Unmanned aerial vehicle take-off and landing control system and control method

What is claimed is: 1. An unmanned aerial vehicle take-off and landing control system, comprising: an unmanned aerial vehicle having a contact surface provided with a magnet assembly, the unmanned aerial vehicle having: a wing configured to rotate to generate lift force, and a rotational speed measuring device configured to generate a rotational speed detection value; a landing platform provided with a magnetic field assembly; an electrified coil provided in the magnetic field assembly; a controller; wherein the controller is configured to control the electrified coil to be supplied with a current, and the magnetic field assembly generates a supporting magnetic field to form a thrust force that acts on the magnetic assembly so the unmanned aerial vehicle is in a magnetic levitation state, and wherein the controller is configured to receive the rotational speed detection value and decrease the current supplied to the electrified coil when the rotational speed value is equal to a preset rotation speed value. 2. The unmanned aerial vehicle take-off and landing control system according to claim 1 , further comprising a distance measuring device, wherein: the rotational speed measuring device is configured to measure a rotational speed of the wing of the unmanned aerial vehicle, the distance measuring device is configured to measure a distance between the unmanned aerial vehicle and a predetermined parking location, and the controller is configured to change a direction and a magnitude of the current supplied into the electrified coil according to the rotational speed measured by the rotational speed measuring device and/or the distance measured by the distance measuring device. 3. The unmanned aerial vehicle take-off and landing control system according to claim 2 , wherein the controller is configured to receive a take-off instruction with which to control the current supplied to the electrified coil to be a forward current which is increased, and thus control the supporting magnetic field generated by the magnetic field assembly such that the thrust force that the supporting magnetic field generated is an upward thrust force that acts on the unmanned aerial vehicle, and the controller is configured to supply the electrified coil with a forward current wherein an air gap is formed when the upward thrust force acting on the unmanned aerial vehicle by the supporting magnetic field is equal to a gravity of the unmanned aerial vehicle, and the forward current supplied to the electrified coil reaches a maximum forward current. 4. The unmanned aerial vehicle take-off and landing control system according to claim 3 , wherein: the controller is configured to receive a landing instruction, the distance measuring device is configured to detect whether the distance between the unmanned aerial vehicle and the predetermined parking location is within a landing allowable range, and the controller is configured to control the current supplied to the electrified coil to be a reverse current to drag the unmanned aerial vehicle to right above the predetermined parking location and the rotational speed of the wing of the unmanned aerial vehicle is maintained unchanged if the distance between the unmanned aerial vehicle and the landing platform is detected to be within the landing allowable range. 5. The unmanned aerial vehicle take-off and landing control system according to claim 4 , wherein: the controller is configured to control the current supplied to the electrified coil to be a forward current which is increased after the unmanned aerial vehicle is dragged right above the predetermined parking location, and the controller is configured to stop supplying the current to the electrified coil when the rotational speed of the wing of the unmanned aerial vehicle is measured by the rotational speed measuring device to be zero and the distance measuring device detects that the distance between the unmanned aerial vehicle and the predetermined parking location is zero. 6. The unmanned aerial vehicle take-off and landing control system according to claim 5 , wherein: the unmanned aerial vehicle further includes an energy storage device and a charge coil provided on an undercarriage of the unmanned aerial vehicle, the energy storage device and the charge coil being electrically connected, unless the unmanned aerial vehicle is flying during which time the energy storage device and the charge coil are disconnected, the controller is configured to control the current supplied to the electrified coil to be a charging current when the unmanned aerial vehicle is parked on the landing platform, to control the magnetic field assembly to generate a varying charging magnetic field at a side of the landing platform, and to control the energy storage device and the charge coil to be connected to charge the energy storage device when the charging current is supplied. 7. The unmanned aerial vehicle take-off and landing control system according to claim 6 , wherein the distance measuring device comprises an infrared distance measuring device provided in the unmanned aerial vehicle and an infrared receiving device provided at the side of the landing platform, and a width of the infrared receiving device is greater than a width of the infrared distance measuring device. 8. The unmanned aerial vehicle take-off and landing control system according to claim 7 , wherein the magnet assembly comprises a permanent magnet, and the magnetic field assembly comprises an iron core and the electrified coil is wound around the iron core. 9. A control method for controlling take-off and landing of an unmanned aerial vehicle by using an unmanned aerial vehicle take-off and landing control system comprising the unmanned aerial vehicle having a contact surface provided with a magnet assembly, the unmanned aerial vehicle further having a wing configured to rotate to generate lift force, a rotational speed measuring device, an energy storage device, and a charge coil, the manned aerial vehicle take-off and landing control system further comprising a landing platform provided with a magnetic field assembly, an electrified coil provided in the magnetic field assembly, a distance measuring device, and a controller, wherein the controller is configured to control the electrified coil to be supplied with a current, and the magnetic field assembly generates a supporting magnetic field to form a thrust force that acts on the magnetic assembly so the unmanned aerial vehicle is in a magnetic levitation state, the method comprises the following steps: receiving, by the controller, a take-off instruction, which is used by the controller to control the current supplied to the electrified coil to be a forward current which is increased; and when the thrust force acting on the unmanned aerial vehicle by the supporting magnetic field is equal to a gravity of the unmanned aerial vehicle, the forward current supplied to the electrified coil reaches a maximum forward current, and an air gap is formed between the unmanned aerial vehicle and the landing platform; controlling, by the controller and after the air gap is formed between the unmanned aerial vehicle and the landing platform, the maximum forward current supplied to the electrified coil to be unchanged, and the wing of the unmanned aerial vehicle to start to rotate, feeding back a rotational speed detection signal by the rotational speed measuring device to an input end of the controller, and the controller providing a controlling signal according to the inputted rotational speed detection signal to control the forward current supplied to the electrified coil to decrease with the increasing of the rotational speed of the wing of the unmanned ae