Method for controlling an artificial orthotic or prosthetic knee joint

The invention claimed is: 1. A method for controlling an artificial orthotic or prosthetic knee joint, the orthotic or prosthetic knee joint including a resistance device, at least one sensor, and a below-knee component, the method comprising: determining sensor data via the at least one sensor during use of the orthotic or prosthetic knee joint; determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and/or an angular velocity of the below-knee component with the sensor data; comparing at least one of the determined linear acceleration, the determined extended stride position, the determined knee angle, the determined knee angle velocity, and/or the determined angular velocity with at least one threshold value therefor; reducing a flexion resistance if the threshold value is reached; determining an absolute angle of the below-knee component in order to detect a terminal stance phase; determining a knee moment about an axis of the orthotic or prosthetic knee joint in order to detect the terminal stance phase; and reducing the flexion resistance if a predefined limit value for the absolute angle of the below-knee component is exceeded such that the below-knee component has a forward inclination and if the knee moment is acting in an extension direction, wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises determining the linear acceleration of the below-knee component, and reducing the flexion resistance when the extended stride position is present, and wherein the threshold value is zero acceleration in a horizontal direction. 2. The method as claimed in claim 1 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises determining the extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, and reducing the flexion resistance when the extended stride position is present. 3. The method as claimed in claim 1 , further comprising measuring the absolute angle of the below-knee component from an absolute angle of a thigh component and a knee angle or directly with an inertial angle sensor. 4. The method as claimed in claim 1 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises determining the knee angle via the at least one sensor, and reducing the flexion resistance if a predefined limit value for the knee angle is not reached. 5. The method as claimed in claim 1 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises determining the knee angle velocity, and reducing the flexion resistance only when a limit value is exceeded. 6. The method as claimed in claim 1 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises calculating or detecting the angular velocity of the below-knee component via the at least one sensor, and reducing the flexion resistance only when the angular velocity is below a limit value. 7. The method as claimed in claim 1 , wherein, after a reduction of the flexion resistance, the method further comprising increasing the flexion resistance again if, within a predefined time interval, no bending of the knee joint took place, or if, within an enclosed knee angle, a limit value for an acceleration is exceeded. 8. The method as claimed in claim 1 , wherein the at least one sensor includes an inertial sensor and an acceleration sensor. 9. A method to control an artificial orthotic or prosthetic knee joint, the method comprising: providing an inertial measurement system, a below-knee component positioned on the orthotic or prosthetic knee joint, and a resistance device, the below-knee component including a sole member; determining sensor data via the inertial measurement system during use of the orthotic or prosthetic knee joint; determining a linear acceleration at a level of the sole member, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data; comparing at least one of the determined linear acceleration, the determined extended stride position, the determined knee angle, the determined knee angle velocity, and the determined angular velocity with at least one threshold value; reducing a flexion resistance if the threshold value is reached; determining an absolute angle of the below-knee component in order to detect a terminal stance phase; and reducing the flexion resistance if a predefined limit value for the absolute angle of the below-knee component is exceeded such that the below-knee component has a forward inclination and if the linear acceleration is zero in a horizontal direction. 10. The method as claimed in claim 9 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises determining the extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, and reducing the flexion resistance when the extended stride position is present. 11. The method as claimed in claim 9 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or orthotic knee joint, a knee angle, a knee angle velocity, and an angular velocity of the below-knee component with the sensor data comprises determining the linear acceleration of the below-knee component, and reducing the flexion resistance when the extended stride position is present, and wherein the threshold value is zero acceleration in a horizontal direction. 12. The method as claimed in claim 11 , further comprising measuring the absolute angle of the below-knee component from an absolute angle of a thigh component and a knee angle or directly with an inertial angle sensor. 13. The method as claimed in claim 9 , wherein determining at least one of a linear acceleration of the below-knee component, an extended stride position of a prosthesis or orthosis having the artificial prosthetic or ort