Optical element driving device, camera module, camera-mounted device, and driving method

What is claimed is: 1 . An optical element driving device, comprising: a fixed body; a movable body that holds an optical element and is disposed so as to be movable with respect to the fixed body; a driving part that includes a piezoelectric element and converts vibration motion of the piezoelectric element into linear motion for driving the movable body; a drive control part that applies a drive signal including a predetermined drive frequency to the driving part; a drive detection part that detects a drive state of the driving part; and a temperature measurement part that measures an ambient temperature of the driving part, wherein the drive control part is configured to store a plurality of drive frequencies and a plurality of ambient temperatures respectively in association with each other, the drive control part determines whether or not a drive error of the driving part occurs from information detected by the drive detection part, when the drive error occurs, the drive control part performs comparison between an ambient temperature associated with a current drive frequency and a current ambient temperature measured by the temperature measurement part, the ambient temperature being one of the plurality of ambient temperatures, and the drive control part corrects the current drive frequency according to a result of the comparison, and stores the current drive frequency corrected and the current ambient temperature in association with each other. 2 . The optical element driving device according to claim 1 , wherein: the plurality of drive frequencies include a reference frequency associated with a reference temperature in advance, a first correction frequency set higher than the reference frequency, and a second correction frequency set lower than the reference frequency, and the drive control part performs comparison between the reference temperature and the current ambient temperature, and selects one of the first correction frequency and the second correction frequency according to a result of the comparison. 3 . The optical element driving device according to claim 2 , wherein a plurality of the first correction frequencies are set stepwise, and a plurality of the second correction frequencies are set stepwise. 4 . The optical element driving device according to claim 2 , wherein when the current drive frequency is not correctable, the drive control part set the current drive frequency back to the reference frequency and maintains the reference frequency. 5 . The optical element driving device according to claim 1 , wherein: the driving part has a plurality of drive modes respectively having drive directions different to each other, and the drive control part controls the predetermined drive frequency for each of the plurality of drive modes. 6 . The optical element driving device according to claim 1 , wherein the drive detection part is a magnetic sensor. 7 . The optical element driving device according to claim 1 , wherein the temperature measurement part is a thermistor. 8 . A camera module, comprising: the optical element driving device according to claim 1 ; and an imaging part that captures a subject image by using the optical element. 9 . A camera-mounted device that is an information device or a transporting device, the camera-mounted device comprising: the camera module according to claim 8 . 10 . A method for driving an optical element driving device that includes a fixed body, a movable body disposed so as to be movable with respect to the fixed body, and a driving part including a piezoelectric element and converting vibration motion of the piezoelectric element into linear motion for driving the movable body, the method comprising: applying a drive signal including a predetermined drive frequency to the driving part; detecting a drive state of the driving part; measuring a current ambient temperature of the driving part; determining whether or not a drive error of the driving part occurs from the drive state detected; when the drive error occurs, performing comparison between an ambient temperature associated with a current drive frequency and the current ambient temperature measured, and correcting the current drive frequency according to a result of the comparison; and storing the current drive frequency corrected and the current ambient temperature in association with each other.