Desmodromic valve train

The invention claimed is: 1. A desmodromic valve train for an engine including a valve actuator arranged to actuate a valve independently of a crank angle of the engine, the desmodromic valve train comprising: a load path arrangement comprising an input arranged to receive actuating force from the valve actuator; an output arranged to provide the actuating force to the valve; and mechanical advantage means arranged such that a first displacement of the input, causes a second displacement of the output wherein the second displacement is a multiple of the first displacement, the multiple being within a range from 1.3 to 1.95, wherein the mechanical advantage means comprises a rocker mounted on a shaft which is a fulcrum for the rocker enabling the rocker to rotate about the shaft in response to a pushing force from the valve actuator and in response to a pulling force from the valve actuator, wherein the rocker comprises a first rocker arm and a second rocker arm, the first rocker arm extending from the shaft to a first follower, the first follower acting as a roller follower for following a camming surface and receiving the pushing force, the second rocker arm extending from the shaft to a second follower, the second follower acting as a roller follower for following a camming surface and receiving the pulling force, wherein the first rocker arm and the second rocker arm are both operably coupled to the output. 2. A desmodromic valve train as claimed in claim 1 , wherein the valve actuator is an electromagnetic valve actuator. 3. A desmodromic valve train as claimed in claim 1 , wherein the valve actuator is arranged to rotate a camshaft comprising one or more camshaft lobes for camming the input of the load path arrangement to cause the first displacement of the input. 4. A desmodromic valve train as claimed in claim 1 , wherein the second displacement of the output is for pushing the valve away from a valve seat or for pulling the valve towards the valve seat. 5. A desmodromic valve train as claimed in claim 1 , wherein the rocker is arranged to enable, at least in part, the second displacement of the output to be the multiple within the range from 1.3 to 1.95 of the first displacement, of the input. 6. A desmodromic valve train as claimed in claim 1 , wherein the mechanical advantage means comprises a plurality of rockers. 7. A desmodromic valve train as claimed in claim 6 , wherein a first one of the rockers is coupled to an output of the valve actuator; and a second one of the rockers is coupled to the first rocker via a connecting rod. 8. A desmodromic valve train as claimed in claim 7 , wherein the second rocker comprises a bearing for connection to the connecting rod. 9. A desmodromic valve train as claimed in claim 1 , wherein the valve actuator is configured to provide a rotational output. 10. A desmodromic valve train as claimed in claim 1 , comprising a valve and wherein: a first curved surface at an upper portion of an end of the valve is arranged to contact a pushing contact surface of the rocker enabling pushing of the upper portion of the end of the valve along a first axis and enabling relative slippage between the pushing contact surface and the upper portion of the end of the valve; and a second curved surface at a lower portion of the end of the valve is arranged to contact a pulling contact surface of the rocker enabling pulling of the lower portion of the end of the valve along the first axis and enabling relative slippage between the pulling contact surface and the lower portion of the end of the valve. 11. A desmodromic valve train as claimed in claim 10 , wherein at least one of the first curved surface and the second curved surface is domed. 12. A desmodromic valve train as claimed in claim 10 , wherein the second curved surface is part of a retainer portion arranged to be retained in position with respect to a valve stem of the valve via at least friction upon application of the pulling of the lower portion of the end of the valve. 13. A desmodromic valve train as claimed in claim 12 , wherein an interface between the retainer portion and the valve stem includes a taper, a direction of the taper being arranged such that the taper further resists sliding of the retainer portion upwardly toward the upper portion of the end of the valve upon application of the pulling of the lower portion of the end of the valve. 14. A desmodromic valve train as claimed in claim 1 , wherein the rocker is arranged to provide a coupling between a valve and the valve actuator and arranged to rotate in response to a pushing force from the valve actuator and in response to a pulling force from the valve actuator; the rocker comprises an input portion for coupling to the valve actuator arranged to receive the pushing force from the valve actuator and to receive the pulling force from the valve actuator; and an output portion, spaced from the input portion, for coupling to the valve, wherein the output portion comprises a pushing contact surface and a pulling contact surface; the pushing contact surface is arranged to contact a first curved surface at an upper portion of an end of the valve enabling pushing of the upper portion of the end of the valve along a first axis and enabling relative slippage between the pushing contact surface and the upper portion of the end of the valve; and the pulling contact surface is arranged to contact a second curved surface at a lower portion of the end of the valve enabling pulling of the lower portion of the end of the valve along the first axis and enabling relative slippage between the pulling contact surface and the lower portion of the end of the valve. 15. An engine comprising the desmodromic valve train of claim 1 . 16. A desmodromic valve train for an engine, comprising: a first surface arranged to be actuated by a valve actuator arranged to actuate a valve independently of a crank angle of the engine causing the first surface to move according to a first lift profile having a first maximum-to-minimum displacement; a second surface arranged to directly actuate the valve in dependence on actuation of the first surface by the valve actuator causing the second surface to move according to a second lift profile having a second maximum-to-minimum displacement; and a load path arrangement for providing a load path from the first surface to the second surface, wherein the load path arrangement comprises mechanical advantage means arranged such that the second maximum-to-minimum displacement is at least 1.3 and up to 1.95 times greater than the first maximum-to-minimum displacement, wherein the mechanical advantage means comprises a rocker mounted on a shaft which is a fulcrum for the rocker enabling the rocker to rotate about the shaft in response to a pushing force from the valve actuator and in response to a pulling force from the valve actuator, wherein the rocker comprises a first rocker arm and a second rocker arm, the first rocker arm extending from the shaft to a first follower, the first follower acting as a roller follower for following a camming surface and receiving the pushing force, the second rocker arm extending from the shaft to a second follower, the second follower acting as a roller follower for following a camming surface and receiving the pulling force, wherein the first rocker arm and the second rocker arm are both operably coupled to the output. 17. A desmodromic valve train as claimed in claim 16 , wherein the mechanical advantage means is arranged such that the second maximum-to-minimum displacement is no les