Bistatic Radar 2008
DOI: 10.1002/9780470985755.ch1
|View full text |Cite
|
Sign up to set email alerts
|

Fundamentals of Bistatic Synthetic Aperture Radar

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
4
1

Citation Types

0
6
0

Year Published

2008
2008
2019
2019

Publication Types

Select...
4
1

Relationship

1
4

Authors

Journals

citations
Cited by 5 publications
(6 citation statements)
references
References 49 publications
0
6
0
Order By: Relevance
“…Due to the limited transmitted bandwidth, the bistatic geometry and the consequent non-orthogonality between range and Doppler resolution directions [33], each ‫ܫ‬ is characterized by a coarse spatial resolution (generally resolution cell area in the order of 80-150 m 2 ), whose worst value coincides with the direction of the resolution ellipse. As an example, we consider a simulated scenario given by a ground-based receiver collecting the signals reflected by a point scatterer in the scene center illuminated by the P-codes transmitted by two GLONASS satellites (5.11 MHz bandwidth).…”
Section: Gnss-based Sarmentioning
confidence: 99%
“…Due to the limited transmitted bandwidth, the bistatic geometry and the consequent non-orthogonality between range and Doppler resolution directions [33], each ‫ܫ‬ is characterized by a coarse spatial resolution (generally resolution cell area in the order of 80-150 m 2 ), whose worst value coincides with the direction of the resolution ellipse. As an example, we consider a simulated scenario given by a ground-based receiver collecting the signals reflected by a point scatterer in the scene center illuminated by the P-codes transmitted by two GLONASS satellites (5.11 MHz bandwidth).…”
Section: Gnss-based Sarmentioning
confidence: 99%
“…It is worth noting that the bistatic angle plays the same role in monostatic-bistatic radargrammetry as the stereo-intersection angle in monostatic repeat-pass one. A general analysis of bistatic SAR resolution is reported in [26, 27], based on the gradient method and on the derivation of bistatic ambiguity function; literature results will be used in the next sections, whereas simplified expressions, based on [23], will be introduced here in order to assess basic rules for mission design. Assuming two space platforms operating at the same altitude in parallel trajectories, the bistatic ground range, Δ r g ″ , and azimuth, Δ x ′ resolution can be related to the monostatic ones (Δ r g ′ and Δ x′ , respectively) [23, 25]: Δrg=2Δrgsinηsinη+sinη Δx=2rr+rΔxwhere η′ and η″ are monostatic and bistatic incidence angles; r′ and r″ are monostatic and bistatic slant ranges.…”
Section: Monostatic-bistatic Geometry For Stereo-radargrammetric Recomentioning
confidence: 99%
“…The projection of bistatic parameters, such as baseline trueB, slant range truer, sensor position trueR, onto the range-elevation plane of the monostatic antenna allows three-dimensional monostatic-bistatic geometry to be accounted [32], and generates an explicit formulation for height determination [23]. The projection can be carried out considering the unit vector normal to the first antenna range elevation plane (Figure 5): n=R×(trueV×R)|R×(trueV×R)|and, by means of this vector, calculating the projected parameters as follows: B=B2(Bn)2 r=r2(truer2n)2 R=|trueR|2(Rn)2where trueR is the monostatic sensor position, V is the monostatic antenna velocity with respect to the Earth-centred-Earth-fixed (ECEF) reference frame.…”
Section: Monostatic-bistatic Geometry For Stereo-radargrammetric Recomentioning
confidence: 99%
See 2 more Smart Citations