Vibration angular velocity sensor

The invention claimed is: 1. A vibration angular velocity sensor comprising: a substrate; a vibrator including support members, linear drive beams, and a plurality of weight portions connected by the drive beams, the vibrator vibrating the plurality of weight portions by bending of the drive beams, the vibrator fixed to the substrate through the support members at fixed points of the drive beams; detection fixed portions formed to one surface side of the substrate and having detection fixed electrodes fixed to the substrate; detection weights including detection movable electrodes disposed opposite to the detection fixed electrodes and mass portions to which the movable electrodes are provided; a pair of inner drive weights surrounding the detection weights and connected with the detection weights through detection beams; a pair of outer drive weights disposed to both sides sandwiching the pair of inner drive weights; and drive fixed portions generating electrostatic attraction forces that vibrate the inner drive weights and the outer drive weights in opposite directions to each other, wherein the outer drive weights and the inner drive weights connected with the detection weights form the plurality of weight portions, the drive beams connect the inner drive weights and the outer drive weights, the support members support the inner drive weights connected with the outer drive weights and the detection weights to the substrate at the fixed points of the drive beams, a sensor driving that vibrates the outer drive weights and the inner drive weights is performed by bending the drive beams based on the electrostatic attraction forces generated by the drive fixed portions, when an angular velocity is applied during the sensor driving, the detection weights are moved in a direction perpendicular to a vibration direction of the inner drive weights by bending of the detection beams, and the angular velocity is detected based on changes of capacitances of the detection fixed electrodes and the detection movable electrodes, the support members include rotation beams that wave and bend during the sensor driving, support beams that support both ends of the rotation beams to the substrate, and connection portions that connect the rotation beams and the drive beams at the fixed points of the drive beams, when a beam width ratio of a width h 2 of the rotation beams to a width h 1 of the drive beams in the vibration direction of the outer drive weights and the inner drive weights is expressed by R, 1/R is set to be greater than or equal to 1, the pair of inner drive weights are vibrated with opposite phases with a drive resonance frequency fd in a drive mode, the pair of inner drive weights are vibrated with same phase with an undesirable mode frequency fr in an undesirable vibration mode, the undesirable mode frequency fr is higher than the drive resonance frequency fd, and a frequency difference Δfr between the drive resonance frequency fd and the unnecessary mode frequency fr is greater than or equal to 10%. 2. The vibration angular velocity sensor according to claim 1 , wherein 1/R is set to be greater than or equal to 2. 3. The vibration angular velocity sensor according to claim 2 , wherein 1/R is set to be greater than or equal to 3. 4. The vibration angular velocity sensor according to claim 1 , wherein the sensor driving is performed when an alternating-current voltage is applied between the drive fixed portions and the inner drive weights and the outer drive weights, a frequency of the alternating-current voltage is set to be a drive resonance frequency fd, and the drive resonance frequency fd is set to be several kHz to several tens of kHz. 5. The vibration angular velocity sensor according to claim 4 , wherein the drive resonance frequency fd is set to be 5 kHz to 10 kHz. 6. The vibration angular velocity sensor according to claim 1 , wherein one of the outer drive weights, one of the inner drive weights, the other of the inner drive weights, and the other of the outer drive weights are arranged in order and are connected by the drive beams, and the support members connect the substrate and the drive beams at positions between the one of the outer drive weights and the one of the inner drive weights, between one of the inner drive weights and the other of the inner drive weights, and between the other of the inner drive weights and the other of the outer drive weights.