1 Free-space optical links for stratospheric platform networks German Aerospace Centre (DLR)

Document Title Free-space optical links for stratospheric platforms

Document Number CAP-0195-WP34-DLR-CON-P00

Author (s) Joachim Horwath

Date 19/07/2004

Participant (s) (short names) DLR

Workpackage(s) 3.4

Total number of slides (including title and this slide)

15

Security level (PUB, RES, CON)

CON

Description / Abstract

At first the advantages and applications of optical links for CAPANINA are introduced. Possible link distances and their geometric restrictions are explained. A short introduction about atmospheric effects is given.

1

Free-space optical links for stratospheric platform networks

German Aerospace Centre

(DLR)

2 Free-space optical links for stratospheric platform networks

Document Properties

Document Title Free-space optical links for stratospheric platforms

Document Number CAP-0195-WP34-DLR-CON-P00

Author (s) Joachim Horwath

Date 19/07/2004

Participant (s) (short names) DLR

Workpackage(s) 3.4

Total number of slides (including title and this slide)

15

Security level (PUB, RES, CON)

CON

Description / Abstract

At first the advantages and applications of optical links for CAPANINA are introduced. Possible link distances and their geometric restrictions are explained. A short introduction about atmospheric effects is given.

3 Free-space optical links for stratospheric platform networks

Outline

Content

Advantages

Applications of optical links for CAPANINA

Link distances

Atmospheric effects

Attenuation

Index of refraction

4 Free-space optical links for stratospheric platform networks

Advantages of optical links

High data-rate and available bandwidth

Small terminals and antenna dimensions

Low power consumption

No interference with radio waves

5 Free-space optical links for stratospheric platform networks

Application of optical links for HAPs

Downlink:

•diversity with microwave to save platform power

•optical downlink-spatial-diversity (cloud-cover diversity)

Main application: inter-platform links

6 Free-space optical links for stratospheric platform networks

graze

height

Inter-platform links: link distance

Geometric restriction Optical links blocked by cloudsMaximum link distance for 100% availability determined by maximum cloud ceiling

7 Free-space optical links for stratospheric platform networks

Inter platform links: link distance

Geometric restriction :Example of parabolically-shaped height profile due to the curvature of the Earth

8 Free-space optical links for stratospheric platform networks

Inter-platform links: link distance

Cloud ceilingMaximum cirrus altitude for temperate latitudes:

After: Goldfarb, L. et al, “A climatological study of cirrus clouds by lidar”

9 Free-space optical links for stratospheric platform networks

Inter-platform links: link distance

Maximum inter-platform link distance Two HAPs, same altitude

maximum link distance: 400 km

10 Free-space optical links for stratospheric platform networks

Atmospheric Effects: Attenuation

Atmospheric effects have to be taken into account for all optical CAPANINA links

11 Free-space optical links for stratospheric platform networks

Atmospheric Effects: Attenuation

HAP height: 22 kmA

tten

uati

on

[d

B]

Wavelength [nm]

30 Elevation45 Elevation

90 Elevation

Atmospheric attenuation for the downlink

Maximum cirrus altitude for temperate latitudes

12 Free-space optical links for stratospheric platform networks

Atmospheric Effects: Turbulence

Index-of-refraction effectsTurbulent air- fluctuations

Small-scale temperature and refractive-index inhomogenities (turbulence cells)

Acts like small lenses

• Wave front distortions• Beam broadening• Angle-of-arrival fluctuations• Intensity redistribution

13 Free-space optical links for stratospheric platform networks

Atmospheric Effects: Turbulence

DAperture > correlation length (intensity)

Decrease of power variance at the receiver

Aperture-Averaging (IM/DD):

( , )el opt

Aperture

I P Intensity x y dxdy

DAperture

Simulated intensity distribution at the receiver

14 Free-space optical links for stratospheric platform networks

Atmospheric Effects: Turbulence

Spatial Covariance Function (986 nm)

Correlation length [m]:

4.5×10-2 (BC) 3.2×10-2 (WC)

Speckle size

15 Free-space optical links for stratospheric platform networks

Summary

Conclusion

Main application:

HAP->HAP links, HAP->SAT links

Downlink with decreased availability

Link distances: 400 to ~780km are possible

Atmospheric effects have to be taken into account

Have been Simulated

Will be measured during the downlink experiment