Abstract:
As the field of gravitational wave astronomy strides rapidly towards its rst
direct detection, developing e cient data analysis strategies become crucial
due to the low signal to noise ratio in the data. The noise level is compara-ble to the signal strength and this poses a serious threat of false detection.
The rst part of my thesis addresses the issues of false-alarm caused by an
important family of glitches that can be modeled as sine-Gaussian in the
data analysis technique used for detecting signals from coalescing compact
binaries. We develop three approximate analytical expressions that allows
us to predict the nature of spurious triggers generated by these glitches. The
second part of my thesis concerns with the map-making in stochastic grav-itational wave background. Here again, the weakness of the signal and the
nature of the detector beam makes the problem non-trivial. We incorporate
a prior knowledge on the source distribution through regularization functions
and investigate the improvement in quality of reconstructed map. This work
will have implications in placing an upper limit on the source parameter in
the absence of detection.
Description:
The work has two part. Part one has been done in collaboration with Prof. S Dhurandhar, Dr. Andrew Lundgen and Tito Dal Canton. The part is an ongoing research project done in collaboration with Prof. Sanjit Mitra and Dr. Jayanti Prasad.