MEMS reflector system

The invention claimed is: 1. A microelectromechanical reflector system comprising: a support; a reflector, a peripheral edge of the reflector including edge points; suspenders including piezoelectric actuators and suspending the reflector from the support; a control device, wherein two pairs of suspenders are fixed from two fixing points to the support such that in each pair of suspenders, first ends of a pair of suspenders are fixed to a fixing point common to the pair, a first axis of rotation is aligned to a line running though the two fixing points, and divides the reflector to a first reflector part and a second reflector part; in each pair of suspenders, a second end of one suspender is coupled to the first reflector part and a second end of the other suspender is coupled to the second reflector part; the control device is coupled to the piezoelectric actuators of the suspenders; the control device is configured to provide control signals to the piezoelectric actuators to simultaneously drive the reflector to a first rotary oscillation about the first axis of rotation in a first resonance frequency, and to a second rotary oscillation about a second axis of rotation in a second resonance frequency, wherein the first axis of rotation and the second axis of rotation are orthogonal, the resulting position of the reflector is a superposition of the first rotary oscillation and the second rotary oscillation, and the first resonance frequency and the second resonance frequency are different but integer multiples of a common numerical value; the reflector system comprises a tuning element comprising an additional movable electrode and a stationary electrode fixed to the support; the additional movable electrode is fixed to the reflector to move with deflections of the reflector, or the additional movable electrode is fixed to the suspender to move with deflections of the suspender; the movable electrode is capacitively coupled to the stationary electrode; and the control device is configured to provide an additional controlled voltage between the movable electrode and the stationary electrode. 2. A microelectromechanical reflector system of claim 1 , wherein a first pair of the two pairs of suspenders includes a first suspender and a second suspender, a first end of the first suspender and a first end of the second suspender fixed from a first fixing point to the support, a second pair of the two pairs of suspenders includes a third suspender and a fourth suspender, a first end of the third suspender and a first end of the fourth suspender fixed from a second fixing point to the support, and wherein the first axis of rotation is aligned to a line running though the first fixing point and the second fixing point. 3. A microelectromechanical reflector system of claim 2 , wherein the edge points include a first edge point and a second edge point, each of which coincides with the first axis of rotation; the first fixing point is adjacent to the first edge point, separated by a gap; and the second fixing point is adjacent to the second edge point, separated by a gap. 4. A microelectromechanical reflector system of claim 2 , further comprising: a third edge point and a fourth edge point in an edge of the first reflector part; a fifth edge point and a sixth edge point in an edge of the second reflector part; wherein the third edge point and the fourth edge point are separated by a non-zero distance, the fifth edge point and the sixth edge point are separated by a non-zero distance, a second end of the first suspender is coupled to the third edge point, a second end of the second suspender is coupled to the fifth edge point, a second end of the third suspender is coupled to the sixth edge point, and wherein a second end of the fourth suspender is coupled to the fourth edge point. 5. A microelectromechanical reflector system of claim 4 , wherein the second axis of rotation is parallel to a line running through the third edge point and the fifth edge point on a plane determined by the third edge point, the fifth edge point and at least one of the fourth edge point and the sixth edge point. 6. A microelectromechanical reflector system of claim 1 , wherein in a non-actuated state, an outer surface of the planar reflector is aligned to a first plane, a direction parallel to a normal to the first plane is an out-of-plane direction; and the coupling between a second end of at least one suspender and an edge point to which the suspender is coupled includes a first coupling spring that relays deflection of the second end of the suspender to the edge point in the out-of-plane direction, and responds flexibly to deflection of the second end of the suspender in at least one in-plane direction parallel to the first plane. 7. A microelectromechanical reflector system of claim 1 , wherein the movable electrode is a movable comb electrode, and comb fingers of the movable comb electrode extend over one fourth or less of the length of the outer edge in the second end of the respective suspender. 8. A microelectromechanical reflector system of claim 1 , wherein the movable electrode is a movable comb electrode, and comb fingers of the movable comb electrode extend over at least one third of the length of the outer edge in the second end of the respective suspender. 9. An optical device including the microelectromechanical reflector system of claim 1 .