Novice question. A few days ago I watched a TV documentary about Virgin Orbit’s failed mission earlier this year to send satellites into orbit from Spaceport Cornwall. One of the satellites shown appeared to about the size of a shoebox. It was secured inside a compartment pressing down against a spring. At the correct altitude, the door of the compartment was supposed to flip open and the spring would eject the satellite into orbit. This seems a bit of a haphazard means of placing a satellite into orbit. Would the satellite have engines of some sort allowing it to be precisely manoeuvred? Do all artificial satellites have engines?
Most satellites do have a thruster system of some sort on board. Indeed, the lifespan of a satellite is often determined by how much fuel it can carry, because once it runs dry, it'll start to slip out of its orbit due to a number of physical processes (for example, drag from the few atmospheric particles that get up that high, sunlight pressure, and the earth's slightly asymmetric gravity field). Most of the time, when the fuel is running out, we spend the last bit to kick the satellite into a "graveyard" orbit (an area set aside for nonfunctional satellites where they'll stay well away from the active orbits and are unlikely to collide with anything), or drop the satellite's lowest orbital point far enough that atmospheric drag will eventually bring it down (which may take weeks or months).
There are a lot of thruster technologies, and only some of them resemble a rocket. Hypergolic propellants have historically been popular for thrusters; in that case it's a tiny rocket where the fuel is two materials that spontaneously ignite when they're combined in the combustion chamber, which means you don't need an igniter system. The earliest satellites used cold gas thrusters (cold meaning there's no combustion — basically using an aerosol spraycan to get around) and those still get used from time to time. The new hotness is ion thrusters, which don't really look like a rocket at all. They are incredibly weak and power-hungry, but extremely fuel-efficient, so if you're willing to spend days or weeks inching your way into the proper orbit, that's an attractive option. (A notable user of ion drives is SpaceX's Starlink constellation.)
What you're looking at, though, is a cubesat, which is usually sent up as a ride-share with some larger payload that doesn't completely consume the rocket's lift capacity (for example, if you're lofting an 8000 lb satellite and the rocket can comfortably lift 8400 lbs to that orbit, you can pretty easily add in a cubesat frame and sell those slots to other people). Cubesats are typically tiny — each "unit" is a cube 10 cm on a side that would fit comfortably in your hand. Most cubesats are one unit, though some of them are two, three, or four units stuck together — but still no bigger than a shoebox. In any case, cubesats often don't have any drive system other than the spring that pops them out of the rocket, and they're intended to reach only an approximate orbit and last only a short time. "Haphazard" is a fully appropriate word. They're mostly meant for university students to get some experience with satellite development or get an instrument into orbit on the cheap, so nobody's going to be overly upset if they're off their intended orbit by a few kilometers.
Some cubesats have been pulling off some really neat tricks with orbital maneuvering, though. At that tiny size, it's possible to angle solar cells to use as a light-sail or reposition in orbit by effectively pushing off the earth's magnetic field.
Short answer: no.
most small satellites (like the cubesat you saw) don't have engines. Rocket engines are complex, and therefore expensive, and these small satellites are usually used in an effort to do a low-cost mission.
many large satellites do use engines. These are called thrusters: small rocket engines that are used to change a satellite's attitude. Some satellites can also change their course, this requires larger engines. This is used to e.g. move the satellite into its final position after launch, and to move it to a graveyard orbit at the end of its life.
Rockets are not the only method for changing a satellite's attitude. You can also use reaction wheels, magnetorquers, or radiation pressure (vanes that stick out of the spacecraft and catch sunlight, using the tiny pressure exerted by the sunlight to rotate the satellite).
The advantage of these over thrusters is that they don't consume propellant, so they can be lighter in the long run. Space telescopes also benefit from not having exhaust gases around the satellite (Hubble, for instance: they didn't want exhaust gases to condense on the telescope optics).
A nice example of satellites that have no effectors whatsoever are the two Laser Geodynamics Satellites (LAGEOS 1 and 2). Neither has an onboard computer. Neither has any effectors. Neither has any attitude control mechanisms.
< Source: NASA, via wikipedia. This image is public domain.
The LAGEOS satellites are very simple vehicles that orbit well above the atmosphere. They are solid spheres made of a dense material but are covered with retroreflectors. The retroreflectors enable ground-based observers to ping those satellites with lasers, hence the name. The LAGEOS satellites are used to investigate the Earth's rotation and to investigate aspects of general relativity.
In space, simple rules!
This seems a bit of a haphazard means of placing a satellite into orbit.
Agreed, it does seem that way, but when done in a planned and thoughtful way it gets the job done, and in spaceflight where all kinds of things can go wrong and cause big problems.
Propulsion systems are a major headache1 - especially for cubesats and smallsats. If they are ride-sharing on other launch missions or the ISS, then they are the type that can get their job done without being in any ultraspecific orbit.
1They are substantial sources of potential mission failure, they are heavy and take up space which limits what else you can put on the spacecraft, and they are considered "stored energy devices" (reactive chemicals and/or pressurized bottles) and that really complicates the process of getting it cleared to be launched along with other cubesats when hitchhiking on other missions.
They rely on their detumbling systems (attitude measurement and control using solar-electric powered magnetotorquers) to right themselves (without using a propulsion system or expending mass) so that their cameras and other instruments can point in specified directions.
The "haphazard" releases are actually well-planned. For example when released from the ISS they are gently pushed at a controlled speed and specific direction so that they will not ever return and bump in to the ISS.
This applies to both satellites and trash destined for reentry and burnup.
- Are the cubesats deployed from the ISS always directed "nadir and retrograde"?
- Was this large pieces of "space junk" just released from the ISS in the "nadir and retrograde" direction?
- How close will the cubesats be when numerous of them are launched simultaneously?
- When jettisoning heavy objects from the ISS e.g. 2.9 tons of batteries+, how much angular impulse does the station get? Corrective actions necessary?
- This ISS trash deployment looks more like 2 feet than 2 inches per second, was it too fast or are these articles incorrect?
- In "spacecraft talk" is nadir just a fancy word for "down"?
If you look at a deployment from this angle and speed it up, it no longer seems so haphazard:
Would the satellite have engines of some sort allowing it to be precisely manoeuvred? Do all artificial satellites have engines?
Yes, many do and many don't, as pointed out in other answers. But what's really cool is that many use a third option to maneuver. It's somewhat analogous to how a glider (the kind you sit in, or say a hawk when it's not flapping its wings) maneuvers around and goes where it wants without propulsion.
The example I like the best is the constellation of eight CYGNSS satellites that were deployed together and then spread out into a great circle constellation spaced every 45 degrees. These cubesats did not have propulsion, but they did have good attitude control and big flat solar panels that could interact with the drag from the small amount of atmosphere up in LEO.
The technique is called differential drag and is discussed at length in
- this answer to Rocket to launch 8 cubesat to LEO at an equidistant distance where I also quote material from Planet Labs who exploit differential drag to help spread their cubesats out around great circles without boost and deboost propulsive maneuvers.
From Differential Drag Control Scheme for Large Constellation of Planet Satellites and On-Orbit Results and my linked answer:
Here is an example of a simulation of the use of alternating between high and low drag configurations to achieve equal spaced phasing and then to maintain it using small station-keeping drag adjustments:
Figure 8: Time-discretized high-drag commands are assigned to achieve desired slots (b) with commands
Figure 9: Attitude modes of Dove satellite enable large drag area ratios (a) Orthographic projections with cross-sectional areas. (b) High-drag and low-drag attitudes