The Chandrayan take 5 earth orbit modifications to reach a translunar trajectory. I thought less orbit modifications should be enough:
The description on wikipedia looks like modifying the orbit eccentricity several times until it reaches the correct Hohmann transfer orbit. Why not only going into the last elliptic orbit earlier?
It didn't have enough thrust. Small rocket engines are easier to build than large ones, and weigh a lot less. That probe (I assume you mean Chandrayaan 1) had a 440 N main thruster that it used to get to Lunar orbit. It weighed initially about 1350 kg all from wiki. That amounts to an acceleration of approximately 0.3 m/s/s. You need around 4000 m/s for a trans lunar injection using basic Hohmann transfer, although there are far more efficient trajectories called low-energy transfers.
An extra 4000 m/s with that little thruster would require several hours of thrusting time, even with the rocket equation helping you as you lose mass. Hohmann transfers assume that you basically make an instantaneous impulse change at one of your apsides, which is impossible if you are thrusting for that long near Earth. So, multiple burns are required to take full advantage of the efficiencies gained by such a transfer orbit.
The multi-revolution transfer orbits can be called as 'Phasing elliptical orbits'. In the mission planning, it gives us some advantage such as reducing the finite burn arc losses which may depending on the particular cases to about 80 m/s that can translate directly to savings in mass. Such transfers also give us good time to characterize the propulsion system and operational flexibility.
Such orbits are achieved mainly utilizing the positive effects of the natural forces that disturb the orbits around the Earth such as gravitational forces of the Sun and the Moon, Earth's atmospheric drag, Earth's non-spherical gravity field, etc. (http://adsabs.harvard.edu/abs/2002cosp...34E1372S).
