The present invention relates to the field of machines adapted for locomotion across a surface. More specifically, the present invention relates to a legged walking machine that is steerable so enabling it to change direction of locomotion across the surface. Legged walking machines are known in the art. In particular, there exist numerous examples of six legged walking machines, commonly referred to as "hexapods", known in the art. These machines can generally be split into two distinct categories. The first category relates to those machines that exhibit a relatively simple design i.e. those that employ a single motor to operate all of the legs. As such these walking machines are only capable of travelling in straight lines which significantly limits their manoeuvrability and, when in the form of a toy, their playability. Some examples of such six legged walking machines are described in US Patent No. 6,652,352 B, Romanian Patent No. 1 14,247 B and Chinese Patent Publication No. 201291928 Y. The second category relates to those machines that exhibit a significantly more complex design i.e. those that employ at least one motor or servo to control the operation of each leg and each of these components is linked to a microprocessor. These walking machines are capable of steerable locomotion across a surface however the use of multiple motors makes them prohibitively expensive to produce and they generally require not insignificant levels of computing power to provide the required directional control. Examples of such steerable walking machine are described within US Patent No. 5,005,658, US Patent Publication Nos. 5,351 ,626 A and 5,351 ,773 A. It is recognised in the present invention that considerable advantage is to be gained in the provision of a walking machine that provides a motor efficient means of locomotion and steering across a surface. It is therefore an object of an aspect of the present invention to obviate or at least mitigate the foregoing disadvantages of the walking machines known in the art. Summary of Invention According to a first aspect of the present invention there is provided a steerable walking machine the steerable walking machine comprising a leg mechanism that provides a means for locomotion of the machine across a surface and a head rotatably mounted upon the leg mechanism wherein the rotational position of the head upon the leg mechanism defines a direction of locomotion of the machine across the surface. The steerable walking machine described above provides a device that can walk in any direction without having to turn the leg mechanism. This is achieved since it is the head's rotational position on the leg mechanism which defines the direction of travel. Thus as the legs mechanism remains stationary direction of locomotion can be rotated through 360°. As a result the steerable walking device can manoeuvre in more confined spaces than those devices known in the art. The leg mechanism may comprise two or more flexible legs the operation of which is controlled by a first leg operating mechanism. Preferably the flexible legs controlled by the first leg operating mechanism are equally spaced around the leg mechanism. The leg mechanism may comprise two or more flexible legs the operation of which is controlled by a second leg operating mechanism. Preferably the flexible legs controlled by the second leg operating mechanism are equally spaced around the leg mechanism. The flexible legs controlled by the first and second leg operating mechanism are preferably alternatively located around the leg mechanism. Preferably the first leg operating mechanism acts to rotate a surface engaging end of the flexible legs. It is also preferable for the second leg operating mechanism to rotate a surface engaging end of the flexible legs. The rotation of the surface engaging ends of the flexible legs provided by the first and second leg operating mechanisms are preferably of the same sense. Most preferably the rotation of the surface engaging ends of the flexible legs provided by the first and second leg operating mechanisms are preferably half of one cycle out of step with each other. With this arrangement the flexible legs provide a stable means for locomotion of the device across a surface since there some of surface engaging ends of the flexible legs are always in contact with the ground. Most preferably the first and second leg operating mechanisms are driven by a first motor. The rotational position of the head upon the leg mechanism is preferably controlled by a second motor. The functionality of the steerable walking machine is therefore achieved through the employment of only two motors, one employed for locomotion and the other employed for steering. The use of only two motors and associated electronics significantly reduces the manufacturing costs involved. In a preferred embodiment the leg mechanism comprises three flexible legs the operation of which is controlled by the first leg operating mechanism. In a preferred embodiment the leg mechanism comprises three flexible legs the operation of which is controlled by the second leg operating mechanism. Preferably the head comprise a support frame having a perimeter section and a rotatable disc located therein. The support frame may further comprise two or more fixed legs depending from the perimeter section which provide an attachment means for the flexible legs. Preferably the flexible legs are pivotally attached to the two or more fixed legs. The support frame may further comprise two or more attachment points located on the perimeter. The attachment points provide a second attachment means for the flexible legs the operation of which is controlled by the second leg operating mechanism. Most preferably a locomotion control mechanism is mounted on top of the rotatable disc. The locomotion control mechanism preferably comprises a lever drive mechanism arranged to pass through an aperture in the rotatable disc. Preferably the lever drive mechanism is pivotally mounted to a support structure located upon the rotatable disc. Alternatively, the lever drive mechanism comprises a Y-shaped lever the proximal ends of which are attached to independent gear wheels. A multi armed joint mechanism is preferably attached to a distal end of the lever drive mechanism. The multi armed joint mechanism preferably comprises an arm suitable for attachment to each flexible leg. Optionally the arms suitable for attachment to the flexible legs controlled by the second leg operating mechanism are longer than the arms suitable for attachment to the flexible legs controlled by the first leg operating mechanism. Most preferably the first and second leg operating mechanisms are configured to translate movement of the multi-armed joint to each of surface engaging ends of the flexible legs. Most preferably the lever drive mechanism is arranged to rotate relative to the multi armed joint mechanism upon rotation of the rotatable disc. Rotation of the rotatable disc therefore defines the direction of locomotion of the walking machine. Most preferably the two or more flexible legs comprise an exoskeleton arranged to house the internal working of the flexible legs. The presence of the exoskeleton prevents an operator from being able to insert a finger into the moving components of the legs. The steerable walking machine may comprise one or more additional accessories selected from the group of accessories comprising a weapon e,g, a suction dart gun, armour modules, a crane and a magnetic pickup. The steerable walking machine may also accommodate a one or more light sensors. The armour modules may comprise a bias means which provides a means for ejecting the armour module from the steerable walking machine. The above features increases the overall payability of the steerable walking mechanism. According to a second aspect of the present invention there is provided a method of controlling the operation of a steerable walking machine the method comprising the steps of:

· employing a leg mechanism to provide locomotion to the walking machine; and · selecting a rotational position of a head mounted upon the leg mechanism so as to define the direction of locomotion of the walking machine. The step of employing a leg mechanism to provide locomotion preferably employs a first motor to drive four or more flexible legs. Preferably the rotational position of the head mounted upon the leg mechanism is controlled by a second motor. Embodiments of the second aspect of the invention may comprise features to implement the preferred or optional features of the first aspect of the invention or vice versa. Brief Description of Drawings Aspects and advantages of the present invention will become apparent upon reading the following detailed description and upon reference to the following drawings in which: Figure 1 presents a schematic representation of a steerable walking machine in accordance with an embodiment of the present invention; Figure 2 presents a partially exploded view of a head of the steerable walking machine of Figure 1 ; Figure 3 presents a top view, with a head cover removed, of the steerable walking machine of Figure 1 . Figure 4 presents a schematic representation of a first leg operating mechanism for the steerable walking machine of Figure 1 ; Figure 5 presents a schematic representation of a second leg operating mechanism for the steerable walking machine of Figure 1 ; Figure 6 presents a schematic representation of the cross over between three of the legs of the steerable walking machine of Figure 1 ; Figure 7 presents a schematic representation of an alternative embodiment of the steerable walking machine of Figure 1 ; Figure 8 presents a schematic cross sectional view of a first and a second leg operating mechanism for the steerable walking machine of Figure 7

(a) in the presence of a support frame;

(b) in the absence of a support frame; Figure 9 presents a schematic representation of a six armed joint mechanism of the steerable walking machine of Figure 7; and Figure 10 presents a schematic representation of an alternative embodiment of the steerable walking machine of Figure 7. Detailed Description A schematic representation of a steerable walking machine 1 in accordance with an embodiment of the present invention is presented in Figure 1 . The steerable walking machine 1 can be seen to comprise a head 2 that is mounted in a rotatable manner upon a leg mechanism 3. The steerable walking machine 1 presented in Figure 1 may be considered to be a "hexapod" since the leg mechanism 3 comprises six flexible legs, three flexible legs having a first operating mechanism 4 and three flexible legs having a second operating mechanism 5. Each set of flexible legs are located substantially 120° apart on the leg mechanism 3 such that there is a flexible leg of alternative type every 60° around the leg mechanism 3. It will be apparent to the skilled man on reading the following description that the steerable walking machine 1 is not limited to comprising six flexible legs 4. Embodiments comprising as few as four flexible legs may be produced while the upper limit of flexible legs is limited only by the physical dimensions of the steerable walking machine 1. In all of the described embodiments the leg mechanism 3 provides for locomotion of the steerable walking device 1 across a surface. It is the relative rotational position between the head 2 and the leg mechanism 3 which defines the direction of locomotion across the surface, as indicated by the arrow 6 within Figure 1. Further details of the steerable walking device 1 will now be described with reference to Figure 2 which presents a partially exploded view of the head 2, and Figure 3 which presents a top view of the steerable walking device 1 with a head cover removed. The head 2 can be seen to comprise a support frame 7 having a circular perimeter 8 depending from which are three fixed legs 9 and mounted centrally therein is a rotatable disc 10. Each fixed leg 9 comprises a foot 1 1 pivotally mounted to which are first 12 and second 13 leg attachment joints. The pivotally mounted first 12 and second 13 leg attachment joints are configured to allow for rotational movement of an associated flexible leg 4 and 5, respectively, about substantially perpendicular axes. In the embodiment shown in Figure 2 first substantially vertical axes are defined by first pivot pins 14 that located within apertures within the associated foot 1 1 while second substantially horizontal axes are defined by second pivot pins 15 housed within the leg attachment joints 12 and 13 themselves. Three similarly designed third leg attachment joints 16 are also located on the underside of the circular perimeter 8. These attachment joints provide a means for attaching the flexible legs 5 to the support frame 7, as described in further detail below. Located on top of the rotatable disc 10 is a locomotion control mechanism 17. The locomotion control mechanism 17 comprises a support structure 18 that extends from the rotatable disc 10 and a lever drive mechanism 19 which is arranged to pass through a central aperture in the rotatable disc 10. The lever drive mechanism 19 is pivotally mounted at its proximal end to a first end of a pivot arm 20 while a second end of the pivot arm 20 is pivotally mounted to a distal end of the support structure 18. At a distal end of the lever drive mechanism 19 is located a Y-shaped mount 21 that is pivotally attached to a six armed joint mechanism 22. It can be seen that the six armed joint mechanism 22 comprises a central rod 23 threaded onto which is a first 24 and second 25 three armed connector. Each arm of the first three armed connector 24 provides a means of attachment for a flexible leg 4 to the lever drive mechanism 19 while each arm of the second three armed connector 25 provides a means of attachment for a flexible leg 5 to the lever drive mechanism 19. The central rod 23 is arranged so that the first 24 and second 25 three armed connectors mimic any horizontal or vertical movement of the rod 23. However, the rod 23 is configured so as to be able to freely rotate upon its own axis within the first 24 and second 25 three armed connectors. Operation of the locomotion control mechanism 17 is achieved through the employment of a first electric motor 26 that is mounted on the rotatable disc 10 and which is mechanically connected to the lever drive mechanism 19 via a first gearing mechanism 27. The first gearing mechanism 27 comprises a first gear wheel 28 located on the rotatable disc 10 and which is configured to drive a second gear wheel 29 mounted on the lever drive mechanism 19. As a result, when the first electric motor 26 is operated it acts to rotate the second gear wheel 29 and thus the six armed joint mechanism 22 in the same vertical plane as indicated by the arrows R1 and R2, respectively. At this time however the proximal end of the lever drive mechanism 19 is restricted to substantially linear movement along its own longitudinal axis, as indicated by arrow 30 of Figure 2. The relative rotational position between the head 2 and the leg mechanism 3, indicated by the arrows R5 within Figure 2, is controlled through the employment of a second electric motor 31 that is mounted on the rotatable disc 10 and which is mechanically connected to the circular perimeter 8 of the support frame 7 via a second gearing mechanism 32. The second gearing mechanism 32 comprises a third gear wheel 33 located on the rotatable disc 10 and configured to interact with a circular toothed gear 34 located around the circular perimeter 8 of the support frame 7. Ball bearings 35 are located between the rotatable disc 10 and the circular perimeter 8 of the support frame 7 so as to assist the rotational movement of the head 2. Further detail of the operating mechanism for the first flexible legs 4 will now be described with reference to Figure 4. The flexible legs 4 can be seen to comprise a first leg lever 36 the proximal end of which is attached to an arm of the first three armed connector 24 and a distal end of which is attached to a surface engaging leg lever 37. The first leg lever 36 is pivotally attached to a first leg attachment joint 12. A second leg lever 38 pivotally attaches the surface engaging leg lever 37 to the first leg attachment joint 12. In Figure 4, the Y-shaped mount 21 is shown aligned with the longitudinal axis of the first leg lever 36 i.e. both lie along the x-axis (see insert). With this arrangement operation of the first electric motor 26 acts to rotate the proximal end of the first leg lever 36 as represented by arrows R2, as described above. As the proximal end of the first leg lever 36 moves it pivots about the first leg attachment joint 12 in a similar manner to a seesaw causing the distal end of the first leg lever 36, and thus the non surface engaging end of the surface engaging leg lever 37, to rotate in the opposite sense to the proximal end of the first leg lever 36, as represented by arrows R3A. The surface engaging leg lever 37 is arranged to pivot about its point of connection with the second leg lever 38, again in a similar manner to a seesaw. As a result, the rotational motion of the non surface engaging end of the surface engaging leg lever 37 acts to rotate the surface engaging end this leg lever 37 in the opposite sense, as represented by arrows R4A. It should be noted that the surface engaging end of this leg lever 37 rotates with the same sense as the proximal end of the first leg lever 36 i.e. R2 has the same rotational sense as R4A. However, an important point to note is that although the rotational senses of R2 and R4A are the same they are offset by half of one rotation. If the Y-shaped mount 21 is rotated through 90° i.e. so as to be aligned with the z-axis (see insert) then rotation the operation of the first electric motor 26 acts to rotate the proximal end of the first leg lever 36 as represented by arrows P2. The first leg lever 36 is therefore driven like an oar of a rowing boat causing the surface engaging end of the surface engaging leg lever 37 to rotate with the same sense as represented by the arrows P4A. An important point to note is that although the rotational senses of P2 and P4A are the same they are again offset by half of one rotation. The walking motion induced on the surface engaging end of surface engaging leg lever 37 can be considered as resulting from vector addition of the above described x-axis and z- axis motions. The magnitude of these components is determined by the rotational movement of the proximal end of the first leg lever 36 and the operating angle of Y-shaped mount 21 relative to the y-axis (see insert), and hence the operating angle of the lever drive mechanism 19. The rotational movement of the surface engaging end of the surface engaging leg lever 37 is always in the same sense as the rotation of the proximal end of the first leg lever 36 but is always offset by half of one rotation. Further detail of the operating mechanism for the second flexible legs 5 will now be described with reference to Figure 5. The second flexible legs 5 can be seen to comprise a substantially Y-shaped leg lever 39 a first proximal end of which is attached to an arm of the second three armed connector 25 and a second proximal end of which is pivotally attached to second leg attachment joint 13. A distal end of the Y-shaped leg lever 39 is pivotally attached towards the middle of a surface engaging leg lever 37. Pivotally attached to the non-surface engaging end of the surface engaging leg lever 37 is a third leg lever 40. The proximal end of the third leg lever 40 is pivotally attached to a third leg attachment joint 16 located on the underside of the circular perimeter 8. Pivotal attachment between the non-surface engaging end of the surface engaging leg lever 37 and the third leg lever 40 is desirable because of the fact that the stationary pivot point provide by attachment joint 16 is not on the same vertical axis as the pivot point provided by second leg attachment joint 13 for the Y-shaped leg lever 39. In Figure 5, the Y-shaped mount 21 is again shown aligned along the x-axis (see insert). With this arrangement operation of the first electric motor 26 acts to rotate the first proximal end of the Y-shaped leg lever 39 as represented by arrows R2, and as described above. As the first proximal end of the Y-shaped leg lever 39 rotates it act to rotate the attachment point between the distal end of the Y-shaped leg lever 39 and the surface engaging leg lever 37, as represented by arrows R3B. It is noted that R2 and R3B exhibit the same rotational sense. The surface engaging leg lever 37 then pivots about its attachment point with the third leg lever 40 causing the surface engaging end of the surface engaging leg lever 37 to also rotate, as represented by arrows R4B. It is further noted that R4B has the same rotational sense as R2 and R3B. If the Y-shaped mount 21 is rotated through 90° i.e. so as to be aligned with the z-axis (see insert) then rotation the operation of the first electric motor 26 acts to rotate first proximal end of the Y-shaped leg lever 39 as represented by arrows P2. The Y-shaped leg lever 39 therefore behaves like a sweeping broom causing the surface engaging end of the surface engaging leg lever 37 to rotate with the same sense as represented by the arrows P4B. The walking motion induced on the surface engaging end of surface engaging leg lever 37 can again be considered as resulting from vector addition of the above described x-axis and z-axis motions. The magnitude of these components is determined by the rotational movement of the first proximal end of the Y-shaped leg lever 39 and the operating angle of Y-shaped mount 21 relative to the y-axis (see insert), and hence the operating angle of the lever drive mechanism 19. The rotational movement of the surface engaging end of the surface engaging leg lever 37 is always in the same sense as the rotation of the first proximal end of the Y-shaped leg lever 39. A point to note is that in order to allow the correct operation of all three of the second flexible legs 5 the arms of the Y-shaped mounts 21 that attach to the second leg attachment joints 13 are formed in the shape of curves, see C1 , C2 and C3 as presented in Figure 6. This provides the second flexible legs 5 with sufficient clearance to produce the above described movements necessary for walking. Locomotion of the steerable walking device 1 is provided by the operation of the first electric motor 26. This acts to simultaneously drive all of the flexible legs 4 and 5 although these legs are always half of one cycle out of step with each other. This ensures that there are always three legs of the steerable walking device 1 in contact with the surface over which it is travelling so providing the device with the required stability. The direction of travel of the steerable walking device 1 can be easily changed through the operation of the second electric motor 31. Operation of the second electric motor 31 acts to alter the relative rotational position between the head 2 and the leg mechanism 3 thus producing a corresponding change in direction for the steerable walking device 1 . Thus instead of the entire device having to rotate to change direction, the steerable walking device 1 simply has to rotate the head 2 and whichever direction it faces becomes the front of the device. The legs mechanism 3 remains stationary while the machine rotates its locomotion direction through 360°. As a result the steerable walking device 1 can manoeuvre in more confined spaces than those devices known in the art. It is preferable for all of the required electronics for the steerable walking device 1 (e.g. batteries, radio control units etc.) to be mounted within a central area of the head 2. This prevents the need for any wires to have to cross the ball bearings 35 thus allow for indefinite rotation between the head 2 and leg mechanism 3. A schematic representation of a steerable walking machine 1 b in accordance with an alternative embodiment of the present invention will now be described with reference to Figures 7 to 9. From Figure 7 the steerable walking machine 1 b can again be seen to comprise a head 2b that is mounted in a rotatable manner upon a leg mechanism 3b. The steerable walking machine 1 b presented in Figure 1 may again be considered to be a "hexapod" since the leg mechanism 3b comprises six flexible legs, three flexible legs having a first operating mechanism 4b and three flexible legs having a second operating mechanism 5b. Each set of flexible legs are located substantially 120° apart on the leg mechanism 3b such that there is again a flexible leg of alternative type every 60° around the leg mechanism 3b. The steerable walking machine 1 b operates in a similar manner to that described previously with reference to Figures 1 to 6. There are however a number of alterations that have been incorporated within the steerable walking machine 1 b which makes the device more mechanically robust while simultaneously making it inherently safer for use by an operator. This is obviously beneficial when the operator of the steerable walking machine 1 b is a young child. These altered features of the steerable walking machine 1 b will now be described with reference to Figures 8 and 9. Figure 8 presents a schematic cross sectional view of a first 4b and a second 5b leg operating mechanism for the steerable walking machine of Figure 7. The representations of Figure 8(a) and Figure 8(b) differ with respect to the presence and absence, respectively, of a support frame 7b. From Figure 8 it can be seen that the first gearing mechanism 27b of the steerable walking machine 1 b differs from that employed within the steerable walking machine 1. In the presently described embodiment the first gearing mechanism 27b comprises a Y-shaped lever drive mechanism 19b. Distal arms of the Y-shaped lever drive mechanism 19b are connected to dedicated second gear wheels 29b while the proximal arm is again connected to six armed joint 22b (further details of which are described below). As a result, when the first electric motor 26 is operated it acts to rotate both of the second gear wheels 29b and thus the six armed joint mechanism 22b in the same vertical plane, as indicated by the arrows R1 and R2, respectively. Significantly however is the fact that the rotational movement of the six armed joint mechanism 22b is achieved without requiring a pivotal Y-shaped mount 21 as employed within the steerable walking machine 1. As a result the proximal arm of Y-shaped lever drive mechanism 19b remains in a substantially vertical orientation without requiring a restraining force being transferred from the first 4b and a second 5b legs. This differs from the operation of the lever drive mechanisms 19 which requires a force transfer from the first 4 and a second 5 legs in order to maintain it in the desired vertical orientation. The overall effect of employing this alternative first gearing mechanism 27b is that it renders the first 4b and a second 5b legs of the steerable walking machine 1 b more mechanically robust. Figures 7 and 8 also highlight some additional design changes to the first legs 4b when compared with those contained within the steerable walking machine 1. In the first instance the second leg levers 38b extend so as to cover the first leg levers 36b. In a similar manner the surface engaging leg levers 37b extend so as to cover the ends of the second leg levers 38b. The extended second leg levers 38b and surface engaging leg levers 37b effectively create an exoskeleton for the first legs 4b and so prevent an operator from being able to insert a finger into the moving components of the first legs 4b. Additional design changes to the second legs 5b when compared with those contained within the steerable walking machine 1 can also be seen with reference to Figures 7 and 8. In the first instance the third leg levers 40b extend so as to cover the leg levers 39b and have rounded profiles at their proximal ends so as to interface smoothly with the leg attachment joints 16b. In a similar manner, the surface engaging leg levers 37b and the leg attachment joints 16b extend so as to cover the opposite ends of the third leg levers 40b. The leg attachment joints 16b still swivel about a vertical axis, and hold the proximal ends of the third leg levers 40b in place with a horizontal pivot point. The extended third leg levers 40b, surface engaging leg levers 37b and leg attachment joints 16b effectively create an exoskeleton for the second legs 5b and so prevent an operator from being able to insert a finger into the moving components of the second legs 5b. The larger leg attachment joints 16b provide a further additional advantage in that they increase the stability of the second legs 5b thus allowing them to remain upright under much larger forces when compared with second legs 5 of the steerable walking machine 1. As a result of the above described changes to the design of the steerable walking machine 1 b the internal space within the device is reduced. In order to accommodate these changes it has proved beneficial to incorporate an alternatively designed six armed joint 22b, a schematic representation of which is provided in Figure 9, and leg lever 39b. As can be seen from Figure 9 the first three armed connector 24b remains as previously described. However the second three armed connector 25b now comprise elongated arms 41 which are connect to a proximal end of the leg lever 39b via a universal joint 42. The presence of the elongated arms 41 act to translate the proximal pivot point for the leg lever 39b away from the Y-shaped lever drive mechanism 19b. The distal end of leg lever 39b is pivotally connected towards the middle of the surface engaging leg lever 37b in a similar manner to that described in relation to the steerable walking machine 1 . As a result the rotational movement of the surface engaging end of the surface engaging leg lever 37b is always in the same sense as the rotation of the proximal end of the leg lever 39b. In this embodiment the need for a second proximal connection point for the leg lever 39b, as required for the Y-shaped leg lever 39 of the steerable walking machine 1 , is removed. This results in a significant internal space saving for the steerable walking machine 1 b. In this embodiment however all three of the second legs 5b must be attached to the second three armed connector 25b in order for any of them to operate correctly i.e. there is nothing keeping the universal joints 42 in the correct spatial alignment other than the combined opposing forces of the three second legs 5b. The above described features of the steerable walking machine 1 b allow certain components of the first 4b and a second 5b legs to operate within other components. As a result the design of the steerable walking machine 1 b facilitates the production of much larger machines that are more durable to use, reliable and which are intrinsically safer for use by an operator when compared to those previously described embodiments. A further alternative embodiment of the steerable walking machine is presented in Figure 10, as generally depicted by reference numeral 1 c. This embodiment is similar to that described above with reference to Figures 7 to 9 with the addition of a number of clip on toy modules in the form of armour 43, exploding armour 44 and weapons 45. Electrical connections provide a means for powering the weapon modules 45 which can be in the form of guns e.g. suction dart guns, light sources etc. The weapon modules 45 are be controlled via a remote control unit 46 by an operator which interacts with a

microprocessor located within the head 2c of the machine 1 c. The clip on armour modules 43 are shaped so as to locate over the legs 4b and 5b and the head 2 of the steerable walking machine 1 c. These components are held in place via an interference fit that results between nodes 47 located on the outer surface of the legs 4b and 5b and the head 2 and holes 48 formed within the armour modules 43. In addition the exploding armour modules 44 further comprise bias means 49 e.g. springs, such that when the exploding armour module 44 is located on the device the bias means 49 push out and lock them in place. When the steerable walking machine 1 c is hit by a weapon 45 from another device e.g. a bullet, light pulse etc. the balance of the device may be sufficiently disrupted, or the microprocessor is activated, so as to unlock the exploding armour module 44 struck by the bullet or light pulse. Once unlocked the exploding armour module 44 is ejected from the steerable walking machine 1 c by the bias means 49. This increases the payability of for the steerable walking devices 1 c since the may be used to duel against one or more other devices. This embodiment may also accommodate a variety of other elements e.g. light sensors within the head, a crane and a magnetic pickup, These elements further increases the payability of for the steerable walking machine 1 c e.g. the head can rotate to aim at targets while simultaneously walking directly towards them. Although the above steerable walking devices 1 and 1 b have been described as comprising a total of six flexible legs, three flexible legs of a first design and three flexible legs of a second design, it will be apparent to the skilled reader that the number of legs is not so limited. By way of example, in an alternative embodiment only two flexible legs of each design are employed. In this embodiment each set of flexible legs are located substantially 180° apart on the leg mechanism 3 such that there is a flexible leg of alternative type every 90° around the leg mechanism 3. To increase the stability of this embodiment of the device it is preferable for each flexible leg to comprise a foot so as to increase the area of contact between each flexible leg and the surface over which the device is moving. In a yet further alternative embodiment more than three flexible legs of each design, suitably spaced around the around the leg mechanism 3 may be employed. It is envisaged that the above described invention could be scaled to provide a full sized human driveable (or remote controlled) vehicle. The steerable walking machine described above provides a device that can walk in any direction without having to turn. This functionality is achieved through the employment of only two electric motors, one employed for locomotion and the other employed for steering. The steerable walking machine therefore employs fewer electric motors, and associated electronics, than those devices known in the art. The use of only two electric motors retains the manoeuvrability and payability of the more expensive and complex prior art devices whilst employing a more simplified design. As a result of the design of the device no reverse control is required to be incorporated. This means that the device can be controlled by fewer buttons or signals than is usually required for standard radio controlled toys. In an alternative embodiment normally reverse button or signal may be employed for an alternative accessory such as suction dart gun, a crane, a magnetic pickup, etc. A steerable walking machine is described which comprises a leg mechanism that provides a means for locomotion of the machine across a surface and a head rotatably mounted upon the leg mechanism. The rotational position of the head upon the leg mechanism acts to defines a direction of locomotion of the machine across the surface. The steerable walking machine can therefore walk in any direction without requiring the leg mechanism to turn and so can manoeuvre in more confined spaces than those devices known in the art. A first motor is employed to control the leg mechanism while a second motor controls the rotation of the head upon the leg mechanism. The functionality of the steerable walking machine is therefore achieved through the employment of only two motors thus significantly reducing the manufacturing costs involved. The foregoing description of the invention has been presented for purposes of illustration and description and is not intended to be exhaustive or to limit the invention to the precise form disclosed. The described embodiments were chosen and described in order to best explain the principles of the invention and its practical application to thereby enable others skilled in the art to best utilise the invention in various embodiments and with various modifications as are suited to the particular use contemplated. Therefore, further modifications or improvements may be incorporated without departing from the scope of the invention as defined by the appended claims.