CN1737613A - Narrow-band filter array with multi-cavity structure - Google Patents
Narrow-band filter array with multi-cavity structure Download PDFInfo
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- CN1737613A CN1737613A CNA2005100293893A CN200510029389A CN1737613A CN 1737613 A CN1737613 A CN 1737613A CN A2005100293893 A CNA2005100293893 A CN A2005100293893A CN 200510029389 A CN200510029389 A CN 200510029389A CN 1737613 A CN1737613 A CN 1737613A
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Abstract
The invention discloses a kind of narrow-band filter array with multi-cavity structure, it is that to utilize a plurality of F-P structural membrane be to form multi-cavity, form the resonant cavity layer array by combination plated film or combination lithographic method, with the logical peak position of band that reaches each miniature narrow band pass filter of control, thereby realize the logical peak position narrow band pass filter integrated purpose on same substrate of different band.This structure is applicable to each wave band multi-cavity narrow-band filter array.The advantage of this structure is that the logical rectangle degree of the band of optical filter is good, and it is integrated to be easy to many passbands, and signal, the while that can obtain more in each spectral band-width curb the outer noise of passband better, improve signal to noise ratio (S/N ratio) greatly, can satisfy through engineering approaches and practicability needs.
Description
Technical field
The present invention relates to optical filter, specifically be meant a kind of narrow-band filter array with multi-cavity structure.
Background technology
Light splitting technology is one of core technology in the multispectral detection technique, be widely used in environmental monitoring, biomedicine, science and technology agricultural, industrial flow monitoring, and in ground or the Aeronautics and Astronautics field to the military and civilian fields such as detection of target such as guided missile, meteor, cloud, rain, landforms and background thereof.Traditional beam split mode mainly contains grating, prism, optical filter runner, and method such as Fourier transform.Though these methods can be composed scanning mostly entirely, the resolution height, its shortcoming is all to relate to mechanical driving device, has not only limited the speed that information is read, and also greatly reduces the resistance to shock and the reliability of instrument; And the structure of grating and lens type system is too huge, and for on-the-spot and open-air, especially the spacer remote sensing use is unfavorable especially.Along with the miniaturization and the lightweight demand of spectrometric instrument, and environmental protection, field, the on-the-spot detection and the specific (special) requirements of multispectral spacer remote sensing aspect reliability and vibration resistance, need to adopt light splitting technology with the nothing machinery gearing of detector compatibility.Therefore, people are seeking effective solution route always.Light-filtering sheet array is a kind of miniature spatial light filter that begins one's study the 1980s and grow up, owing to can combine the common discernible detector of spectrum that constitutes with detector array, simplify beam splitting system greatly, improve reliability, stability and the optical efficiency of instrument, therefore the beam splitting system of microminaturization spectral instrument of new generation all is tending towards adopting this new structure, see J.R.Toweret al.RCA Review 47,266 (1986); J.A.Hall et al.SPIE 345,145 (1982).And the realization of light-filtering sheet array also will provide strong technical support to the raising and the miniaturization of respective sensor part integrated level.
Though the application prospect of light-filtering sheet array is considerable, never make great progress for many years, greatly restricted the development and the application of light-filtering sheet array.Trace it to its cause, the development of restriction light-filtering sheet array mainly contains two critical technological points, the i.e. microminiaturization of optical filter and integrated.The inventor has proposed some preparation efficiencies and the very high integrated optical filter array of yield rate, as patent of invention 200310108346.5,200410067892.3.But the prepared integrated optical filter array of these methods all is single cavity configuration, though possessed the basic function of integrated optical filter array, can reach the purpose of beam split, but the logical rectangle degree (or waveform) of its band is still good inadequately, the utilization factor of signal is just not high enough in the logical scope of this belt transect, also is difficult to really reach through engineering approaches and practicability requirement.
Summary of the invention
Based on the deficiency that above-mentioned single chamber light-filtering sheet array exists, the objective of the invention is to propose the integrated multi-cavity optical filter array that a kind of rectangle degree obviously improves, to satisfy the demand of through engineering approaches and practicability.
Integrated multi-cavity optical filter array of the present invention is with the design of F-P film structure, and said multi-cavity can be: two-chamber, three chambeies or four chambeies, and they generate following film by vacuum coating method respectively on substrate separately be that the concrete structure of film system is as follows:
Two-chamber is: H (LH)
A-1WL (HL)
aH (LH)
a XL (HL)
A-1H,
Three chambeies are: H (LH)
A-1WL (HL)
a H (LH)
aXL (HL)
aH (LH)
aYL (HL)
A-1H,
Four chambeies are: H (LH)
A-1WL (HL)
aH (LH)
aXL (HL) aH (LH)
aYL (HL)
aH (LH)
aZL (HL)
A-1H, wherein wL, xL, yL, zL are resonant cavity layer, w=x=y=z.H is a high refractive index layer, and L is a low-index film, and a and a-1 are high refractive index layer and low-index film alternative stacked number of times, a 〉=2, and the optical thickness of rete (nd) is λ
0/ 4, λ
0Centre wavelength when being for designing initial narrow band pass filter film.
Said resonant cavity layer wL, xL, yL, zL are the different array of thickness, its one-tenth-value thickness 1/10 changes with the value of w, x, y and z, the span of general w, x, y and z is 1<w=x=y=z<3 or 3<w=x=y=z<5, and the resonant cavity layer thickness of corresponding units is identical.
The different resonant cavity layer array of said thickness is to utilize the mask plate stack plated film or the combination etching that have the zones of different window to form.
The present invention utilizes characteristics design that the logical peak position of the band of F-P structure optical filter changes with the variation of its resonant cavity layer thickness, the logical rectangle degree of band utilizes multi-cavity structure to be improved, realize the preparation of each resonant cavity layer array by combination plated film or combination etching, with the logical peak position of band that reaches each miniature narrow band pass filter of control, thereby realize the logical peak position narrow band pass filter integrated purpose on same substrate of different band.This structure is applicable to the preparation of each wave band multi-cavity narrow-band filter array.
The advantage of multi-cavity narrow-band filter array of the present invention is:
1, adopt multi-cavity F-P structure Design, make that the logical rectangle degree of band of optical filter is good, signal, the while that can obtain more in the passband curb the outer noise of passband better, improve signal to noise ratio (S/N ratio) greatly, can satisfy through engineering approaches and practicability needs.
2, can realize the integrated of multi-cavity F-P structure optical filter by combination plated film or combination lithographic method, and can prepare the multi-cavity optical filter array that matches according to the shape and size design of detector array, but common formation spectrum recognition detector, simplify the structure of multispectral sensing device greatly, help the miniaturization of instrument and integrated, this structure is applicable to each spectral band.
Description of drawings
Fig. 1 (a) is the transmission spectrum of single channel narrow band pass filter, and wherein solid line is the transmission spectrum of double cavity structure optical filter, and rectangle degree 1.7, film are H (LH)
52L (HL)
6H (LH)
62L (HL)
5H; Dotted line is the transmission spectrum of single cavity configuration optical filter, and rectangle degree 3.0, film are H (LH)
52L (HL)
5H.
Fig. 1 (b) is the transmission spectrum of 8 passage two-chamber narrow-band filter arrays, and film is H (LH)
5XL (HL)
6H (LH)
6YL (HL)
5H, the value 1.7~2.4 of x=y, interval 0.1.
Fig. 2 is the preparation process synoptic diagram of two-chamber narrow-band filter array.
Fig. 3 is the structural representation of multi-cavity narrow-band filter array.
Embodiment
Below in conjunction with accompanying drawing the specific embodiment of the present invention is elaborated:
Two-chamber narrow-band filter array with integrated 8 passages is an example, and film structure is H (LH)
A-1XL (HL)
aH (LH)
aYL (HL)
A-1H, design wavelength lambda 0 is 777.4nm, and L is a silica coating, and H is the tantalum pentoxide rete, a=6, the value 1.7~2.4 of x=y is got an interval 0.1, and concrete preparation process is as follows:
At first on substrate 1, alternately be coated with silica coating and tantalum pentoxide rete H (LH)
5, constituting lower membrane is 2, shown in Fig. 2 (a).
Utilize the mask plate stack plated film that has the zones of different window then, film is xL, and x value 1.7~2.4 is got an interval 0.1, forms the different following resonant cavity layer array 3 of thickness.The unit number of resonator cavity rete is 2 along with the increase of stack coating times n is exponential increase
n, the unit number of resonator cavity rete is 8 (promptly 2 in the present embodiment
3), only need carry out the stack plated film 3 times.In like manner, 8 stack plated films just can obtain 256 (2
8) individual unit, efficient is very high, and stacking method is asked for an interview Chinese patent in detail: 200310108346.5.If the thickness of each plated film is a preceding coating film thickness half, then the thickness through resulting resonant cavity layer array behind the stack plated film is linear change, the logical peak position of the band of corresponding narrow-band filter array also is spacedly distributed, shown in Fig. 2 (b).
The plating mesopelagic layer is 4 on following resonant cavity layer array 3 again, and its film is (HL)
6H (LH)
6, shown in Fig. 2 (c).
And then utilize the mask plate stack plated film have the zones of different window, and film is yL, y value 1.7~2.4 is got an interval 0.1, forms the last resonator cavity rete array 5 identical and corresponding with following resonator cavity rete array 3, shown in Fig. 2 (d).
At last, plating tunic on the resonator cavity rete array 5 on preparing is 6, and its film is (HL)
5H promptly finishes the preparation of two-chamber narrow-band filter array, shown in Fig. 2 (e).
The resonant cavity layer array of above-mentioned different-thickness also can utilize the mask plate alignment that has the zones of different window to form, and different is the resonant cavity layer of the same thickness of elder generation's growth, forms the different resonator cavity rete array of thickness through alignment again.
Multi-cavity structure of the present invention can obviously improve the logical rectangle degree of band of narrow band pass filter, see Fig. 1 (a), be defined as the peak width at the peak width/50% transmitance place at 10% transmitance place, it is 1 good more to approach more, from the figure as can be seen, the rectangle degree (1.7) that single channel double cavity structure optical filter band is logical obviously is better than corresponding single cavity configuration (3.0), signal, the while that can obtain more like this in the passband curb the outer noise of passband better, improve signal to noise ratio (S/N ratio) greatly, if adopt three chambeies or four cavity configurations, the rectangle degree can be further improved.
Fig. 1 (b) is the transmission spectrum of 8 different resonant cavity layer thickness narrow band pass filters, and the logical peak position of the band of narrow band pass filter changes along with the change of resonant cavity layer thickness as can be seen, is directly proportional substantially.Therefore, the thickness of resonant cavity layer was with the logical peak position of band of final control optical filter about we can control by twice stack plated film (or stack etching) method.
Claims (2)
1. narrow-band filter array with multi-cavity structure is characterized in that:
Said multi-cavity can be: two-chamber, three chambeies or four chambeies, and they generate following film by vacuum coating method respectively on substrate separately be that the concrete structure of film system is as follows:
Two-chamber is: H (LH)
A-1WL (HL)
aH (LH)
a XL (HL)
A-1H,
Three chambeies are: H (LH)
A-1WL (HL)
a H (LH)
aXL (HL)
aH (LH)
aYL (HL)
A-1H,
Four chambeies are: H (LH)
A-1WL (HL)
aH (LH)
aXL (HL)
aH (LH)
aYL (HL)
aH (LH)
aZL (HL)
A-1H,
Wherein wL, xL, yL, zL are resonant cavity layer, and w=x=y=z, H are high refractive index layer, and L is a low-index film, and a and a-1 are high refractive index layer and low-index film alternative stacked number of times, a 〉=2, and the optical thickness of rete (nd) is λ
0/ 4, λ
0Centre wavelength when being for designing initial narrow band pass filter film;
Said resonant cavity layer wL, xL, yL, zL are the different array of thickness, its one-tenth-value thickness 1/10 changes with the value of w, x, y and z, the span of general w, x, y and z is 1<w=x=y=z<3 or 3<w=x=y=z<5, and the resonant cavity layer thickness of corresponding units is identical.
2. according to a kind of narrow-band filter array with multi-cavity structure of claim 1, it is characterized in that: the different resonant cavity layer array of said thickness is to utilize the mask plate stack plated film or the combination etching that have the zones of different window to form.
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Cited By (11)
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WO2006114050A1 (en) * | 2005-04-27 | 2006-11-02 | Shanghai Institute Of Technical Physics, Chinese Academy Of Sciences | Narrow bandpass filter matrix and the manufacturing method thereof |
CN101303424B (en) * | 2008-06-12 | 2011-02-16 | 中国科学院上海技术物理研究所 | Three-cavity multichannel optical spectrum step type integrated optical filter |
CN105954833A (en) * | 2016-06-24 | 2016-09-21 | 上海晶鼎光电科技有限公司 | Light splitting chip and preparation method thereof |
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US5719989A (en) * | 1995-06-28 | 1998-02-17 | Jds Fitel Inc. | Multilayer thin film bandpass filter |
US6031653A (en) * | 1997-08-28 | 2000-02-29 | California Institute Of Technology | Low-cost thin-metal-film interference filters |
US6850366B2 (en) * | 2002-10-09 | 2005-02-01 | Jds Uniphase Corporation | Multi-cavity optical filter |
CN1226639C (en) * | 2003-10-31 | 2005-11-09 | 中国科学院上海技术物理研究所 | Filter type spectrum component |
CN100385264C (en) * | 2004-11-05 | 2008-04-30 | 中国科学院上海技术物理研究所 | Integrated narrow-band filter |
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WO2006114050A1 (en) * | 2005-04-27 | 2006-11-02 | Shanghai Institute Of Technical Physics, Chinese Academy Of Sciences | Narrow bandpass filter matrix and the manufacturing method thereof |
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CN107667287A (en) * | 2015-06-03 | 2018-02-06 | 美题隆公司 | Automatic defect detection and mapping for optical filter |
CN105954833A (en) * | 2016-06-24 | 2016-09-21 | 上海晶鼎光电科技有限公司 | Light splitting chip and preparation method thereof |
CN107703637B (en) * | 2017-09-29 | 2019-11-15 | 中国科学院长春光学精密机械与物理研究所 | A kind of superelevation spectral coverage integrated level open score device suitable for fine multi-spectral imager |
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CN107703637A (en) * | 2017-09-29 | 2018-02-16 | 中国科学院长春光学精密机械与物理研究所 | A kind of superelevation spectral coverage integrated level open score device suitable for fine multi-spectral imager |
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US11408769B2 (en) | 2018-10-04 | 2022-08-09 | Imec Vzw | Spectral sensor for multispectral imaging |
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