Acceleration sensor

What is claimed is: 1. An acceleration sensor comprising: a fixation member; a weight member including two sides opposite to each other in a first direction when looked at in a plan view; a vibrating beam including a first end portion connected at one location to the fixation member and a second end portion connected at one location to one of the two sides of the weight member opposite to each other in the first direction when looked at in a plan view, the vibrating beam supporting the weight member to be displaceable in the first direction; a holding beam including a first end portion connected at one location to the fixation member and a second end portion connected at one location to the other of the two sides of the weight member opposing to each other in the first direction when looked at in a plan view, the holding beam supporting the weight member to be displaceable in the first direction; a driver disposed on the vibrating beam and vibrating the vibrating beam; and a detector disposed on the vibrating beam and configured to output a detection signal that changes according to deformation of the vibrating beam; wherein at the one of the two sides of the weight member opposite to each other in the first direction when looked at in a plan view, the weight member is connected to the fixation member by only the vibrating beam and the weight member is supported at only one location; at the other of the two sides of the weight member opposite to each other in the first direction when looked at in a plan view, the weight member is connected to the fixation member by only the holding beam and the weight member is supported at only one location; and the weight member is supported at a total of only two locations. 2. The acceleration sensor according to claim 1 , wherein the vibrating beam is vibrated by the driver in a point-symmetric vibration mode. 3. The acceleration sensor according to claim 1 , wherein the vibrating beam has a meander shape zigzagging with respect to the first direction and a point-symmetric shape with a center point thereof being a reference, the vibrating beam including a weight member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the weight member, a fixation member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the fixation member, and a vibrating portion connected between the weight member-side connecting portion and the fixation member-side connecting portion and that extends in a second direction perpendicular or substantially perpendicular to the first direction; the holding beam includes a weight member-side connecting portion that extends in the first direction from a connected position between the holding beam and the weight member, a fixation member-side connecting portion that extends in the first direction from a connected position between the holding beam and the fixation member, and a vibrating portion connected between the weight member-side connecting portion and the fixation member-side connecting portion and that extends in the second direction; and the vibrating portion connected to the weight member-side connecting portion in the holding beam and the vibrating portion connected to the weight member-side connecting portion in the vibrating beam extend in opposite directions. 4. The acceleration sensor according to claim 1 , wherein the vibrating beam includes a fixation member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the fixation member; and a center position of the fixation member-side connecting portion of the vibrating beam in the second direction is coincident with a center position of the weight member in the second direction. 5. The acceleration sensor according to claim 1 , wherein the vibrating beam includes a weight member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the weight member, a fixation member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the fixation member, and a vibrating portion connected between the weight member-side connecting portion and the fixation member-side connecting portion and that extends in a second direction perpendicular or substantially perpendicular to the first direction; and a center position of the weight member-side connecting portion of the vibrating beam in the second direction is offset from a center position of the weight member in a direction in which a size of the vibrating portion of the vibrating beam connected to the weight member-side connecting portion of the vibrating beam in the second direction is increased. 6. The acceleration sensor according to claim 1 , wherein the vibrating beam includes a plurality of vibrating portions, and a spacing between two adjacent ones of the plurality of vibrating portions in the first direction is smaller than a width of each of the plurality of vibrating portions in the first direction. 7. The acceleration sensor according to claim 1 , wherein the vibrating beam includes a fixation member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the fixation member, a weight member-side connecting portion that extends in the first direction from a connected position between the vibrating beam and the weight member, and a plurality of vibrating portions; and in the vibrating beam, a width of each of the fixation member-side connecting portion and the weight member-side connecting portion in the second direction is equal or substantially equal to a width of each of the plurality of vibrating portions in the first direction. 8. The acceleration sensor according to claim 1 , wherein the fixation member has an external shape that is a rectangular or substantially rectangular frame. 9. The acceleration sensor according to claim 1 , wherein the weight member includes a substantially quadrangular plate. 10. The acceleration sensor according to claim 1 , wherein respective centers of the fixation member, the vibrating beam, the weight member, and the holding beam in an X-Y plane are arranged to lie on an X-axis. 11. The acceleration sensor according to claim 1 , wherein each of the vibrating beam and the holding beam has resiliency and is configured to expand and contract in an X-axis direction. 12. The acceleration sensor according to claim 1 , wherein each of the driver and the detector includes a lower electrode layer provided on the vibrating beam at an upper surface side, a piezoelectric layer provided on the lower electrode layer, and an upper electrode layer provided on the piezoelectric layer. 13. The acceleration sensor according to claim 1 , wherein the driver includes a plurality of band-shaped portions and a plurality of connecting portions. 14. The acceleration sensor according to claim 13 , wherein the band-shaped portions are one of L-shaped, substantially L-shaped, C-shaped and substantially C-shaped. 15. The acceleration sensor according to claim 1 , wherein each of the vibrating beam, the driver and the detector has a point-symmetric shape with a center point thereof being a reference.