In the present study, a horizontal Rijke tube is used to investigate the thermoacoustic instability. Twodimensional,
unsteady Reynolds-averaged numerical simulations are performed on the Rijke tube. To
trigger the instability, an oscillating pressure signal with a small time scale is applied at the inlet of
the Rijke tube. The effects of amplitude (1-30 Pa), frequency (100-250 Hz), and impulse time (10-20
ms) of the triggering pressure on the thermoacoustic instability are investigated. The heater is used
as a heating source to investigate the impact of heater temperature on thermoacoustic instability. The
results demonstrate that the temperature variation (800-5000 K) leads to concurrent variation in both
amplitude (0-6500 Pa) and frequency (177-186 Hz) of oscillation. At heater temperature of 2000 K,
beating-type instability is observed, with the main and beating cycle frequency of 183.64 Hz and 0.33
Hz, respectively. In a Rijke tube viable to thermoacoustic instability, the amplitude and frequency of
limit cycle pressure waves do not depend on the triggering pressure. An increase in the amplitude of
triggering pressure amplifies the amplitude of nonlinear oscillations and decreases the time taken to
attain limit cycle oscillation. The present study successfully identifies the tipping surface separating
the stable and unstable region of triggering parameters in a Rijke tube.