# Chandrayaan-2; time taken to get to the Moon

Depicted above is the print version of the July 02, 2019 Times of India article Why the world keeps returning to Chandamama which nicely surveys the large number of missions to the Moon.

India is going to launch the spacecraft Chandrayaan-2 to the moon on 16 July which will consist of a lander, an orbiter and a rover. I found an article in today's newspaper regarding this. If you zoom in a bit, you will be able to see the list of other lunar missions that have taken place over the years. A common difference that I found in lunar missions of 20th century and lunar missions of 21st century was the time. Earlier, the spacecrafts reached moon in a day or two but recent missions take over 2 months.

With developed technology, it should take even less time, but it's the other way round. Can anyone explain the reason behind this?

Link of the article

• Welcome to Space! This question is possibly a duplicate of space.stackexchange.com/q/32629/26446 or space.stackexchange.com/q/10731/26446 . The bottom line is that there are trajectories that use much less energy (fuel), but take much longer time. – DrSheldon Jul 3 '19 at 6:50
• I didn't see that. The question is different but I seem to have got my answer. Thanks. – Aditya Jain Jul 3 '19 at 6:55
• @AdityaJain It's not a bad thing if a question is closed as duplicate; the idea is to direct readers to good answers, so your new question will help to do that. The wording is a little confusing, we call it a duplicate question but the criteria is really that the answers to that question should also answer your question. Please feel free to ask more questions. I've added the isro tag to your question, you may enjoy reading over sixty other isro-tagged questions here and their answers. Welcome to space! – uhoh Jul 4 '19 at 3:47
• @DrSheldon those are bad choices for duplicates, I don't think you did much research on Chandrayaan-2 before proposing them. Can I ask you to consider adding to the re-open votes so we can do this right? Thanks! – uhoh Jul 4 '19 at 4:03
• Voted to reopen – user10509 Jul 12 '19 at 9:27

Chandrayaan-2 will launch on a GSLV Mark-III from Satish Dhawan Space Centre. It consists of three parts, with a total mass at launch of about 2,400 kg:

• Orbiter
• Vikram Lander
• Pragyan Rover

After launch, from here:

...the cryogenic upper stage, powered by CE-20, India's largest cryogenic engine, will ignite, driving the module to a highly elliptical Earth Parking Orbit.

At this stage, the onboard propulsion system will raise the module’s orbit around the Earth through a number of burn. How does this work, you may ask?

[...] The closer the module is to the Earth, the more the gravitational pull, and the greater the speed. Every time the module reaches the perigee, or the point of highest speed, the onboard engine fires, increasing its speed even more, pushing it into a higher, more elongated orbit as a result. With every burn of the onboard propulsion system, the module will keep spiralling outwards in increasingly elongated ellipses.

It's not really a spiral, the perigee remains fairly constant.

Burning only at perigee where velocity is maximum is taking advantage of the Oberth effect, something you can read about in the several excellent answers to Oberth effect for Earth vehicles, or here.

I don't know the details of the burns yet. This article India set to launch second moon mission Chandrayaan-2 in July, landing by September says:

Orbital path

Just like Chandrayaan-1 and Mars Orbiter Mission, the Chandrayaan-2 will also perform orbit raising manoeuvres around the Earth six times to gain the required height and speed to break away from the Earth’s gravity.

This six-step process is a staple procedure followed by the ISRO with the objective of reducing cost of fuel and launching with a home-grown rocket that is as of now incapable of flying directly to the moon, like Saturn V rocket did for the Apollo missions.

However, here is a table of Chandrayaan-1's burns from here:

Date (UTC)    Burn time (min)    Resulting apogee (km)
22 October        Launch            22,860
23 October          18              37,900
25 October          16              74,715
26 October          9.5            164,600
29 October          3              267,000
4 November         2.5            380,000


There will likely be a check of the trajectory after each burn, and there are several adjustments that need to be made before the Lunar Transfer Trajectory (LTT) can be reached.

Satish Dhawan Space Centre is close to 14 N latitude, which means it can potentially launch into a 24° inclination orbit to match the Moon's inclination with respect to Earth's equator. However, the delicate LTT maneuver will have a small window in time and position so that the spacecraft can be in just the right place, at just the right time to be captured into lunar orbit without using a huge amount of valuable propellant.

Hitting this "keyhole" in both space and time will be difficult, and so Chandrayaan-2 will take its time, step by step in order to be captured into lunar orbit with a minimum amount of propellant usage.

All eyes will be on ISRO and Chandrayaan-2 for several reasons.

1. ISRO is hot! They have had an excellent run in deep-space missions to the Moon and to Mars, and this moon orbiter, lander, and rover are a new thing for this space agency.
2. This is the 50th anniversary of the Apollo-11 Moon landing, and so there is a lot of extra moon hype going around.