C9. The evolution of a technical idea.

(a) The aeolipile (Hero z Aleksandrii, 130 BC)- k8a.1_3.gif- c9a.2e.gif

(b) Steam turbine (C. A. Parsons, 1884)- k8b.1_3.gif- c9b.2e.gif

&Fig. D1. Mr Alan Plank with his pump.- h2.1_3.jpg- d1.2e.jpg

Fig. D2. A technique for YES/NO answers in a pendulum.- h1.1_3.gif- d2.2e.gif

Fig. D3. A wedge of the Universe in threedimensions.- h3.1_3.gif- d3.2e.gif

Fig. D4. Photo of tables levitated by Eusapia Palladino.

(góra) Stó_ lewitowany w Londynie w 1903 roku- j2h.1_3.gif- d4h.2e.gif

(dó_) Fotografia z ksi__ki "Spirits & Spirit Worlds" - j2l.1_3.gif- d4l.2e.gif

Fig. D5. Photographs of a table levitated by SORRAT.

(left) The table lifted physically~d3a.4i.jpg- d5l.2e.jpg

(right) The table lifted telekinetically ~d3b.4i.jpg- d5r.2e.jpg

Fig. E1. Blenkinsop's engine built in 1811.- o30.1_3.jpg- e1.2e.jpg

Fig. F1. The evolution of the Oscillatory Chamber.- c1.1_3.gif- f1.2e.gif

Fig. F2. The appearance of the Oscillatory Chamber~ c3.1_3.gif- f2.2e.gif

Fig. F3. The neutralization of the electromagnetic forces- c4.1_3.gif - f3.2e.gif

Fig. F4. The "twinchamber capsule".- c5.1_3.gif- f4.2e.gif

Fig. F5. Appearances of twinchamber capsules.- c6.1_3.gif - f5.2e.gif

Fig. F6. Outputs from chambers of twinchamber capsule- c7.1_3.gif- f6.2e.gif

Fig. F7. An arrangement called "spider configuration".- c9.1_3.gif- f7.2e.gif

Fig. F8. The curve of the "interactions in equilibrium"- c12.1_3.gif- f8.2e.gif

Fig. F9. Experimental station for the Oscillatory Chamber.

(a) Working model of the chamber in dakness.- c13a.1_3.jpg - f9a.2e.jpg

(b) Photograph of the experimental station.- c13b.1_3.jpg - f9b.2e.jpg

Fig. F10. The justification for needleshaped electrodes.- c2.1_3.gif- f10.2e.gif

Tab G2. The coupled Magnocraft: K factor versus D/h.~ f2_tab.1_3.gif- g2_tab.2e.gif

Fig. G1. Tilting the magnetic propulsor.- f2.1_3.gif- g1.2e.gif

Fig. G2. The magnetic propulsion unit of the Magnocraft.- f3.1_3.gif- g2.2e.gif

Fig. G3. Alternative flight positions: upright and inverted.- f4.1_3.gif- g3.2e.gif

Fig. G4. The appearance of the Magnocraft type K3.- f1b.1_3.gif- g4.2e.gif

Fig. G5. The Magnocraft's design and the main features.- f5.1_3.gif- g5.2e.gif

Fig. G6. Six classes of arrangements of the Magnocraft.

#1. Flying complex (cigar-shaped)- f6_1.1_3.gif- g6_1.2e.gif

#2. Semi-attached configuration- f6_2.1_3.gif- g6_2.2e.gif

#3. Detached configuration- f6_3.1_3.gif- g6_3.2e.gif

#4. Carrier platform- f6_4.1_3.gif- g6_4.2e.gif

#5. Flying systems- f6_5.1_3.gif- g6_5.2e.gif

#6. Flying clusters- f6_6.1_3.gif- g6_6.2e.gif

Fig. G7. A spherical complex of K3 type Magnocraft.- f1c.1_3.gif- g7.2e.gif

Fig. G8. A stacked cigar of K6 type Magnocraft.

(a) Side view od the whole cigar- f7a.1_3.gif- g8a.2e.gif

(b) Vertical cross-section of the cigar (propulsors)- f7b.1_3.gif- g8b.2e.gif

Fig. G9. A doubleended cigarshaped flying complex.- f8_1.1_3.gif- g9.2e.gif

Fig. G10. Example of a "firtree" shaped flying complex.

(a) Vertical cross-section showing propulsors.- f8_2a.1_3.gif- g10a.2e.gif

(b) Side view.- f8_2b.1_3.gif- g10b.2e.gif

Fig. G11. A very simple semiattached configuration K3.- f9a.1_3.gif- g11.2e.gif

Fig. G12. A "flying necklace" semiattached configuration. - f9b.1_3.gif- g12.2e.gif

Fig. G13. An example of a K7 detached configuration.

(high) External appearence.- f10h.1_3.gif- g13h.2e.gif

(low) Vertical cross-section showing propulsors.- f10l.1_3.gif- g13l.2e.gif

Fig. G14. An example of a carrier platform.- f11a.1_3.gif- g14.2e.gif

Fig. G15. The "zigzag" carrier configuration.- f11b.1_3.gif- g15.2e.gif

Fig. G16. Examples of flying systems.

(a) A single cell made of 16 K3 Magnokrafts- f12a.1_3.gif- g16a.2e.gif

(b) Flying system shaped as a "flutes"- f12b.1_3.gif- g16b.2e.gif

(d) Flying system shaped as a "platform"- f12d.1_3.gif- g16d.2e.gif

Fig. G17. An example of a flying cluster.- f13.1_3.gif- g17.2e.gif

Fig. G18. Coupling a through a detached configuration.- f14_1.1_3.gif- g18.2e.gif

Fig. G19. Coupling through a semiattached configuration. - f14_2.1_3.gif- g19.2e.gif

Fig. G20. Force interactions acting in Magnocraft. - f15.1_3.gif- g20.2e.gif

Fig. G21. A top view of one cell of the flying system K3.- f16.1_3.gif- g21.2e.gif

Fig. G22. The flanges meshing in flying systems.

(a) A cigar meshed with a single K3 Magnokraft- f17a.1_3.gif- g22a.2e.gif

(b) Two cigar K6 mutually meshed (6 vehicles)- f17b.1_3.gif- g22b.2e.gif

Fig. G23. Shape & dimension equations of a Magnocraft.- f18.1_3.gif- g23.2e.gif

Fig. G24. Side outlines of eight basic types of Magnocraft.

(a) Types K3 to K6 with lens-shaped flange:

K3 type- f19a_k3.1_3.gif- g24a_k3.2e.gif

K4 type- f19a_k4.1_3.gif- g24a_k4.2e.gif

K5 type- f19a_k5.1_3.gif- g24a_k5.2e.gif

K6 type- f19a_k6.1_3.gif- g24a_k6.2e.gif

(b) K7 to K10 with horse-wagon shaped flange:

K7 type- f19b_k7.1_3.gif- g24b_k7.2e.gif

K8 type- f19b_k8.1_3.gif- g24b_k8.2e.gif

K9 type- f19b_k9.1_3.gif- g24b_k9.2e.gif

K10 type- f19b_k10.1_3.gif- g24b_k10.2e.gif

Fig. G25. Methods of identifying the Magnocraft's type.- f20.1_3.gif- g25.2e.gif

Fig. G26. The creation of a latitudinal thrust force.- f22a.1_3.gif- g26.2e.gif

Fig. G27. The "rolling sphere rule" for flight direction.- f22b.1_3.gif- g27.2e.gif

Fig. G28. The counteracting of the magnetic whirl.- f23.1_3.gif- g28.2e.gif

Fig. G29. The magnetic circuits in a K6 Magnocraft.- f24.1_3.gif- g29.2e.gif

Fig. G30. The spinning circuits of a K6 type Magnocraft.

(a) The vertical cross-section showing propulsors- f25a.1_3.gif- g30a.2e.gif

(b,c) Side view showing magnetic circuits- f25bc.1_3.gif- g30bc.2e.gif

Fig. G31. Converting field pulses into a magnetic whirl.- f26.1_3.gif- g31.2e.gif

Fig. G32. An example of the "ionic picture of a whirl".- f27.1_3.gif- g32.2e.gif

Fig. G33. View of propulsors in a K3 type Magnocraft.

(a) The upward view of K3 Magnocraft.- f28a.1_3.gif- g33a.2e.gif

(b) Side view of the detached configuration.- f28b.1_3.gif- g33b.2e.gif

Fig. G34. Multiple images of glowing magnetic circuits.- f29.1_3.gif- g34.2e.gif

Fig. G35. The SUB system of position lamps.- f30.1_3.gif- g35.2e.gif

Fig. G36. Tunnels formed by the Magnocraft.- f31.1_3.gif- g36.2e.gif

Fig. G37. A magneticlens effect in ascending Magnocraft.- f32.1_3.gif- g37.2e.gif

Fig. G38. Shapes of marks left by a single Magnocraft.- f33.1_3.gif- g38.2e.gif

Fig. G39. Typical marks in hovering close to the ground.- f34.1_3.gif- g39.2e.gif

Fig. G40. Landings of an inverted Magnocraft.- f35.1_3.gif- g40.2e.gif

Fig. G41. Plants swirled by circuits whirling in the air.- f36.1_3.gif- g41.2e.gif

Fig. G42. Examples of landings by flying systems.

(a) Landing of a single cell of flying system- f37a.1_3.gif- g42a.2e.gif

(b) Landing of a "platform" flying system- f37b.1_3.gif- g42b.2e.gif

Fig. H1. A FourPropulsor Magnocraft.- d1a.1_3.gif - h1.2e.gif

Fig. H2. Propulsors of the FourPropulsor Magnocraft.- d1bc.1_3.gif - h2.2e.gif

Fig. I1. The Magnocraft and personal propulsion system.

(a) Magnocraft K3 type in hanging position.- e1a.1_3.gif - i1a.2e.gif

(b) The propelling system in personal propulsion. - e1b.1_3.gif - i1b.2e.gif

Fig. I2. The standard personal propulsion garment.- e2.1_3.gif - i2.2e.gif

Fig. I3. External and internal magnetic forces.

(left) External forces in personal propulsion.- e3l.1_3.gif- i3l.2e.gif

(right) Internal forces in personal propulsion.- e3r.1_3.gif - i3r.2e.gif

Fig. I4. Examples of two modifications of personal propulsion.

(a) Personal propulsion with propulsors in epolettes.- e4a.1_3.gif- i4a.2e.gif

(b) Personal propulsion with a helment and cushion.- e4b.1_3.gif- i4b.2e.gif

Fig. K1. Comparison of the Magnocraft to a UFO.- o1.1_3.jpg- k1.2e.gif

(Framed) The appearnence of K3 Magnocraft.- o1_framed.1_3.jpg- k1_framed.2e.gif

Fig. K2. A spherical flying complex of two UFOs type K6.

(ab) Side view of the spherical flying komplex.- o9ab.1_3.gif- k2ab.2e.gif

(d) Enlargement of a UFO from Thorn's photograph- o9d.1_3.jpg- k2d.2e.jpg

(e) Shape of Thorn's UFO in GICOFF reconstruction- o9e.1_3.jpg- k2e.2e.jpg

Fig. K3. A photo of a cigarshaped flying complex of UFOs.

(a) Cigar-shaped UFO from Palomar Gardens, 1952- o10a.1_3.jpg- k3a.2e.jpg

(b) Cigar-shaped UFO from Palermo, Sycili, 1978- o10b.1_3.jpg- k3b.2e.jpg

(d) Enlargement of cigar UFO from New York (c)- o10d.1_3.jpg- k3d.2e.jpg

Fig. K4. The location of propulsors in UFOs.

(A) Propulsors of a K3 Magnocraft K3 from below- o15a.1_3.gif- k4a.2e.gif

(B) Propulsors of a K3 UFO photographed from below- o15b.1_3.jpg- k4b.2e.jpg

Fig. K5. Photos of UFOs with pulsating magnetic field.

#1. Principles involved in multiple images of UFOs- o18_1.1_3.gif- k5_1.2e.gif

#2. Very fast flaying UFO from Chamberlain- o18_2.1_3.jpg- k5_2.2e.jpg

#3. Pulsating UFO by Karl Maier dated 1962- o18_3.1_3.jpg- k5_3.2e.jpg

Fig. K6. Magnetic circuits and magnetic whirl of UFOs.

AB. Magnocraft's magnetic circuits- o19ab.1_3.gif- k6ab.2e.gif

C. Side photo of magnetic circuits in K6 UFO- o19c.1_3.jpg- k6c.2e.jpg

D. Upright photo of a propulsor and circuits' fragment - o19d.1_3.jpg- k6d.2e.jpg

Fig. K7. An eastern section of the Tapanui Crater.- p4.1_3.jpg- k7.2e.jpg

Fig. K8. Similarities between Tapanui and Tunguska.- p5.1_3.gif- k8.2e.gif

Fig. K9. Tunnels made in underground flights of UFOs.

(a) Tunnel Morona-Santiago, Ecuador- p6a.1_3.jpg- k9a.2e.jpg

(b) Cocklebiddy Cave, Australia- p6b.1_3.jpg- k9b.2e.jpg

(d) Deer Cave, Borneo, Malaysia- p6d.1_3.jpg- k9d.2e.jpg

(e) The author at the S entrance to Deer Cave- p6e.1_3.jpg- k9e.2e.jpg

Fig. K10. Photographs of landing sites from single UFOs.

(A) Two concentric rings- p1a.1_3.jpg- k10a.2e.jpg

(B) One ring with a central scorching- p1b.1_3.jpg- k10b.2e.jpg

(D) Comparison of landings by UFO K4, K6 & K7- p1d.1_3.jpg- k10d.2e.jpg

Fig. K11. UFO landing sites made by flying clusters.

(a) A crop circles from UFO K6 type, England- p3a.1_3.jpg- k11a.2e.jpg

(b) A crop circle from Ashburton, New Zealand, 1992.

(high) Photo of the whole circle- p3bh.1_3.jpg- k11bh.2e.jpg

(low) Photo of the crop field with the cicle- p3bl.1_3.jpg- k11bl.2e.jpg

Fig. K12. Mathematical relationships in crop circles.- f38.1_3.gif- k12.2e.gif

Fig. L1. Detached configuration of two UFOs.

(a) External view of a detached configuration - s1a.1_3.gif- l1a.2e.gif

(b) Vertical cross-section through such a UFO- s1b.1_3.gif- l1b.2e.gif

(d) Enlargement of the vehicle showing "black bars"- s1d.1_3.jpg- l1d.2e.jpg

(e) The same configuration a while later- s1e.1_3.jpg- l1e.2e.jpg

Fig. L2. "Black bars" in a UFO.

(a) "Balck bars" in a spool-shaped UFO- s2a.1_3.gif- l2a.2e.gif

(b) UFO K3 shaped like a spool, Brazil, 1969- s2b.1_3.gif- l2b.2e.gif

Fig. L3. A UFO's twin-chamber capsule scorched in grass. - s3.1_3.jpg- l3.2e.jpg

Fig. L4. A twinchamber capsule from an ascending UFO.- s4.1_3.gif- l4.2e.gif

Fig. L5. Photos of twin-chamber capsules from UFOs.

(left) Kolour photo of a UFO capsule of 1st gener. - s5l.1_3.jpg- l5l.2e.jpg

(right) Night photo of a 1st generation UFO capsule - s5r.1_3.jpg- l5r.2e.jpg

Fig. L6. Magnocraft's Oscillatory Chamber seen on a UFO.

(left)The predicted appearance of a chamber- s6l.1_3.gif- l6l.2e.gif

(right)Observed appearance of a UFO chamber- s6r.1_3.gif- l6r.2e.gif

Fig. L7. An ancient plan for an Oscillatory Chamber.- s7.1_3.gif- l7.2e.gif

Fig. M1. A fourpropulsor UFO which abducted Jan Wolski.- q1.1_3.gif- m1.2e.gif

Fig. M2. The night appearance of a fourpropulsor UFO.

(a) Witnesse's oryginal sketch of the UFO- q2a.1_3.gif- m2a.2e.gif

(b) Author's rekonstruction of this UFO- q2b.1_3.gif- m2b.2e.gif

Fig. M3. A photograph of a fourpropulsor UFO. - q1.1_3.jpg- m3.2e.jpg

Fig. N1. UFOnauts and their vehicle by S. Mas_owski.- r1.1_3.jpg- n1.2e.jpg

(Framed) Appearance of a K3 Magnocraft- r1_framed.1_3.gif- n1_framed.2e.gif

Fig. N2. A UFOnaut with a glowing belt.- r2.1_3.jpg- n2.2e.jpg

Fig. N3. One flash pictures of UFOnaut by Jeff Greenhaw.- r3.1_3.jpg- n3.2e.jpg

Fig. N4. A UFOnaut calling himself "Ausso".- r4.1_3.gif- n4.2e.gif

Fig. N5. A UFOnaut climbing a wall.- r5.1_3.gif- n5.2e.gif

Fig. N6. Footprint of an UFOnaut.- r6.1_3.jpg- n6.2e.jpg

Fig. O1. UFOs of 2nd generation with telekinetic propulsors.- t1.1_3.jpg- o1.2e.jpg

Passport photograph of the autor ("About the autor")- prof_pajak.1_3.jpg- prof_pajak.2e.jpg