Control of a passive prosthetic knee joint with adjustable damping

The invention claimed is: 1. A method, comprising: providing a passive prosthetic knee joint and a prosthetic leg unit, the passive prosthetic knee joint being connected to the prosthetic leg unit, the prosthetic leg unit comprising a prosthetic foot; operating the passive prosthetic knee in a stair climbing mode comprising: detecting with at least one sensor of the passive prosthetic knee joint a lift phase of the prosthetic foot, the at least one sensor generating first sensor data associated with detecting the lift phase; adjusting a flexion damping level of the passive prosthetic knee joint in the lift phase in response to the first sensor data to a reduced level that is below a level used by the passive prosthetic knee joint during a lift phase of a swing phase control when walking on level ground; detecting with at least one sensor a foot placement phase of the prosthetic foot, the at least one sensor generating second sensor data associated with detecting the foot placement phase; increasing the flexion damping level of the passive prosthetic knee joint in the foot placement phase in response to the second sensor data from the reduced level to an increased level that is above the level that is used during a foot placement phase of the swing phase control when walking on level ground; and maintaining the increased level until a straightened hip is detected when in the foot placement phase. 2. The method of claim 1 , wherein in the foot placement phase, an extension damping level is increased to an increased level that is above a level that is used for walking on level ground. 3. A method, comprising: providing a passive prosthetic knee joint and a prosthetic unit, the passive prosthetic knee joint being connected to the prosthetic unit, and the prosthetic unit comprising an artificial foot; controlling the passive prosthetic knee joint with adjustable damping in a direction of flexion such that the prosthetic unit can climb stairs, the controlling comprising: detecting with at least one sensor of the passive prosthetic knee joint a low-torque lift phase of the prosthetic foot, the at least one sensor generating first sensor data associated with detecting the low-torque lift phase; lowering the flexion damping in the low-torque lift phase in response to the first sensor data to below a level that is used during a swing phase control when walking on level ground; detecting with at least one sensor of the passive prosthetic knee joint a foot placement and hip-straightening phase, the at least one sensor generating second sensor data associated with detecting the foot placement and hip-straightening phase; increasing extension damping and flexion damping in the foot placement and hip-straightening phase in response to the second sensor data to a level above a damping of the swing phase control when walking on level ground; and maintaining the increased flexion damping in the foot placement and hip-straightening phase until a hip is fully straightened. 4. The method of claim 3 , wherein the flexion damping in the foot placement phase is increased to a maximum value. 5. The method of claim 3 , wherein the flexion damping is lowered as a function of an axial force acting on a lower leg shaft. 6. The method of claim 3 , wherein an extension damping is set at a first level during the low-torque lift phase and set at a second level during the foot placement and hip-straightening phase. 7. The method of claim 3 , wherein the at least one sensor includes a force sensor or a torque sensor. 8. The method of claim 3 , wherein the low-torque lift phase is detected by the at least one sensor determining that no forefoot moment is present, which indicates no forefoot load. 9. The method of claim 3 , wherein the flexion in the low-torque lift phase is provided by a pre-tensioned spring mechanism. 10. The method of claim 3 , wherein the increase in the flexion and extension damping is initiated when the prosthetic foot, after being lifted, is placed down again. 11. The method of claim 3 , wherein the flexion damping in the low-torque lift phase is lowered to a minimum value.