1. A universal synthetic gasoline conditioner additive product, produced by a method comprising:
blending polymerized alpha-olefins, low odor aromatic solvents, 2-Propanol, and at least one base oil selected from the base oil group consisting of hydroisomerized base oils and severe hydro-cracked base oils, until the blend is a consistent amalgamation without any appearance of separation, thereby producing a primary blend;
separately, blending an octane booster, detergent, acid neutralizer blend, thereby producing a secondary blend; and
adding said secondary blend to said primary blend.
2. The product-by-process of claim 1, said method further comprising adding low flash mineral spirits to said primary and secondary blend.
3. The product-by-process of claim 2, wherein said low flash mineral spirits have been subjected to hydrodesulfurization.
4. The product-by-process of claim 1, said method further comprising:
separately blending synthetic calcium sulfonates and low flash mineral spirits, thereby producing a tertiary blend; and
adding said tertiary blend to said primary and secondary blend.
5. The product-by-process of claim 4, wherein said low flash mineral spirits have been subjected to hydrodesulfurization.
6. The product-by-process of claim 2, said method further comprising adding at least one depressant; isomer reformate; and dimethyl ketones to the blend of primary and secondary blends and low flash mineral spirits.
7. The product-by-process of claim 6, said at least one depressant selected from the group consisting of pour point depressants and cloud point depressants.
8. The product-by-process of claim 4, said method further comprising adding at least one depressant; isomer reformate; and dimethyl ketones to said primary, secondary, and tertiary blends.
9. The product-by-process of claim 8, said at least one depressant selected from the group consisting of pour point depressants and cloud point depressants.
10. The product-by-process of claim 6, said method further comprising adding solvent activated dyes to the blend of primary and secondary blends and low flash mineral spirits.
11. The product-by-process of claim 8, said method further comprising adding solvent activated dyes to said primary, secondary, and tertiary blends.
12. A universal synthetic gasoline conditioner additive product, produced by a method comprising:
blending polymerized alpha-olefins, low odor aromatic solvents, 2-Propanol, and at least one base oil selected from the base oil group consisting of hydroisomerized base oils and severe hydro-cracked base oils, until the blend is a consistent amalgamation without any appearance of separation, thereby producing a primary blend; and
adding polyether amine to said primary blend.
13. The product-by-process of claim 12, said method further comprising:
adding said polyether amine to said primary blend by separately blending said polyether amine; petroleum naphtha; naphthalene; and hydrocarbon solvent, thereby producing a secondary blend; and adding said secondary blend to said primary blend.
14. The product-by-process of claim 12, said method further comprising:
separately blending 2-ethylhexyl nitrate; petroleum naphtha; naphthalene; and hydrocarbon solvent, thereby producing a secondary blend; and
adding said secondary blend to said primary blend.
15. The product-by-process of claim 14, said method further comprising:
adding low flash mineral spirits to said primary and secondary blend.
16. The product-by-process of claim 14, said method further comprising:
separately blending synthetic calcium sulfonates and low flash mineral spirits, thereby producing a tertiary blend; and
adding said tertiary blend to said primary and secondary blend.
17. The product-by-process of claim 15, said method further comprising:
adding solvent activated dyes; at least one depressant selected from the group consisting of pour point depressants and cloud point depressants; isomer reformate; and dimethyl ketones, to said blend of primary and secondary blends, and said low flash mineral spirits.
18. The product-by-process of claim 16, said method further comprising:
adding solvent activated dyes; at least one depressant selected from the group consisting of pour point depressants and cloud point depressants; isomer reformate; and dimethyl ketones, to said primary, secondary, and tertiary blends.
19. A method of producing a universal synthetic gasoline conditioner additive, comprising:
blending polymerized alpha-olefins, low odor aromatic solvents, 2-Propanol, and at least one base oil selected from the base oil group consisting of hydroisomerized base oils and severe hydro-cracked base oils, until the blend is a consistent amalgamation without any appearance of separation, thereby producing a primary blend;
separately, blending an octane booster, detergent, acid neutralizer blend, thereby producing a secondary blend; and
adding said secondary blend to said primary blend.
20. The method of claim 19, said method further comprising adding low flash mineral spirits to said primary and secondary blend.
21. The method of claim 20, wherein said low flash mineral spirits have been subjected to hydrodesulfurization.
22. The method of claim 19, said method further comprising:
separately blending synthetic calcium sulfonates and low flash mineral spirits, thereby producing a tertiary blend; and
adding said tertiary blend to said primary and secondary blend.
23. The method of claim 22, wherein said low flash mineral spirits have been subjected to hydrodesulfurization.
24. The method of claim 20, said method further comprising adding at least one depressant; isomer reformate; and dimethyl ketones to the blend of primary and secondary blends and low flash mineral spirits.
25. The method of claim 24, said at least one depressant selected from the group consisting of pour point depressants and cloud point depressants.
26. The method of claim 22, said method further comprising adding at least one depressant;
isomer reformate; and dimethyl ketones to said primary, secondary, and tertiary blends.
27. The method of claim 26, said at least one depressant selected from the group consisting of pour point depressants and cloud point depressants.
28. The method of claim 24, said method further comprising adding solvent activated dyes to the blend of primary and secondary blends and low flash mineral spirits.
29. The method of claim 26, said method further comprising adding solvent activated dyes to said primary, secondary, and tertiary blends.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. An image processing apparatus outputting an image signal corresponding to one frame of an input video signal formed by a plurality of sub frames, comprising:
a processing region detection portion including a first detection portion detecting motion of an image in a sub frame from the plurality of sub frames continuing in time, and a second detection portion detecting a component having a predetermined value or more of level difference to peripheral pixels on a pixel forming an image in the sub frame; and
a gradation conversion portion including a plurality of adaptive gradation conversion portions each converting the gradation for a region of a respective component having the level difference at which motion in the corresponding sub frame is detected among the plurality of sub frames by the first and second detection portions in accordance with the motion detected value and the detected value of level difference detected at the processing region detection portion and a sub frame selecting and outputting portion selecting and outputting selectively gradation-converted sub frames by switching these sub frames for each sub frame rate,
wherein the apparatus further comprises a frame rate conversion portion converting a frame of the input video signal to a plurality of sub frames having a higher rate than the respective frame and outputting the converted sub frames to the processing region detection portion and the gradation conversion portion.
2. An image processing apparatus as set forth in claim 1, wherein each of the adaptive gradation conversion portions converts the gradation according to a predetermined characteristic corresponding to a brighter level and a darker level than the image signal.
3. An image processing apparatus as set forth in claim 1, wherein the luminance of a certain image at the time, when a plurality of sub frames converted by the adaptive gradation conversion portions are displayed by the improved pseudo impulse drive, is approximately equal to the luminance at the time when one frame of the input signal before the conversion is displayed by the predetermined display drive.
4. An image processing apparatus as set forth in claim 1, wherein
the component, having the predetermined value or more of level difference detected by the second detection portion in the processing region detection portion, is an edge component forming a contour of the image, and
each adaptive gradation conversion portion in the gradation conversion portion selectively performs the gradation conversion to the region at which motion was detected at the first detection portion in the sub frame image and detected as an edge component at the second detection portion.
5. An image processing apparatus as set forth in claim 4, wherein the adaptive gradation conversion portions perform the gradation conversion according to predetermined characteristics corresponding to a brighter level and a darker level than the image signal.
6. An image processing method outputting an image signal corresponding to one frame of an input video signal by a plurality of sub frames, comprising:
a first step of detecting motion of an image in a sub frame from the plurality of sub frames continuing in time,
a second step of detecting a component, having a predetermined value or more of level difference to peripheral pixels on a pixel forming an image in the sub frame,
a third step of converting the gradation for a region of a respective component having the level difference at which motion in the corresponding sub frame is detected among the plurality of sub frames by the first and second steps, and
a fourth step of switching and selecting the selectively gradation-converted sub frames for each sub frame rate and outputting the selected sub frame,
wherein the first step and the second step are performed by a processing region detection portion of an image processing apparatus and the third step and the fourth step are performed by a gradation conversion portion of the image processing apparatus, and
wherein the method further comprises converting a frame of the input video signal to a plurality of sub frames having a higher rate than the respective frame and outputting the converted sub frames to the processing region detection portion and the gradation conversion portion.