Magnetically damped isolator and pointing mount

What is claimed is: 1. A system for mounting and isolating a payload onboard a host platform, said system comprising: a base plate mounted to the host platform; an isolator plate on which the payload is affixed; a plurality of flexures attached to both the base plate and the isolator plate, wherein said flexures support the isolator plate at a distance from the base plate; and three bidirectional magnetic dampers connected between the isolator plate and the base plate which collectively provide magnetic damping of all six degrees of freedom of motion of the isolator plate with respect to the base plate. 2. The system of claim 1 wherein each of the bidirectional magnetic dampers includes: two back iron plates of identical rectangular shape, where the back iron plates are composed of a material with a high magnetic permeability, and where the back iron plates are arranged parallel to each other to define inner faces and outer faces; a plurality of permanent magnets, where half of the magnets are attached to the inner face of each of the back iron plates, and where a fixed air gap exists between the magnets on one back iron plate and the magnets on the other back iron plate; and a conductor plate of a size generally equivalent to the back iron plates, where the conductor plate is oriented parallel to the back iron plates and positioned in the air gap between the magnets, and where the conductor plate is composed of a material with a high electrical conductivity and a low magnetic permeability, whereby an in-plane movement of the conductor plate relative to the back iron plates produces a force on the conductor plate which is a function of and in an opposite direction to a velocity of the movement. 3. The system of claim 2 wherein the plurality of permanent magnets is eight magnets in an arrangement with one of the magnets positioned at each corner of the inner faces of each of the back iron plates. 4. The system of claim 2 wherein the permanent magnets are composed of a neodymium-iron-boron alloy, the back iron plates are composed of iron or a magnetic alloy thereof, and the conductor plate is composed of a copper alloy. 5. The system of claim 2 further comprising electrical coils affixed to at least one face of the conductor plate, where electrical current can be supplied to the coils to produce a translational force on the conductor plate relative to the back iron plates, whereby the bidirectional magnetic dampers can supply an actuation force and the system can actively position the payload relative to the host platform. 6. The system of claim 1 wherein the flexures and the bidirectional magnetic dampers are arranged such that a motion of the payload produces an amplified motion within the bidirectional magnetic dampers, thereby increasing damping effectiveness of the bidirectional magnetic dampers. 7. A system for mounting and isolating a payload onboard a host platform, said system comprising: a base plate mounted to the host platform; an isolator plate on which the payload is affixed; a plurality of spring flexures attached to both the base plate and the isolator plate, where the spring flexures support the isolator plate in a position generally parallel to the base plate and at a prescribed distance from the base plate; and three bidirectional magnetic dampers positioned at equal 120° intervals around a periphery of the isolator plate and attached to both the base plate and the isolator plate, where the bidirectional magnetic dampers collectively provide magnetic damping of all six degrees of freedom of motion of the isolator plate with respect to the base plate. 8. The system of claim 7 wherein each of the bidirectional magnetic dampers includes: two back iron plates of identical rectangular shape, where the back iron plates are composed of a material with a high magnetic permeability, and where the back iron plates are arranged parallel to each other to define inner faces and outer faces; a coupling device rigidly attached between the two back iron plates and holding the back iron plates in alignment with and parallel to each other at a fixed distance between the inner faces, where the coupling device is composed of a material with a low magnetic permeability; eight permanent magnets, where four of the magnets are attached to the inner face of each of the back iron plates in an arrangement with one of the magnets positioned at each corner of each of the back iron plates, and where a fixed air gap exists between the magnets on one back iron plate and the magnets on the other back iron plate; and a conductor plate of a size generally equivalent to the back iron plates, where the conductor plate is oriented parallel to the back iron plates and positioned in the air gap between the magnets, and where the conductor plate is composed of a material with a high electrical conductivity and a low magnetic permeability, whereby an in-plane movement of the conductor plate relative to the back iron plates produces a force on the conductor plate which is a function of and in an opposite direction to a velocity of the movement. 9. The system of claim 8 wherein the conductor plate of each of the bidirectional magnetic dampers is fixed to the base plate, and one of the back iron plates of each of the bidirectional magnetic dampers is coupled to the isolator plate, the coupling device has a cylindrical shape and is positioned centrally on the inner faces of the back iron plates, and the conductor plate has a central hole larger than a diameter of the coupling device and through which the coupling device passes. 10. The system of claim 8 further comprising electrical coils affixed to at least one face of the conductor plate, where electrical current can be supplied to the coils to produce a translational force on the conductor plate relative to the back iron plates, whereby the bidirectional magnetic dampers can supply an actuation force and the system can actively position the payload relative to the host platform. 11. The system of claim 8 wherein the permanent magnets are composed of a neodymium-iron-boron alloy, the back iron plates are composed of iron or a magnetic alloy thereof, the coupling device is composed of stainless steel, and the conductor plate is composed of a copper alloy. 12. The system of claim 7 wherein the plurality of spring flexures is six L-shaped flexures, where one leg of each L-shaped flexure is fixed to the base plate and the other leg of each L-shaped flexure extends out of plane of the base plate and attaches at a distal end to the isolator plate, and where the six L-shaped flexures are positioned in pairs at three equally-spaced locations around the isolator plate, and a position and orientation of the six L-shaped flexures are designed to place a center of force of the six L-shaped flexures at a distance from the base plate which is equal to a distance from the base plate to a center of mass of the payload. 13. The system of claim 7 wherein the host platform is a space vehicle operating in a zero-gravity environment. 14. A motion-amplifying system for mounting and isolating a payload onboard a host platform, said system comprising: a base plate mounted to the host platform; an isolator plate on which the payload is affixed; a central hub fixed to the base plate; three bending beams having a slender rod shape, where the bending beams are positioned at equal 120° intervals around the central hub, and where the bending beams are fixed at an inner end to the central hub and extend perpendicularly away from the central hub and parallel to the base plate; three strut extensions having a cylindrical sha