CN101995665A - Optical system for a digital light projection system including 3-channel and 4-channel LED array light engines - Google Patents
Optical system for a digital light projection system including 3-channel and 4-channel LED array light engines Download PDFInfo
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- CN101995665A CN101995665A CN2010102606677A CN201010260667A CN101995665A CN 101995665 A CN101995665 A CN 101995665A CN 2010102606677 A CN2010102606677 A CN 2010102606677A CN 201010260667 A CN201010260667 A CN 201010260667A CN 101995665 A CN101995665 A CN 101995665A
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Abstract
An optical system for a digital light projection system is provided. The optical system comprises a plurality of LED arrays, wherein each LED array comprises a plurality of LEDs. The optical system also comprises an optical concentrator element positioned substantially adjacent to each of the LED arrays, wherein each concentrator element totally internally reflects light emitted from the plurality of LEDs within the corresponding LED array so as to provide substantially uniform light at an output surface of each concentrator element, and wherein the concentrator element has a complex conic shape. The optical system preferably further comprises an optical combiner element, wherein the output surface of each concentrator element is positioned substantially adjacent to a corresponding side of the combiner element, and wherein the combiner element spatially combines the substantially uniform light arranged at the output surface of each concentrator element so as to form substantially white light at an output surface of the combiner element.
Description
Technical field
Present invention relates in general to the digital light projection systems field, relate more specifically to be used to comprise the optical system of the digital light projection systems of 3 channel LED array ray machines.
Background technology
At digital light projection (DLP) system, need a kind ofly can on illumination path, to produce even basically and be essentially the optical system of white light.Traditional optical system that is used for the DLP system for example comprises the light source such as high strength mercury lamp or xenon lamp.Yet these traditional optical systems and corresponding light source for example have the shortcoming such as non-homogeneous light, non-white light and luminance shortage.In addition, these conventional optical systems produce excessive heat and design height complexity, thereby cause making process and the technical sophistication and the costliness of optical system.
Therefore, be desirable to provide a kind of optical system that can overcome above-mentioned defective and can make in cheap mode efficiently.
Therefore, be desirable to provide a kind of optical system that comprises the optical collector element of led array and correspondence, this optical system can be used in the DLP system and overcome the above-mentioned defective that conventional optical systems had.In addition, when addressing these problems, the described led array and the optical system of the optical collector element of correspondence of comprising of the present invention also will provide even light, white light and the brightness of the desirable excellence of DLP system.
According to following detailed description of the present invention, these and other advantages of the present invention will be clear fully.
Summary of the invention
The present invention is devoted to provide a kind of optical system that is used for digital light projection systems, and this optical system comprises a plurality of led array, and wherein each led array comprises a plurality of LED.Described optical system also comprises near the optical collector element that is located substantially on each led array, wherein the light of a plurality of LEDs emissions of each optical collector element total internal reflection in the led array of correspondence provides basically light uniformly with the output surface place at each optical collector element.Described optical system also can comprise the optical combiner element, wherein the output surface of each optical collector element is located substantially near the respective side of combiner element, and the uniform basically light that the output surface place that is combined in to wherein said combiner element space each optical collector element provides forms white light basically with the output surface place in this combiner element.
Description of drawings
In order more to be expressly understood the present invention and to be convenient to implement the present invention, will the present invention be described in conjunction with the following drawings, in the accompanying drawings:
Fig. 1 is an illustration comprises the normal axomometric drawing of the digital light projection systems of 3 channel LED array structures according to the preferred embodiment of the invention.
Fig. 2 is the left side view of the digital light projection systems shown in Fig. 1.
Fig. 3 is the right side view of the digital light projection systems shown in Fig. 1.
Fig. 4 is the planimetric map of the digital light projection systems shown in Fig. 1.
Fig. 5 is the sectional view of the digital light projection systems shown in Fig. 1.
Fig. 6 is the amplification profile left side view of the part of the digital light projection systems shown in Fig. 1, and it comprises 3 optical collector elements, optical combiner element and 3 led array.
Fig. 7 is the amplification normal axomometric drawing of the part of the digital light projection systems shown in Fig. 1, and it comprises optical collector element, led array and corresponding led array installing plate.
Fig. 8 is the amplification view of the part of the digital light projection systems shown in Fig. 1, and it comprises led array and corresponding led array installing plate.
Fig. 9 is the normal axomometric drawing of the part of the digital light projection systems shown in Fig. 1, and it comprises led array and corresponding led array installing plate.
Figure 10 is the planimetric map of the part of the digital light projection systems shown in Fig. 1, and it comprises optical combiner element, lamp optical system, total internal reflection (TIR) prism, digital imagery device and projection optical system.
Figure 11 is the left side view of the structure shown in Figure 10.
Figure 12 is the expansion planimetric map of the structure shown in Figure 10.
Figure 13 is the amplification normal axomometric drawing of the optical collector element shown in Fig. 7.
Figure 14 is the amplification normal axomometric drawing that has another optical collector element of rectangle input surface and rectangle output surface according to the preferred embodiment of the invention.
In Fig. 1, component information is as shown in the table:
| Item No. | | Part number | |
| 1? | 1? | OSA armature 2-25-05 | |
| 2? | 1? | Projection housing 2-25-05 | |
| 9? | 1? | Camera lens 6-8300-01-006 | |
| 22? | 1? | DMD PC plate 2-09-05 | |
| 32? | 1? | |
|
| 33? | 1? | |
|
| 52? | 1? | Deviation mirror 23-09-05 | |
| 53? | 1? | |
|
| 55? | 1? | TIR prism |
|
| 57? | 1? | |
|
| 58? | 1? | Beam |
|
| 66? | 1? | Luminaire housing 3-8-05 | |
| 71? | 1? | The LED housing | |
| 87? | 3? | The LED heating radiator |
In Fig. 6, component information is as shown in the table:
| Item No. | | Part number | |
| 1? | 2? | The M2 |
|
| 2? | 1? | The aligning |
|
| 3? | 1? | The 1pc housing | |
| 4? | 4? | |
|
| 5? | 3? | The |
|
| 8? | 1? | The |
|
| 11? | 1? | Prism O type ring |
| 13? | 3? | The |
| 14? | 3? | OCE?bd- |
| 15? | 96? | The LL- |
| 16? | 3? | The accurately machined OCE of X-cube 1_ |
| 17? | 3? | The low profile |
| 18? | 3? | The |
| 19? | 3? | Heat radiator dedicated |
| 20? | 3? | |
Embodiment
Should be appreciated that accompanying drawing of the present invention and describe and simplify, concern being expressly understood element of the present invention with illustration, for purpose clearly, removed other elements in the typical digital light projection systems simultaneously.Those skilled in the art will recognize that, in order to implement the present invention, other elements can be wish and/or be essential.Yet, because these elements are known in the field, and owing to they do not help understand the present invention better, so do not provide the description about these elements herein.It is also understood that the included accompanying drawing of this paper has only provided the diagrammatic representation for current preferred structure of the present invention, the structure that falls within the scope of the present invention can comprise and is different from the structure shown in these accompanying drawings.With quoted figures, wherein give similar Reference numeral below to similar structure.
For purposes of this disclosure, term " complicated taper (complex conic shape) " is defined as the shape that has by at least 1 side of at least 2 different equation definition thus.
Shown in Fig. 1 is digital light projection (DLP) system 100 according to preferred illustrative embodiment of the present invention.This DLP system is assembling and the orientation to following element, these elements comprise: armature 1, projection housing 2, camera lens 9, Digital Micromirror Device (DMD) plate 22, camera lens strap (strap) 32,33, turn to (folding) mirror 52,53, total internal reflection (TIR) prism top cover 55, TIR prism protecgulum 57, beam dump 58, luminaire housing 66, light emitting diode (LED) housing 71 and LED heating radiator 87.Although in this structure, adopt DMD as digital imagery device 75 (referring to Figure 10 to Figure 12), can envision other digital imagery device.
Fig. 2 is the left side view of the DLP system 100 shown in Fig. 1.Fig. 3 is the right side view of the DLP system 100 shown in Fig. 1.Fig. 4 is the planimetric map of the DLP system 100 shown in Fig. 1.Fig. 5 is the sectional view of the DLP system 100 shown in Fig. 1.
Fig. 6 (with reference to the section part of Fig. 5) is the amplification profile left side view of the part of the DLP system 100 shown in Fig. 1, and this part comprises 3 optical collector elements 16, optical combiner element 40 and 3 led array 150.Fig. 6 has gone back illustration pin 1, aligning dish 2, housing 3 (being preferably the aluminum component that casting or machine work form), prism 4, aperture 5, prism retainer 8, prism O type ring 11, spring 13, optical collector element board (or led array installing plate) 14, LED (wafer (die)) 15, low profile thermal fan diffuser 17, optical collector element lock 18, heat radiator dedicated 19 and optical collector component support 20.Although the LED (that is, having adopted LL-CREE XB290 in 3 passages) that adopts a kind of particular type has been shown in the preferred embodiment, other LED of other manufacturer also is feasible certainly.LED quantity in each led array is preferably 32, but also other number.In addition, the LED quantity in led array can be different from the LED quantity in other led array.
Fig. 7 is the amplification normal axomometric drawing of the part of the DLP system 100 shown in Fig. 1, and this part comprises optical collector element 16, led array 150 and corresponding led array installing plate 14.Fig. 7 also illustration preferred led circuit trace (trace) 46, it for example comprises gold.Led array installing plate 14 comprises the secondary installing plate 47 of LED, and it for example comprises beryllia.LED 15 can be directly installed on the led array installing plate 14, perhaps can be installed on the led array installing plate 14 by the accessory plate between LED 15 and led array installing plate 14.
Fig. 8 is the amplification view of the part of the DLP system 100 shown in Fig. 1, and this part comprises led array 150 and corresponding led array installing plate 14.The preferred size of LED 15 in the corresponding led array 150 and spacing are as (that is, A=0.30mm, B=0.30mm, C=1.90mm, and D=1.90mm) as illustrated in Fig. 8.Should be noted that size and the spacing that also can conceive other.Fig. 9 is the normal axomometric drawing of the part of the DLP system 100 shown in Fig. 1.
Contiguous basically each led array 150 of optical collector element 16 is provided with, the light of each a plurality of LEDs 15 of optical collector element 16 total internal reflections in the led array 150 of correspondence wherein, thus light uniformly is provided basically at the output surface place of each optical collector element 16.Optical collector element 16 is to form by diamond turning or molding process.Optical collector element 16 preferably includes plastics, glass or polymeric material or their combination, for example Zeonex that can withstand high temperature
Optical collector element 16 is set to directly contact with each led array.In the illustrated in the drawings preferred embodiment, optical collector element 16 is entities, wherein adopts TIR.Yet, can on part (or all) outside surface of optical collector element 16, form the reflection horizon, with the realization direct reflection, but not TIR.Alternatively, optical collector element 16 can be hollow and have reflecting surface and realize direct reflection.Alternatively can also conceive the optical collector element 16 that has made up TIR and direct reflection part.
Each led array comprises width preferably less than the LED of 0.35mm, and more preferably its optimal width is 0.30mm.LED in each led array is with spaced apart preferably less than the amount of 0.025mm with the adjacent LED in an array, and more preferably its optimum spacing is 0.02mm.Can also conceive other width and spacing outside these scopes within the spirit and scope of the present invention.
Quantity with lateral parts 16a, 16b of different equatioies can be greater than 2.Have that each size among lateral parts 16a, the 16b of different equatioies can change independently and can be unequal each other.The position also can be along changing independently to the longitudinal direction of output surface 16p from importing surperficial 16i.It is flat that the complicated taper of optical collector element 16 allows one among lateral parts 16a, the 16b.The lateral parts of bigger quantity can be crooked (that is, " crooked " is the equation that is different from " flat ") as long as at least one other lateral parts is arranged for flat.
Can also conceive other I/O surface configurations within the spirit and scope of the present invention.For example, optical collector element 16 can have circle (or oval) surperficial 16i of input and rectangle (for example, square) output surface 16p, perhaps can alternatively have rectangle (for example, square) input surface and circular (or oval) output surface.
In another alternative embodiment, optical collector element 1600 can alternatively have rectangle and import surperficial 1600i and rectangle output surface 1600p, as illustrated in Figure 14.Be similar to Figure 13, optical collector element 1600 among Figure 14 is along having complicated taper (and therefore having similar light homogeneity advantage) from importing surperficial 1600i to the longitudinal direction of output surface 1600p, and wherein at least one side of optical collector element 1600 comprises lateral parts (surface profile) 1600a, 1600b.Lateral parts 1600a is defined by first equation.Lateral parts 1600b is by second equation definition that is different from first equation.Equation can be represented any suitable shape, for example straight line, para-curve, or the like.This para-curve optical collector element 1600 with rectangle input and output surface obtains better pupil coupling thus.Then, rectangle input surface can preferably be designed to have the aspect ratio that the aspect ratio with imager (image device) is complementary, for example, and 16: 9.Because when the intermediate image that when the distance that fundamentally helps to reduce hot spot is watched, forms more even and smooth diffusion, so this configuration provides better far field uniformity coefficient.
The above-mentioned alternative means (for example, the quantity of lateral parts, size and/or position, and various I/O surface configuration) that can be used for similarly, optical collector element 16 at 1600 conceptions of optical collector element.
In structure shown in Figure 6, the feasible ruddiness from left side optical collector element 16 of combiner element reflects downwards, sees through green glow and blue light from other optical collector elements 16 simultaneously.Similarly, the feasible blue light from right side optical collector element 16 of same combiner element reflects downwards, sees through green glow and ruddiness from other optical collector elements 16 simultaneously.Yet same combiner element is a transmission-type, the feasible downward transmission of green glow from top optical collector element 16.Certainly, can change or change the position of these colors.
A plurality of led array preferably are made of 3 led array, and wherein these 3 led array preferably are made of 3 monochromatic LED arrays, and wherein each in these 3 monochromatic LED arrays preferably has the color that is different from each other.More preferably, these 3 monochromatic LED arrays are by the led array that only comprises red-light LED, only comprise the led array of green light LED and only comprise that the led array of blue-ray LED constitutes.Yet, alternatively can conceive multi-colored led array (that is the led array that, in same led array, has many colors LED).
Figure 10 is the planimetric map of the part of the DLP system 100 shown in Fig. 1, this part (for example comprises optical combiner element 40, TIR cube 76, preferably include 2 prisms, preferably have air interface (gap) between these 2 prisms) and digital imagery device 75.Among Figure 10 to Figure 12 also illustration the sample light line tracking.Figure 11 is the left side view of the structure shown in Figure 10.Figure 12 is the expansion planimetric map of the structure shown in Figure 10.The optical system that comprises lamp optical system 98 and projection optical system 99 parts of DLP system 100 that Figure 12 has gone back illustration.
(for example can adopt optical design software commonly used, ZEMAX (Focus Software, Inc.)) the corresponding various characteristics of each surf zone (for example, whether radius, thickness, type of glass, diameter and surface are taper) of each the individual component/group in next auxiliary description and the optical system.In Figure 10 and preferred illustrative embodiment shown in Figure 11, the surface data of description these character of surface of ZEMAX software output shown in table 1 and 2.Table 1 has specifically illustrated the corresponding data of lamp optical system 98 parts with DLP system 100, and table 2 has specifically illustrated the corresponding data of projection optical system 99 parts with DLP system 100.
Certainly, those of ordinary skills will know other surface data value of each individual component/group according to the disclosure, and convention experimental result that therefore can be by especially depending on one-piece construction and the independent location of element/group in optical system and the picture quality of hope are determined these other surface data values.
Table 1
ZEMAX software is exported the result, is used to describe the surface data summary and the details of each individual component in the lamp optical system 98.
The conventional lenses data
Surface: 58
Diaphragm: 18
System aperture: object space NA=0.342
Heart pattern far away: open
Glass classification: OHARA SCHOTT
Light aiming: close
Become mark: evenly, the factor=0.00000E+000
Effective focal length: 8.441475 (in the air, under system temperature and pressure)
Effective focal length: 8.441475 (at image spaces)
Back focal length :-1.62518
Total trace: 103.0885
Image space F/#:1.159715e-009
Paraxial work F/#:3.000081
Work F/#:3.786189
Image space NA:0.1643947
Object space NA:0.342
Diaphragm radius :-14.12827
Paraxial image height: 10.26355
Paraxial enlargement ratio :-2.183735
Entrance pupil diameter: 7.278919e+009
Entrance pupil position: 1e+010
Exit pupil diameter: 6.144481
Exit pupil position :-0.7151799
The field type: object height is unit with the millimeter
Maximum field: 4.7
Prima: 0.525
Lens unit: millimeter
Angle enlargement ratio: 1.184627e+009
: 8
The field type: object height is unit with the millimeter
# X value Y value weight
1 0.000000 -4.700000 1.000000
2 -4.700000 0.000000 1.000000
3 0.000000 0.000000 1.000000
4 0.000000 4.700000 1.000000
5 -4.700000 0.000000 1.000000
6 0.000000 2.350000 1.000000
7 0.000000 -2.350000 1.000000
8 4.680000 0.000000 1.000000
Vignetting factor
#?VDX VDY VCX VCY VAN
1?0.000000?0.000000?0.000000?0.000000?0.000000
2?0.000000?0.000000?0.000000?0.000000?0.000000
3?0.000000?0.000000?0.000000?0.000000?0.000000
4?0.000000?0.000000?0.000000?0.000000?0.000000
5?0.000000?0.000000?0.000000?0.000000?0.000000
6?0.000000?0.000000?0.000000?0.000000?0.000000
7?0.000000?0.000000?0.000000?0.000000?0.000000
8?0.000000?0.000000?0.000000?0.000000?0.000000
Wavelength: 3
Unit: μ m
# value weight
1 0.460000 0.100000
2 0.525000 0.100000
3 0.638000 0.100000
(wherein, Infinity represents infinite the surface data summary; MIRROR represents catoptron)
The surface data details
Surface OBJ:TILTSURF
X tangent: 0
Y tangent: 0
Surface 1:COORDBRK
Eccentric X:0
Eccentric Y:0
Tilt around X: 0
Tilt around Y: 0
Tilt around Z :-131
Order: off-centre tilts then
Surface 2:COORDBRK
Eccentric X:0
Eccentric Y:0
Tilt around X: 0
Tilt around Y: 0
Tilt around Z :-2.9
Order: off-centre tilts then
Surface 3:STANDARD
Aperture: rectangular aperture
X half width: 10
Y half width: 10
X off-centre: 0
Y off-centre :-0.5
Surface 4:STANDARD
Aperture: rectangular aperture
X half width: 10
Y half width: 10
X off-centre: 0
Y off-centre :-0.5
Surface 5:COORDBRK
Eccentric X:-5.2218237
Eccentric Y:0.54365794
Tilt around X: 1.9041816
Tilt around Y :-15.502077
Tilt around Z: 2.9
Order: off-centre tilts then
Surface 6:COORDBRK
Eccentric X:3.3921034
Eccentric Y:-0.66705067
Tilt around X :-5.3573672
Tilt around Y: 19.739401
Tilt around Z: 0
Order: off-centre tilts then
Surface 7:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 12
Surface 8:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 15
Surface 9:COORDBRK
Eccentric X:0.14501681
Eccentric Y:-1.0712542
Tilt around X :-0.066043177
Tilt around Y :-2.1064114
Tilt around Z: 0
Order: off-centre tilts then
Surface 10:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 17
Surface 11:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 17
Surface 12:COORDBRK
Eccentric X:0
Eccentric Y:0
Tilt around X: 47.8
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 13:STANDARD
Aperture: oval aperture
X half width: 17
Y half width: 23
X off-centre: 0
Y off-centre: 2.5
Surface 14:COORDBRK
Eccentric X:0
Eccentric Y:0
Tilt around X: 47.8
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 15:COORDBRK
Eccentric X:0.99137317
Eccentric Y:3.376614
Tilt around X :-1.475471
Tilt around Y :-0.81685172
Tilt around Z: 131
Order: off-centre tilts then
Surface 16:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 17.5
Surface 17:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 17.5
Surface STO:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 17.5
Surface 19:COORDBRK
Eccentric X:0
Eccentric Y:0
Tilt around X :-38.08
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 20:STANDARD
Aperture: oval aperture
X half width: 13.5
Y half width: 17
Surface 21:COORDBRK
Eccentric X:0
Eccentric Y:0
Tilt around X :-38.08
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 22:COORDBRK
Eccentric X:-0.47489395
Eccentric Y:-2.5440208
Tilt around X :-11.395468
Tilt around Y: 0.41607589
Tilt around Z: 0
Order: off-centre tilts then
Surface 23:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 10.75
Surface 24:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 13
Surface 25:COORDBRK
Eccentric X:0.14410789
Eccentric Y:0.37194946
Tilt around X: 4.0907234
Tilt around Y :-1.1395971
Tilt around Z: 0
Order: off-centre tilts then
Surface 26:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 14
Surface 27:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 14
Surface 28:COORDBRK
Eccentric X:-0.19341404
Eccentric Y:0.80152634
Tilt around X: 3.4489226
Tilt around Y: 0.68325579
Tilt around Z: 0
Order: off-centre tilts then
Surface 29:STANDARD
Surface 30:STANDARD
Aperture: rectangular aperture
X half width: 13.5
Y half width: 13.03
Surface 31:COORDBRK
Eccentric X:0
Eccentric Y:13.03
Tilt around X: 47
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 32:COORDBRK
Eccentric X:0
Eccentric Y:-23.565
Tilt around X: 0
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 33:STANDARD
Aperture: rectangular aperture
X half width: 13.5
Y half width: 23.57
Surface 34:COORDBRK
Eccentric X:0
Eccentric Y:-23.565
Tilt around X: 33
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 35:COORDBRK
Eccentric X:0
Eccentric Y:17.5
Tilt around X: 0
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 36:STANDARD
Aperture: rectangular aperture
X half width: 13.5
Y half width: 17.5
Surface 37:STANDARD
Surface 38:STANDARD
Surface 39:STANDARD
Surface 40:COORDBRK
Eccentric X:0
Eccentric Y:4451.5
Tilt around X: 0
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 41: paraxial
Focal length :-10000
OPD pattern: 0
Surface 42:COORDBRK
Eccentric X:0
Eccentric Y:-4451.5
Tilt around X: 0
Tilt around Y: 0
Tilt around Z: 0
Order: off-centre tilts then
Surface 43: paraxial
Focal length: 0
OPD pattern: 0
Surface 44:STANDARD
Surface 45:STANDARD
Surface 46:STANDARD
Surface 47:STANDARD
Aperture: rectangular aperture
X half width: 13.5
Y half width: 18
Surface 48:STANDARD
Aperture: rectangular aperture
X half width: 13.5
Y half width: 18
Surface 49:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 13
Surface 50:STANDARD
Aperture: the aperture of floating
Maximum gauge: 13.5
Surface 51:STANDARD
Aperture: the aperture of floating
Maximum gauge: 13.5
Surface 52:STANDARD
Aperture: the aperture of floating
Maximum gauge: 13.5
Surface 53:STANDARD
Aperture: the aperture of floating
Maximum gauge: 10
Surface 54:STANDARD
Aperture: the aperture of floating
Maximum gauge: 10
Surface 55:STANDARD
Surface 56:STANDARD
Surface 57:STANDARD
Aperture: circular aperture
Least radius: 0
Maximum radius: 3.06
Surface IMA:STANDARD
The coating definition:
Physical optics is propagated summary is set:
OBJ?TILTSURF
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
1?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
2?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
3?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
4?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
5?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
6?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
7?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
8?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
9?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
10?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
11?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
12?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
13?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
14?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
15?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
16?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
17?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
STO?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
19?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
20?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
21?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
22?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
23?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
24?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
25?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
26?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
27?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
28?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
29?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
30?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
31?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
32?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
33?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
34?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
35?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
36?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
37?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
38?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
39?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
40?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
41?PARAXIAL
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
42?COORDBRK
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
43?PARAXIAL
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
44?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
45?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
46?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
47?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
48?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
49?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
50?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
51?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
52?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
53?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
54?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
55?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
56?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
57?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
IMA?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
The edge thickness data:
Y limit, X limit, surface
OBJ -0.100000 -0.100000
1 0.000000 0.000000
2 0.000000 0.000000
3 -20.000000 -20.000000
4 0.000000 0.000000
5 -8.500000 -8.500000
6 3.617900 3.617900
7 -3.654235 -3.654235
8 -8.354689 -8.354689
9 0.000000 0.000000
10 -2.907821 -2.907821
11 -21.649201 -21.649201
12 0.000000 0.000000
13 0.000000 0.000000
14 15.000000 15.000000
15 4.953367 4.953367
16 2.301690 2.301690
17 12.929674 12.929674
STO 19.363056 19.363056
19 0.000000 0.000000
20 0.000000 0.000000
21 -25.000000 -25.000000
22 4.791929 4.791929
23 -6.777909 -6.777909
24 -5.547609 -5.547609
25 0.000000 0.000000
26 -5.495339 -5.495339
27 -4.398835 -4.398835
28 0.000000 0.000000
29 0.000000 0.000000
30 0.000000 0.000000
31 0.000000 0.000000
32 0.000000 0.000000
33 0.000000 0.000000
34 0.000000 0.000000
35 0.000000 0.000000
36 2.500000 2.500000
37 3.000000 3.000000
38 0.500000 0.500000
39 0.000000 0.000000
40 0.000000 0.000000
41 0.000000 0.000000
42 0.000000 0.000000
43 0.000000 0.000000
44 -0.500000 -0.500000
45 -3.000000 -3.000000
46 -2.500000 -2.500000
47 -23.000000 -23.000000
48 -3.893537 -3.893537
49 -1.991427 -1.991427
50 -6.275709 -6.275709
51 -2.011827 -2.011827
52 -4.113875 -4.113875
53 -1.932791 -1.932791
54 -10.004803 -10.004803
55 -0.536530 -0.536530
56 0.000000 0.000000
57 0.000000 0.000000
IMA 0.000000 0.000000
Many structured datas:
Structure 1:
1 Y field 1:-4.7
2 X field 2:-4.7 pick up from structure 1, and operand 1, ratio 1, skew 0
3 Y field 4:4.7 pick up from structure 1, and operand 1, ratio-1, skew 0
4 X field 5:-4.7 pick up from structure 1, and operand 1, ratio 1, skew 0
5 Y field 6:2.35 pick up from structure 1, and operand 1, ratio-0.5, skew 0
6 Y field 7:-2.35 pick up from structure 1, and operand 1, ratio 0.5, skew 0
7 apertures: 0.342
Find the solution and variable data:
Parameter 4 surfaces 5: variable
Parameter 4 surfaces 6: variable
7 thickness: variable
Half diameter 7: fixing
Half diameter 8: fixing
Parameter 4 surfaces 9: variable
10 thickness: variable
Half diameter 10: fixing
Half diameter 11: fixing
Parameter 4 surfaces 15: variable
16 thickness: variable
Half diameter 16: fixing
Half diameter 17: fixing
Parameter 4 surfaces 22: variable
23 thickness: variable
Half diameter 23: fixing
24 thickness: variable
Half diameter 24: fixing
Parameter 4 surfaces 25: variable
26 thickness: variable
Parameter 4 surfaces 28: variable
44 thickness: find the solution, from 38 values of picking up, resize ratio-1.00000 adds 0.00000
Half diameter 49: fixing
50 curvature: find the solution, from 49 values of picking up, resize ratio-1.00000
Half diameter 50: pick up from 49
Half diameter 51: fixing
Half diameter 52: fixing
Half diameter 53: fixing
Half diameter 54: fixing
The refractive index data:
The hot coefficient of growth data:
Watch crystal TCE*10E-6
0 0.00000000
1 <CRD?BRK> 0.00000000
2 <CRD?BRK> 0.00000000
3 BK7 7.10000000
4 0.00000000
5 <CRD?BRK> 0.00000000
6 <CRD?BRK> 0.00000000
7 S-TIM5 8.30000000
8 0.00000000
9 <CRD?BRK> 0.00000000
10 S-LAH66 6.20000000
11 0.00000000
12 <CRD?BRK> 0.00000000
13 MIRROR 0.00000000
14 <CRD?BRK> 0.00000000
15 <CRD?BRK> 0.00000000
16 S-PHM52 10.10000000
17 S-TIH6 8.90000000
18 0.00000000
19 <CRD?BRK> 0.00000000
20 MIRROR 0.00000000
21 <CRD?BRK> 0.00000000
22 <CRD?BRK> 0.00000000
23 S-LAH66 6.20000000
24 0.00000000
25 <CRD?BRK> 0.00000000
26 S-LAH66 6.20000000
27 0.00000000
28 <CRD?BRK> 0.00000000
29 0.00000000
30 BK7 7.10000000
31 <CRD?BRK> 7.10000000
32 <CRD?BRK> 7.10000000
33 MIRROR 0.00000000
34 <CRD?BRK> 0.00000000
35 <CRD?BRK> 0.00000000
36 0.00000000
37 FK5 9.20000000
38 0.00000000
39 0.00000000
40 <CRD?BRK> 0.00000000
41 0.00000000
42 <CRD?BRK> 0.00000000
43 0.00000000
44 MIRROR 0.00000000
45 FK5 9.20000000
46 0.00000000
47 BK7 7.10000000
48 0.00000000
49 S-PHM53 9.30000000
50 0.00000000
51 S-BSM81 5.80000000
52 0.00000000
53 S-FSL5 9.00000000
54 S-TIH6 8.90000000
55 0.00000000
56 0.00000000
57 0.00000000
58 0.00000000
The F# data:
F# calculates and has considered vignetting factor and ignored surface apertures.
Wavelength: 0.460000 0.525000 0.638000
# field Tan Sag Tan Sag Tan Sag
1 0.0000,4.7000mm:?4.8398?4.3748?4.4425?4.0018?4.2373?3.7817
2 -4.7000,0.0000mm:3.8570?6.8070?3.5637?6.0899?3.3948?5.7508
3 0.0000,0.0000mm:?3.8427?4.6147?3.5095?4.1546?3.3157?3.8884
4 0.0000,4.7000mm:?9.9516?4.6933?8.4478?4.2863?7.9387?4.0561
5 -4.7000,0.0000mm:3.8570?6.8070?3.5637?6.0899?3.3948?5.7508
6 0.0000,2.3500mm:?4.6871?4.6396?4.2321?4.1943?3.9876?3.9387
7 0.0000,-2.3500mm:3.9215?4.5231?3.5916?4.0869?3.3990?3.8313
8 4.6800,0.0000mm:?3.7304?6.3593?3.4531?5.6840?3.2929?5.3537
Whole apex coordinate, orientation and rotation/bias matrix:
With reference to surperficial: 35
Surface R11 R12 R13 X
R21 R22 R23 Y
R31 R32 R33 Z
0 0.4336132998 0.4566178415 0.7768395285 4.517843432E+001
0.5349194913 0.5633300907 -0.6296986158?4.369443138E+001
-0.7251487047?0.6885923001 0.0000136360 -6.445732627E+001
1 -0.6290897799?0.0276838538 0.7768395285 4.510075037E+001
-0.7760893783?0.0341310725 -0.6296986158?4.375740124E+001
-0.0439468507?-0.9990338704?0.0000136360 -6.445732764E+001
2 -0.6296847481?-0.0041791009?0.7768395285 4.510075037E+001
-0.7768222763?-0.0051772806?-0.6296986158?4.375740124E+001
0.0066534903 -0.9999778652?0.0000136360 -6.445732764E+001
3 -0.6296847481?-0.0041791009?0.7768395285 4.510075037E+001
-0.7768222763?-0.0051772806?-0.6296986158?4.375740124E+001
0.0066534903 -0.9999778652?0.0000136360 -6.445732764E+001
4 -0.6296847481?-0.0041791009?0.7768395285 2.956395980E+001
-0.7768222763?-0.0051772806?-0.6296986158?5.635137355E+001
0.0066534903 -0.9999778652?0.0000136360 -6.445760036E+001
5 -0.3976204718?0.0418064530 0.9165970657 3.284979056E+001
-0.9168711729?0.0203151008 -0.3986659617?6.040498788E+001
-0.0352875716?-0.9989191745?0.0302534317 -6.503598962E+001
6 -0.6837956136?-0.0439565517?0.7283483921 2.368205873E+001
-0.7295767638?0.0574488052 -0.6814817536?6.066997554E+001
-0.0118871570?-0.9973802968?-0.0713529197?-6.474651317E+001
7 -0.6837956136?-0.0439565517?0.7283483921 2.368205873E+001
-0.7295767638?0.0574488052 -0.6814817536?6.066997554E+001
-0.0118871570?-0.9973802968?-0.0713529197?-6.474651317E+001
8 -0.6837956136?-0.0439565517?0.7283483921 1.793464400E+001
-0.7295767638?0.0574488052 -0.6814817536?6.604756449E+001
-0.0118871570?-0.9973802968?-0.0713529197?-6.418346556E+001
9 -0.6565646105?-0.0447960683?0.7529383935 1.751839659E+001
-0.7541295542?0.0582342911 -0.6541386572?6.622096220E+001
-0.0145439936?-0.9972973877?-0.0720166136?-6.308106508E+001
10?-0.6565646105?-0.0447960683?0.7529383935 1.751839659E+001
-0.7541295542?0.0582342911 -0.6541386572?6.622096220E+001
-0.0145439936?-0.9972973877?-0.0720166136?-6.308106508E+001
11?-0.6565646105?-0.0447960683?0.7529383935 1.408723977E+001
-0.7541295542?0.0582342911 -0.6541386572?6.920188645E+001
-0.0145439936?-0.9972973877?-0.0720166136?-6.275288379E+001
12?-0.6565646105?0.5276897813 0.5389493547 -9.715280989E-001
-0.7541295542?-0.4454717516?-0.4825386348?8.228465959E+001
-0.0145439936?-0.7232554274?0.6904274466 -6.131255152E+001
13?-0.6565646105?0.5276897813 0.5389493547 -9.715280989E-001
-0.7541295542?-0.4454717516?-0.4825386348?8.228465959E+001
-0.0145439936?-0.7232554274?0.6904274466 -6.131255152E+001
14?-0.6565646105?0.7537162500 -0.0288916372?-9.715280989E-001
-0.7541295542?-0.6566993861?0.0058763849 8.228465959E+001
-0.0145439936?0.0256462639 0.9995652762 -6.131255152E+001
15?0.9999997042 0.0007607226 -0.0001135077?4.892056127E-001
-0.0007607547?0.9999996707 -0.0002827083?7.940776125E+001
0.0001132926 0.0002827946 0.9999999536 -4.624689337E+001
16?0.9999997042 0.0007607226 -0.0001135077?4.892056127E-001
-0.0007607547?0.9999996707 -0.0002827083?7.940776125E+001
0.0001132926 0.0002827946 0.9999999536 -4.624689337E+001
17?0.9999997042 0.0007607226 -0.0001135077?4.876678347E-001
-0.0007607547?0.9999996707 -0.0002827083?7.940393118E+001
0.0001132926 0.0002827946 0.9999999536 -3.269910661E+001
18?0.9999997042 0.0007607226 -0.0001135077?4.867597732E-001
-0.0007607547?0.9999996707 -0.0002827083?7.940166951E+001
0.0001132926 0.0002827946 0.9999999536 -2.469910698E+001
19?0.9999997042 0.0006688102 0.0003798365 4.847166348E-001
-0.0007607547?0.7873244644 0.6165384083 7.939658076E+001
0.0001132926 -0.6165385149?0.7873247404 -6.699107813E+000
20?0.9999997042 0.0006688102 0.0003798365 4.847166348E-001
-0.0007607547?0.7873244644 0.6165384083 7.939658076E+001
0.0001132926 -0.6165385149?0.7873247404 -6.699107813E+000
21?0.9999997042 0.0002921858 0.0007114846 4.847166348E-001
-0.0007607547?0.2394858009 0.9708995687 7.939658076E+001
0.0001132926 -0.9708998228?0.2394859523 -6.699107813E+000
22?0.9999678527 0.0001458509 0.0080169972 -8.707615719E-003
-0.0080158666?0.0429346250 0.9990457266 5.451519596E+001
-0.0001984951?-0.9990778732?0.0429344139 -1.021632109E+001
23?0.9999678527 0.0001458509 0.0080169972 -8.707615719E-003
-0.0080158666?0.0429346250 0.9990457266 5.451519596E+001
-0.0001984951?-0.9990778732?0.0429344139 -1.021632109E+001
24?0.9999678527 0.0001458509 0.0080169972 -5.473424960E-002
-0.0080158666?0.0429346250 0.9990457266 4.877954327E+001
-0.0001984951?-0.9990778732?0.0429344139 -1.046281320E+001
25?0.9999288973 0.0007173794 -0.0119031827?7.505312732E-002
0.0117436164 0.1140931188 0.9934006481 4.700360971E+001
0.0020707164 -0.9934698011?0.1140765819 -1.091140643E+001
26?0.9999288973 0.0007173794 -0.0119031827?7.505312732E-002
0.0117436164 0.1140931188 0.9934006481 4.700360971E+001
0.0020707164 -0.9934698011?0.1140765819 -1.091140643E+001
27?0.9999288973 0.0007173794 -0.0119031827?1.749705142E-001
0.0117436164 0.1140931188 0.9934006481 3.866483183E+001
0.0020707164 -0.9934698011?0.1140765819 -1.186898511E+001
28?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.1736481777 0.9848077530 3.726390811E+001
0.0000000000 -0.9848077530?0.1736481777 -1.283679270E+001
29?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.1736481777 0.9848077530 3.726390811E+001
0.0000000000 -0.9848077530?0.1736481777 -1.283679270E+001
30?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.1736481777 0.9848077530 3.726390811E+001
0.0000000000 -0.9848077530?0.1736481777 -1.283679270E+001
31?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.8386705679 0.5446390350 3.952654387E+001
0.0000000000 -0.5446390350?0.8386705679 -2.566883772E+001
32?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.8386705679 0.5446390350 1.976327193E+001
0.0000000000 -0.5446390350?0.8386705679 -1.283441886E+001
33?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.8386705679 0.5446390350 1.976327193E+001
0.0000000000 -0.5446390350?0.8386705679 -1.283441886E+001
34?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 0.000000000E+000
35?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 0.000000000E+000
36?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 0.000000000E+000
37?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 2.500000000E+000
38?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 5.500000000E+000
39?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
40?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 4.469000000E+003
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
41?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 4.469000000E+003
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
42?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
43?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
44?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
45?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 5.500000000E+000
46?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 2.500000000E+000
47?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 0.000000000E+000
48?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -2.300000000E+001
49?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -2.500000000E+001
50?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -3.077850000E+001
51?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -3.097850000E+001
52?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -3.717250000E+001
53?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -3.737250000E+001
54?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -4.466950000E+001
55?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -5.285050000E+001
56?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -5.376050000E+001
57?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -5.316050000E+001
58?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 1.750000000E+001
0.0000000000 0.0000000000 1.0000000000 -5.376050000E+001
The component size data:
For centring element with plane or sphere circular face, by the hypothesis side of getting, limit up to preceding radially aperture with after radially the greater in the aperture calculate volume accurately.
For every other element, the numerical integration approximate volumes reaches 0.1% precision.Volume is a null representation volume calculated exactly.
The discrete component that repeats in the lens data editing machine for the purpose of ray tracing can be listed and surpass once, estimates thereby obtain inaccurate gross mass.
Cardinal points:
Measure the object space position with respect to surface 1.
Measure the image space position with respect to image planes.
Consider the refractive index in object space and the image space.
The object space image space
W=0.460000
Focal length :-8.312566 8.312566
Focal plane: 3.847888-0.619539
Principal plane: 12.160454-8.932105
Antiprincipal plane :-4.464678 7.693027
Pitch plane: 12.160454-8.932105
Anti-pitch plane :-4.464678 7.693027
W=0.5250000 (mainly)
Focal length :-8.441475 8.441475
Focal plane: 3.965614-0.715180
Principal plane: 12.407089-9.156655
Antiprincipal plane :-4.475861 7.726295
Pitch plane: 12.407089-9.156655
Anti-pitch plane :-4.475861 7.726295
W=0.6380000
Focal length :-8.588137 8.588137
Focal plane: 4.163721-0.827454
Principal plane: 12.751857-9.415591
Antiprincipal plane :-4.424416 7.760682
Pitch plane: 12.751857-9.415591
Anti-pitch plane :-4.424416 7.760682
Table 2
ZEMAX software is exported the result, is used to describe the surface data summary and the details of each individual component in the projection optical system 99.
The conventional lenses data
Surface: 22
Diaphragm: 13
System aperture: object space NA=0.342
Heart pattern far away: open
Glass classification: MISC SCHOTT OHARA
Light aiming: close
Become mark: evenly, the factor=5.00000E-001
Effective focal length: 53.39083 (in the air, under system temperature and pressure)
Effective focal length: 53.39083 (at image spaces)
Back focal length :-622.2273
Total trace: 330.1757
Image space F/#:1.307803e-008
Paraxial work F/#:29.07414
Work F/#:29.00313
Image space NA:0.01719487
Object space NA:0.2
Diaphragm radius: 2.913214
Paraxial image height: 88.17827
Paraxial enlargement ratio :-11.86947
Entrance pupil diameter: 4.082483e+009
Entrance pupil position: 1e+010
Exit pupil diameter: 21.79671
Exit pupil position :-622.2273
The field type: object height is unit with the millimeter
Maximum field: 7.429
Prima: 0.46
Lens unit: millimeter
Angle enlargement ratio: 1.872981e+008
: 5
The field type: object height is unit with the millimeter
# X value Y value weight
1 0.000000 0.000000 1.000000
2 0.000000 2.500000 3.000000
3 0.000000 5.000000 12.000000
4 0.000000 7.000000 15.000000
5 0.000000 7.429000 1.000000
Vignetting factor
#?VDX VDY VCX VCY VAN
1?0.000000?0.000000?0.000000?0.000000?0.000000
2?0.000000?0.000000?0.000000?0.000000?0.000000
3?0.000000?0.000000?0.000000?0.000000?0.000000
4?0.000000?0.000000?0.000000?0.000000?0.000000
5?0.000000?0.000000?0.000000?0.000000?0.000000
Wavelength: 3
Unit: μ m
# value weight
1 0.460000 1.000000
2 0.525000 1.000000
3 0.635000 1.000000
Surface data summary: (wherein, Infinity represents infinite)
Surface type remarks radius thickness glass diameter taper
OBJ?STANDARD Infinity 0 14.858 0
1?STANDARD Infinity 0.5 16.3438 0
2?STANDARD Infinity 3 N-FK5 16.56834?0
3?STANDARD Infinity 2.5 17.46482?0
4?STANDARD Infinity 23 N-BK7 18.5875 0
5?STANDARD Infinity 2 25.32628?0
6?STANDARD 49.071 5.778508 S-PHM53 27 0
7?STANDARD -49.071 0.2 27 0
8?STANDARD 23.88 6.19367 S-BSM81 27 0
9?STANDARD Infinity 0.2 23.87212?0
10?STANDARD 14.732 7.297311 S-FSL5 20 0
11?STANDARD -35.2 8.181407 S-TIH6 20 0
12?STANDARD 32 0.9104899 9 0
STO?STANDARD Infinity 6.399912 6.116962?0
14?STANDARD -6.67 11.23256 S-TIH3 11 0
15?STANDARD -18 0.2 25.6 0
16?STANDARD -96.016 4.960048 S-TIH6 30 0
17?STANDARD -52.68 49.35403 34 0
18?STANDARD 182.45 11.9887 S-BSM81 92 0
19?STANDARD Infinity 161.2791 92 0
20?STANDARD Infinity 0 183.3892?0
21?EVENASPH 295.1198 25 POLYCARB?190.8502?0
IMA?STANDARD Infinity 174.5479?0
The surface data details:
Surface OBJ:STANDARD
Surface 1:STANDARD
Surface 2:STANDARD
Surface 3:STANDARD
Surface 4:STANDARD
Surface 5:STANDARD
Surface 6:STANDARD
Aperture: the aperture of floating
Maximum radius: 13.5
Surface 7:STANDARD
Aperture: the aperture of floating
Maximum radius: 13.5
Surface 8:STANDARD
Aperture: the aperture of floating
Maximum radius: 13.5
Surface 9:STANDARD
Surface 10:STANDARD
Aperture: the aperture of floating
Maximum radius: 10
Surface 11:STANDARD
Aperture: the aperture of floating
Maximum radius: 10
Surface 12:STANDARD
Aperture: the aperture of floating
Maximum radius: 4.5
Surface STO:STANDARD
Surface 14:STANDARD
Aperture: the aperture of floating
Maximum radius: 5.5
Surface 15:STANDARD
Aperture: the aperture of floating
Maximum radius: 12.8
Surface 16:STANDARD
Aperture: the aperture of floating
Maximum radius: 15
Surface 17:STANDARD
Aperture: the aperture of floating
Maximum radius: 17
Surface 18:STANDARD
Aperture: the aperture of floating
Maximum radius: 46
Surface 19:STANDARD
Aperture: the aperture of floating
Maximum radius: 46
Surface 20:STANDARD
Surface 21:EVENASPH
Coefficient 2:0 about r
Coefficient 4:0 about r
Coefficient 6:0 about r
Coefficient 8:0 about r
Coefficient 10:0 about r
Coefficient 12:0 about r
Coefficient 14:0 about r
Coefficient 16:0 about r
Surface IMA:STANDARD
The coating definition:
Physical optics is propagated summary is set:
OBJ?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
1?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
2?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
3?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
4?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
5?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
6?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
7?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
8?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
9?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
10?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
11?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
12?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
STO?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
14?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
15?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
16?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
17?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
18?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
19?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
20?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
21?EVENASPH
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
IMA?STANDARD
Use light ray propagation to next surface: Off
Recomputate guide beam: Off
Unfavorable with light data readjustment beam size: Off
Adopt angular spectrum propagation operator: Off
Adopt parallel probing light: Off
With reference to radius: the most suitable
The edge thickness data:
Surface Edge
OBJ 0.000000
1 0.500000
2 3.000000
3 2.500000
4 23.000000
5 3.893537
6 1.991435
7 6.275709
8 2.011497
9 4.113875
10 1.933102
11 9.949726
12 0.592504
STO 3.503359
14 8.784551
15 4.365649
16 3.320598
17 58.066448
18 6.094651
19 161279099
20 15.853350
21 9.146650
IMA 0.000000
Many structured datas:
Structure 1:
1 thickness 20:0
Structure 2:
1 thickness 20:-5
Structure 3:
1 thickness 20:5
Find the solution and variable data
6 thickness: variable
Half radius 6: fixing
7 curvature: find the solution, pick up resize ratio-1.00000 from 6
Half radius 7: pick up from 6
8 thickness: variable
Half radius 8: pick up from 6
10 thickness: variable
Half radius 10: fixing
11 thickness: variable
Half radius 11: pick up from 10
12 thickness: variable
Half radius 12: fixing
13 thickness: variable
14 thickness: variable
Half radius 14: fixing
Half radius 15: fixing
16 thickness: variable
Half radius 16: fixing
17 thickness: variable
Half radius 17: fixing
18 thickness: variable
Half radius 18: fixing
19 thickness: variable
Half radius 19: fixing
21 curvature: variable
The refractive index data:
Watch crystal temperature, pressure 0.460000 0.525000 0.635000
0 20.00 1.00 1.00000000 1.00000000 1.00000000
1 20.00 1.00 1.00000000 1.00000000 1.00000000
2 N-FK5 20.00 1.00 1.49402111 1.49012584 1.48594605
3 20.00 1.00 1.00000000 1.00000000 1.00000000
4 N-BK7 20.00 1.00 1.52443350 1.51986781 1.51501420
5 20.00 1.00 1.00000000 1.00000000 1.00000000
6 S-PHM53 25.00 1.00 1.61177822 1.60651481 1.60097110
7 20.00 1.00 1.00000000 1.00000000 1.00000000
8 S-BSM81 25.00 1.00 1.65011121 1.64405670 1.63764082
9 20.00 1.00 1.00000000 1.00000000 1.00000000
10 S-FSL5 25.00 1.00 1.49404408 1.49013274 1.48594450
11 S-TIH6 25.00 1.00 1.83685381 1.81725141 1.79857441
12 20.00 1.00 1.00000000 1.00000000 1.00000000
13 20.00 1.00 1.00000000 1.00000000 1.00000000
14 S-TIH3 25.00 1.00 1.76602131 1.74996726 1.73451038
15 20.00 1.00 1.00000000 1.00000000 1.00000000
16 S-TIH6 25.00 1.00 1.83685381 1.81725141 1.79857441
17 20.00 1.00 1.00000000 1.00000000 1.00000000
18 S-BSM81 25.00 1.00 1.65011121 1.64405670 1.63764082
19 20.00 1.00 1.00000000 1.00000000 1.00000000
20 20.00 1.00 1.00000000 1.00000000 1.00000000
21 POLYCARB?20.00 1.00 1.60505860 1.59293157 1.58138766
22 20.00 1.00 1.00000000 1.00000000 1.00000000
The hot coefficient of growth data:
Watch crystal TCE*10E-6
0 0.00000000
1 0.00000000
2 N-FK5 9.20000000
3 0.00000000
4 N-BK7 7.10000000
5 0.00000000
6 S-PHM53 9.30000000
7 0.00000000
8 S-BSM81 5.80000000
9 0.00000000
10 S-FSL5 9.00000000
11 S-TIH6 8.90000000
12 0.00000000
13 0.00000000
14 S-TIH3 8.50000000
15 0.00000000
16 S-TIH6 8.90000000
17 0.00000000
18 S-BSM81 5.80000000
19 0.00000000
20 0.00000000
21 POLYCARB 67.00000000
22 0.00000000
The F# data:
F# calculates and has considered vignetting factor and ignored surface apertures.
Wavelength: 0.460000 0.525000 0.635000
# field Tan Sag Tan Sag Tan Sag
1 0.0000mm:?29.0031?29.0031?28.8420?28.8420?28.9161?28.9161
2 2.5000mm:?29.2056?29.0837?29.0481?28.9190?29.0876?28.9776
3 5.0000mm:?29.5933?29.3230?29.5306?29.1621?29.5295?29.1850
4 7.0000mm:?29.0724?29.5275?29.2642?29.4061?29.3265?29.4099
5 7.4290mm:?28.6953?29.5394?28.9573?29.4353?29.0457?29.4397
Whole apex coordinate, orientation and rotation/bias matrix:
With reference to surperficial: 0
Surface R11 R12 R13 X
R21 R22 R23 Y
R31 R32 R33 Z
0 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 0.000000000E+000
1 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 0.000000000E+000
2 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 5.000000000E-001
3 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.500000000E+000
4 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 6.000000000E+000
5 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 2.900000000E+001
6 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.100000000E+001
7 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.677850848E+001
8 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.697850848E+001
9 1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 4.317217864E+001
10?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 4.337217864E+001
11?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 5.066948953E+001
12?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 5.885089610E+001
13?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 5.976138604E+001
14?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 6.616129816E+001
15?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 7.739386198E+001
16?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 7.759386198E+001
17?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 8.255391027E+001
18?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 1.319079376E+002
19?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 1.438966413E+002
20?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.051757408E+002
21?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.051757408E+002
22?1.0000000000 0.0000000000 0.0000000000 0.000000000E+000
0.0000000000 1.0000000000 0.0000000000 0.000000000E+000
0.0000000000 0.0000000000 1.0000000000 3.301757408E+002
The component size data:
For centring element with plane or sphere circular face, by the hypothesis side of getting, limit up to preceding radially aperture with after radially the greater in the aperture calculate volume accurately.
For every other element, the numerical integration approximate volumes reaches 0.1% precision.Volume is a null representation volume calculated exactly.
The discrete component that repeats in the lens data editing machine for the purpose of ray tracing can be listed and surpass once, estimates thereby obtain inaccurate gross mass.
Volume cc density g/cc quality g
Element surface 4 to 5 11.586722 2.510000 29.082673
Element surface 6 to 7 2.231471 3.510000 7.832462
Element surface 10 to 11 1.482899 2.460000 3.647932
Element surface 21 to 22 449.470461 1.250000 561.838077
Gross mass 836.669550
Cardinal points:
Measure the object space position with respect to surface 1.
Measure the image space position with respect to image planes.
Consider the refractive index in object space and the image space.
The object space image space
W=0.460000 (mainly)
Focal length :-53.390829 53.390829
Focal plane: 4.498166-622.227272
Principal plane: 57.888995-675.618101
Antiprincipal plane :-48.892663-568.836444
Pitch plane: 57.888995-675.618101
Anti-pitch plane :-48.892663-568.836444
W=0.525000
Focal length :-51.915834 51.915834
Focal plane: 4.391026-604.898243
Principal plane: 56.306860-656.814077
Antiprincipal plane :-47.524807-552.982409
Pitch plane: 56.306860-656.814077
Anti-pitch plane :-47.524807-552.982409
W=0.635000
Focal length :-50.637947 50.637947
Focal plane: 4.268027-589.053890
Principal plane: 54.905974-639.691837
Antiprincipal plane :-46.369920-538.415942
Pitch plane: 54.905974-639.691837
Anti-pitch plane :-46.369920-538.415942
Aforesaid lamp optical system 98 suitably is imaged on digital imagery device 75 places with the output surface of optical collector element 16.
Replace comprising that the element that lens, illumination optical system are unified in the projection optical system alternatively comprises refracting element, reflecting element (for example, catoptron), diffraction element or their combination separately.These surface configurations can be integrally or partly by Fresnel rank or face setting.Can on the light path of optical system, provide other mirror elements to be used to realize other folding ideally, thereby reduce the overall dimensions of the housing that comprises DLP system 100.
Above-mentioned DLP system 100 has following characteristic: resolution height (for example, XGA or higher); Power requirement is low, less than 30 watts; (less than 30 pounds) in light weight; Form factor is little; Can adopt such as DVI, VGA, USB, RS232, synthetic (composite) and the input of HDMI.
DLP of the present invention system 100 can be used as self-supporting or hand-held projector (promptly, do not have screen), the screen that perhaps alternatively can be combined in disclosed type in U.S. Patent No. 6301417 of authorizing people such as Biscardi or the U.S. Patent No. 6487350 of the authorizing people such as Veligdan uses together.Known these screens (or optical display panel) are even also have excellent luminance and contrast under background environment.
Within the spirit and scope of the present invention, can consider above specifically described conception modification and modification.
It will be appreciated by one of skill in the art that under the situation that does not break away from the spirit and scope of the present invention and can carry out various modifications and variations the foregoing description.For example, can adopt the LED of other color rather than the ruddiness of in above embodiment, mentioning, green glow or blue-ray LED for led array 150.Therefore, should be appreciated that the present invention is not limited to above disclosed specific embodiment, and be intended to cover modification and the modification that limits by following claim.
Claims (25)
1. optical system that is used for digital light projection systems, this optical system comprises:
At least one led array, wherein each led array comprises a plurality of LED; And
The optical collector element, it is positioned near each led array substantially, the light of a plurality of LEDs emissions of each optical collector element total internal reflection in the led array of correspondence wherein, provide basically light uniformly with output surface place, and wherein said optical collector element has complicated taper along the longitudinal direction from the input surface of this optical collector element to the output surface of this optical collector element at each optical collector element.
2. optical system according to claim 1, wherein, described optical collector element is set to directly contact with each led array.
3. optical system according to claim 1, this optical system also comprise the optical coupled material between described optical collector element and each led array, and wherein, described optical coupled material contacts with described optical collector element and each led array.
4. optical system according to claim 3, wherein, described optical coupled material comprises the gel that refractive index is complementary with the refractive index of described optical collector element basically.
5. optical system according to claim 1, wherein, each led array comprises the LED of width less than 0.35mm.
6. optical system according to claim 1, wherein, each led array comprises such LED, its with the adjacent LED in an array at interval less than the amount of 0.025mm.
7. optical system according to claim 1, wherein, described optical collector element has parabolic cross-sections substantially.
8. optical system according to claim 1, wherein, this optical system is a lamp optical system.
9. optical system according to claim 1, this optical system also comprises the digital imagery device.
10. optical system according to claim 9, wherein, the output surface direct imaging of each optical collector element is on described digital imagery device.
11. an optical system that is used for digital light projection systems, this optical system comprises:
A plurality of led array, wherein each led array comprises a plurality of LED;
The optical collector element, it is positioned near each led array substantially, the light of a plurality of LEDs emissions of each optical collector element total internal reflection in the led array of correspondence wherein, provide basically light uniformly with output surface place, and wherein said optical collector element has complicated taper along the longitudinal direction from the input surface of this optical collector element to the output surface of this optical collector element at each optical collector element; And
The optical combiner element, wherein, the output surface of each optical collector element is positioned near the respective side of combiner element substantially, and wherein, the light uniformly basically that is combined in described combiner element space that the output surface place of each optical collector element provides forms white light basically with the output surface place in this combiner element.
12. optical system according to claim 11, wherein, described optical collector element is set to directly contact with each led array.
13. optical system according to claim 11, this optical system also comprise the optical coupled material between described optical collector element and each led array, wherein, described optical coupled material contacts with described optical collector element and each led array.
14. optical system according to claim 13, wherein, described optical coupled material comprises the gel that refractive index is complementary with the refractive index of described optical collector element basically.
15. optical system according to claim 11, wherein, each led array comprises the LED of width less than 0.35mm.
16. optical system according to claim 11, wherein, each led array comprises such LED, its with the adjacent LED in an array at interval less than the amount of 0.025mm.
17. optical system according to claim 11, wherein, described optical collector element has parabolic cross-sections substantially.
18. optical system according to claim 11, wherein, a plurality of led array are made of 3 led array, and wherein these 3 led array are made of 3 monochromatic LED arrays, and wherein each in these 3 monochromatic LED arrays has the color that is different from each other.
19. optical system according to claim 18, wherein, described 3 monochromatic LED arrays are by the led array that only comprises red-light LED, only comprise the led array of green light LED and only comprise that the led array of blue-ray LED constitutes.
20. optical system according to claim 11, wherein, a plurality of led array are made of 3 led array, and wherein said combiner element is the combiner cube.
21. optical system according to claim 11, wherein, a plurality of led array are made of 3 led array, and wherein said combiner element is a dichroic combiner cube.
22. optical system according to claim 11, wherein, a plurality of led array are made of 3 led array, and wherein said combiner element is a dichroic combiner cube, and wherein said combiner cube comprises 4 prisms.
23. optical system according to claim 11, wherein, described optical system is a lamp optical system.
24. optical system according to claim 11, this optical system also comprises the digital imagery device.
25. optical system according to claim 24, wherein, the output surface direct imaging of each optical collector element is on described digital imagery device.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US12/583,548 | 2009-08-20 | ||
| US12/583,548 US7973996B2 (en) | 2005-12-09 | 2009-08-20 | Optical system for a digital light projection system including a 3-channel LED array light engine |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN101995665A true CN101995665A (en) | 2011-03-30 |
Family
ID=43786028
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN2010102606677A Pending CN101995665A (en) | 2009-08-20 | 2010-08-20 | Optical system for a digital light projection system including 3-channel and 4-channel LED array light engines |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN101995665A (en) |
-
2010
- 2010-08-20 CN CN2010102606677A patent/CN101995665A/en active Pending
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Application publication date: 20110330 |