pact of the use of satellite data was seriously limited by the full polarmetry will considerably increase the utility of 
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
ss, and nearly continuous cloud coverage. radar imagery for geological and hydrological studies 
, if it all. * New tools should be analysed: (cf. Tab. 5 and 6). However, the user must be aware 
ns, the Viewing and target parameters confine the possibili- that the efficiency of imaging radars is best in flat ter- 
than the ties of SAR imagery. Radar systems with variable sy- rain and decreases in hilly and mountainous terrain, 
92). stem parameters such as multiple frequencies, respectively. 
re inve- electable look directions and depression angles, and 
R flown 
^ would Table 5 The potential of SAR for the application to major geological and hydrological phenomena concerning disaster 
management 
Disaster 
Mangement Hazard/ Early Disaster Planning/ 
: Vulnerability Warning Effects/ Mitigation 
llite re- Geolog. & Hydrogeol. Analysis Relief 
Fraane- Phenomena 
ins, and Rocktall T T T e 
ncluded : 
fields Landslide / sid ++ ++ ++ 
ypes of Creep/flow + + n.a. + 
jnisable Mudflow zt T Ft + 
d lands- Soil moisture + er n.a. o 
are too Ground water aquifer © © o ++) 
Flood +++ ++" +++ +++ 
lata that Snow smelt ++ T n.a. ++ 
Snow avalanche ++ + +++ ++ 
' no sudden events Key: 
2 only detectable if debris shows up sufficiently n.a. not applicable 
? fractures/faults can be mapped as idicators e fair 
1 provided, repetition rate is suffcient + good 
time-series required ++ better 
Abb exellent 
Table 6 Potential of major SAR features for the ascertainment of physical ground properties with regard to their rele- 
vance for mass movements. Incidence angle mainly based on NASA 1987. 
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
Geolog. & Hydro- MULTI- MULTI- Inc. 
geol. Phenomena FREQUENCY POLARISATION POLARIMETRY INTERFEROMETR | ang. 
X HH,HV,VV,VH Y, 0 
Disaster HA | EW | DR | PL | HA | EW | DR | PL | HA | EW | DR | PL | HA |EW|DR| PL 
Management 
Creep/flow' + Ina | + | + | 2 ala + + + | ++ | + | ++ | ++ | 10-25 
Mudflow ++ | na. | ++ | ++ | + + + | ++ ++ | ++ | ++ ++ | ++ | 10-20 
+ | + 
MS/ Landslide ++ | na. | ++ | ++ | + + | + | ++ ++ | ++ | ++ ++ |++ | 10-20 
| + + | + 
Rockfall + | na | + | + | + + | + | ++ ++ | ++ [++ | @ |++ [++ | 35-55 
+ + | + 
Flood +++ | +++ | 4E | EE | HP | HE | ++ +++ | ++ | + + + + | 30-40 
+ + | + | + 
Aquifer n.a.|na.|n.a| + | D Q |na| + D na. | + + G | @ | + | 20-30 
Soil moisture TE T ++ + ++ e ++ | ++ | ++ [02 +++ | ++ e Qe A | 20-30 
ed ade- + 
1e most Snow smelt ++ + na) ++ rina | wh n.a. © | © | @ | 10-20 
should Snow avalanche Tt T ++ | ++ | ++ + + + |++ e +++ | ++ | ++ Q | ++ | ++ | 25-40 
for cer- + DAT nah M E 
) to ha- 
ution. ' no sudden events 0 = Recommendable optimum INCIDENCE ANGLE 
1e most 
jer, it is Key: 
rom the n.a. not applicable 
s where HA hazard analysis D fair 
EW early warning + good 
DR disaster relief ++ better 
PL plannin/mitigation +++ exellent 
43 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B6. Vienna 1996