JP7001455B2 - Optical scanning device - Google Patents

Description

The present invention relates to an optical scanning device having a function of calibrating the intensity of a drive signal.

Conventionally, there is known an optical scanning device that includes a scanning mirror that reflects laser light from a light source and a drive mechanism that drives the scanning mirror to reciprocate, and scans with laser light (see Patent Document 1). ).

This optical scanning device includes a rear mirror that rotates with the rotation of the scanning mirror, and a servo light source that emits servo light. In this optical scanning device, the scanning range by the laser beam is monitored by irradiating the rear mirror with servo light and detecting the reflected light with an optical spot position sensor such as a PSD (position sensitive detector).

Japanese Unexamined Patent Publication No. 2008-298686

However, according to the optical scanning device of Patent Document 1, in order to monitor the scanning range by the laser beam, a servo light source and a rear mirror are required in addition to the scanning light source, which complicates the device configuration.

Further, when the optical scanning device is configured by using the scanning mirror as a digital micromirror device as a MEMS (Micro Electro Mechanical Systems) device, the scanning mirror is configured as a double-sided mirror having a rear mirror. Therefore, the mass of the scanning mirror increases, which leads to an increase in power for driving the scanning mirror and a decrease in scanning performance.

Furthermore, since it has a more complicated device configuration than a normal optical scanning device that does not have a servo light source, a special package structure suitable for dustproof and moistureproof measures is used. There is a need.

Therefore, when trying to calibrate the intensity of the drive signal in the optical scanning device so as to obtain an appropriate scanning angle by utilizing the scanning range monitoring function in the optical scanning device of Patent Document 1, the device configuration is complicated. In addition, it is unavoidable to reduce performance and increase power consumption.

An object of the present invention is to provide an optical scanning device capable of calibrating the strength of a drive signal without any trouble with a simple configuration in view of the problems of the prior art.

The optical scanning apparatus according to the first invention is
Light source and
A scanning mirror that reflects and scans the light from the light source,
A mirror drive unit that can drive the scanning mirror so as to make a rotational simple vibration based on the applied drive signal.
A scanning light detection unit that detects scanning light incident on the first detection position and the second detection position set on both sides within the range of the maximum scanning angle of the scanning light from the scanning mirror.
The time when the scanning light detection unit detects that the scanning light from the scanning mirror is incident on the first detection position and the second detection position due to the simple vibration of the scanning mirror due to the drive signal, and the drive signal. It is characterized by including a calibration unit for calibrating the intensity of the drive signal applied to the mirror drive unit based on the frequency and intensity of the above.

In such an optical scanning device, when the scanning mirror is driven for a long period of time, the maximum scanning angle decreases as the driving time elapses. Therefore, in order to maintain the maximum scanning angle constant, it is required to calibrate the strength of the drive signal so as to gradually increase with the passage of the drive time.

In the first invention, the calibration of the drive signal is constant between the time point at which the scanning light is incident on the first detection position and the second detection position due to the simple vibration of the scanning mirror, the frequency and intensity of the drive signal, and the maximum scanning angle. It is done by paying attention to the fact that there is a relationship between. That is, the calibration unit calibrates the intensity of the drive signal so that the planned constant maximum scanning angle is maintained based on the frequency and intensity of the drive signal at the time of incident.

According to the first invention, as the main hardware configuration, a servo light source or a rear mirror is not required as in the conventional case, and a scanning light detection unit that detects scanning light incident on the first and second detection positions is not required. The strength of the drive signal can be appropriately calibrated only by providing. Therefore, it is possible to appropriately calibrate the strength of the drive signal with a simple configuration while avoiding the complexity of the optical scanning device, the deterioration of performance, and the increase of power consumption.

The optical scanning apparatus according to the second invention is the same as that in the first invention.
The calibration unit includes a maximum scanning angle acquisition unit that acquires the maximum scanning angle based on the time point detected by the scanning light detection unit and the frequency of the drive signal at the time of detection.
A calibration value acquisition unit that obtains a calibration value of the intensity of the drive signal applied to the mirror drive unit based on the maximum scanning angle acquired by the maximum scanning angle acquisition unit and the intensity of the drive signal at the time of detection. It is characterized by having.

According to the second invention, the calibration value for the intensity of the drive signal causing a certain maximum scanning angle has a certain relationship with the maximum scanning angle and the intensity, and the calibration value acquisition unit uses this relationship. Then, the calibration value of the intensity can be obtained from the maximum scanning angle acquired by the maximum scanning angle acquisition unit and the intensity of the drive signal at the time of acquisition.

The optical scanning apparatus according to the third invention is the second invention.
The maximum scanning angle acquisition unit is
The time Δta0 from the time point t4 where the scanning light was once incident to the first detection position to the time point t5 when it was re-incident, and the time Δta1 from the time point t5 where the scanning light was re-incident to the time point t6 when it was further incident.
The time Δtb0 from the time point t1 when the scanning light was once incident to the second detection position to the time point t2 when it was re-incident, and the time Δtb1 from the time point t2 where the scanning light was re-incident to the time point t3 when it was further incident.
The angle (θa + θb) between the scanning light at the time of incident on the first detection position and the scanning light at the time of incident on the second detection position.
It is characterized in that the maximum scanning angle (2A) is acquired based on the frequency ω of the drive signal.

According to the third invention, the maximum scanning angle acquisition unit can easily calculate and obtain the maximum scanning angle (2A) based on the above time Δta0, Δta1, Δtb0, Δtb1, angle (θpa + θPb) and frequency ω. Can be done.

The optical scanning apparatus according to the fourth invention is the same as in any one of the first to third inventions.
The scanning light detection unit is
Optical sensor and
It is characterized by including a light guide unit that guides the scanning light incident on the first detection position and the second detection position to the optical sensor.

According to the fourth invention, it is possible to detect the scanning light incident on the first detection position and the second detection position by using only one optical sensor.

In the fourth aspect of the present invention, the light guide unit is arranged at the first detection position and the second detection position, respectively, and the scanning light from the scanning mirror is transmitted to the optical sensor in the optical scanning device according to the fifth invention. It is characterized by having a reflecting surface that reflects toward it. According to the fifth invention, the light guide unit can be easily configured.

The optical scanning apparatus according to the sixth invention is the fourth invention.
The light guide unit is
Slits provided at the first detection position and the second detection position, respectively.
It is characterized by being composed of an optical element that guides the scanning light from the scanning mirror incident on each slit to the optical sensor.

According to the sixth invention, the light guide portion can be provided by utilizing the space on the side opposite to the incident side of the scanning light of each slit.

The optical scanning apparatus according to the seventh invention is the sixth invention.
The optical scanning device includes a scanning light reflecting mirror that reflects the scanning light from the scanning mirror.
The slit is provided in the scanning light reflection mirror.

According to the seventh invention, the scanning light incident on the first detection position and the second detection position can be detected by utilizing the space behind the scanning light reflection mirror.

The optical scanning apparatus according to the eighth aspect of the invention is characterized in that, in the seventh aspect, the scanning light reflection mirror is a curved surface mirror configured with a curved surface or a scanning light reflection mirror for correcting distortion of the scanning light.

It is a side view which shows the main part of the projector which provided the optical scanning apparatus which concerns on one Embodiment of this invention. It is a perspective view of the optical scanning apparatus of the projector of FIG. It is a perspective view which shows an example of the deflection apparatus in the optical scanning apparatus of FIG. It is a block diagram which shows the structure of the calibration part in the optical scanning apparatus of FIG. It is explanatory drawing for demonstrating the calculation method of the maximum scanning angle in the maximum scanning angle acquisition section of the calibration section of FIG. FIG. 3 is a waveform diagram showing the relationship between the output of the optical sensor of the scanning light detection unit in the optical scanning device of FIG. 2 and the scanning phase. It is a side view which shows the main part of the optical scanning apparatus which concerns on another embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a main part of a projector provided with an optical scanning device according to an embodiment.

As shown in FIG. 1, the projector 1 includes a screen 2 and an optical scanning device 3 that irradiates the screen 2 with scanning light. The optical scanning device 3 includes a light source 4, a deflection device 5 that reflects and deflects the light from the light source 4, and a scanning light reflection mirror 6 that reflects the scanning light from the deflection device 5 toward the screen 2. The scanning light reflection mirror 6 may be a mirror having a flat surface, but may be a curved mirror composed of a curved surface or a correction mirror for correcting distortion of scanning light.

In the following description, a right-handed XYZ-axis Cartesian coordinate system as shown in FIGS. 1 to 3 is used to indicate the direction. The Y-axis is parallel to the first rotation axis 12 of the scanning mirror 7, which will be described later. The XY plane is substantially parallel to the mirror surface of the scanning light reflection mirror 6.

FIG. 2 is a perspective view showing a main part of the optical scanning device 3. As shown in FIG. 2, the scanning light from the scanning mirror 7 toward the scanning light reflection mirror 6 is scanned in the X direction and the Y direction by the scanning mirror 7. As a result, the scanning light reflected by the scanning light reflection mirror 6 performs horizontal scanning and vertical scanning of the screen 2. Image information can be included in the scanning light by turning on / off the output of the light source 4 in accordance with the scanning speed of the scanning light by the deflection device 5.

As the light source 4, a light source that outputs light having coherent properties such as laser light is preferably used. The on / off timing of the light source 4 is controlled so that a desired pattern is projected on the screen 2 in consideration of the on / off timing of the output light and the scanning speed.

The deflection device 5 includes a scanning mirror 7 that reflects light from a light source, and a mirror driving unit 8 that drives the scanning mirror 7. The mirror drive unit 8 can be driven to make a rotational simple vibration by rotating the scanning mirror 7 in the forward and reverse directions based on the applied drive signal.

FIG. 3 shows an example of the deflection device 5. As shown in FIG. 3, in the deflection device 5, the scanning mirror 7 has a oscillating reflective surface 9, and is driven by a mirror driving unit 8 as another part in FIG.

That is, the mirror drive unit 8 includes a first support portion 10 that supports the scanning mirror 7, and first piezoelectric actuators 11a and 11b having one end connected to the scanning mirror 7 and the other end connected to the first support portion 10. .. By piezoelectrically driving the first piezoelectric actuators 11a and 11b, the scanning mirror 7 can be rotated around the first rotation axis 12 with respect to the first support portion 10.

Further, the mirror drive unit 8 includes a second support portion 13 that supports the first support portion 10, and a second piezoelectric actuator 14 having one end connected to the first support portion 10 and the other end connected to the second support portion 13. To prepare for. By piezoelectrically driving the second piezoelectric actuator 14, the first support portion 10 can be swung around the second rotation axis 15 with respect to the second support portion 13.

The deflection device 5 is the same as that described in Japanese Patent Application Laid-Open No. 2013-7779, but the deflection device 5 is not limited to this, and other MEMS mirrors or the like may be used.

The scanning mirror 7 reciprocates while exhibiting a rotational simple vibration due to a horizontal drive signal of a predetermined frequency, for example, 30 kHz applied to the first piezoelectric actuators 11a and 11b of the mirror drive unit 8. As this frequency, the resonance frequency is selected so that scanning can be performed with the maximum scanning angle as large as possible.

In the present specification, the maximum scanning angle is defined as the angle 2A in FIG. 5 described later, from one end to the other where the scanning light from the scanning mirror 7 swings in one cycle of simple vibration. It means the angle to the edge.

The scanning mirror 7 reciprocates by a vertical drive signal having a predetermined frequency, for example, 60 Hz, which is applied to the second piezoelectric actuator 14 of the mirror drive unit. As a result, the screen 2 is scanned by the scanning light at 30 kHz in the horizontal direction and 60 Hz in the vertical direction.

However, when driven by a drive signal having a constant intensity, the maximum scanning angle (maximum runout angle) of the scanning light by the scanning mirror 7 decreases with the lapse of the driving time of the scanning mirror 7. For example, the maximum scanning angle whose initial value was about ± 7.5 ° decreases to about 6.8 ° after driving for 300 hours. Therefore, in order to project the desired pattern on the screen 2 with accurate dimensions, the strength of the drive signal is appropriately calibrated so that the maximum scanning angle does not decrease.

In order to perform this calibration for the horizontal drive signal, the optical scanning device 3 is composed of a scanning light detection unit 16 for detecting scanning light incident on the first detection position P1 and the second detection position P2, and a scanning light detection unit 16. A calibration unit 21 (see FIG. 4) for calibrating the strength of the horizontal drive signal applied to the mirror drive unit 8 based on the detection result is provided. The first detection position P1 and the second detection position P2 are set on both sides within the range of the maximum scanning angle of the scanning light from the scanning mirror 7.

In FIG. 1, both sides of the range of scanning light used for projection onto the screen 2 are indicated by alternate long and short dash lines. The first detection position P1 and the second detection position P2 are set outside this range.

The scanning light detection unit 16 includes an optical sensor 17 and a light guide unit 18 that guides the scanning light indicated by the two-point chain line incident on the first detection position P1 and the second detection position P2 to the optical sensor 17. The light guide unit 18 includes a beam splitter 19 and a light guide mirror 20 that form reflective surfaces arranged at the first detection position P1 and the second detection position P2, respectively.

The beam splitter 19 arranged at the first detection position P1 reflects the scanning light incident on the first detection position P1 at the junction surface B and guides it to the optical sensor 17. The light guide mirror 20 arranged at the second detection position P2 reflects the scanning light incident on the second detection position P2 toward the optical sensor 17. The reflected scanning light travels straight through the beam splitter 19 and passes through the beam splitter 19 and is incident on the optical sensor 17.

The calibration unit 21 is at the time when the scanning light detection unit 16 detects that the scanning light is incident on the first detection position P1 and the second detection position P2 due to the simple vibration of the scanning mirror 7 due to the horizontal drive signal, and the horizontal drive signal. The intensity of the horizontal drive signal applied to the mirror drive unit 8 is calibrated based on the frequency and intensity of.

This calibration corresponds to, for example, the timing at the start of operation of the projector 1 or the timing of each drawing of one frame during operation. However, at the start of driving the mirror drive unit 8, the maximum scanning angle momentarily increases by, for example, about 2.8%, so it is preferable to perform calibration while avoiding such a point.

FIG. 4 shows the configuration of the calibration unit 21. As shown in FIG. 4, the calibration unit 21 has a maximum scanning angle acquisition unit 22 that obtains a maximum scanning angle based on information from the scanning light detection unit 16, and a drive signal strength based on the obtained maximum scanning angle. A calibration value acquisition unit 23 for obtaining a calibration value is provided. The calibration unit 21 can be configured by a microcomputer or the like.

The maximum scanning angle acquisition unit 22 determines the time when the scanning light detection unit 16 detects that the scanning light from the scanning mirror 7 has passed through the first detection position P1 and the second detection position P2, and the frequency of the horizontal drive signal. It has a function to obtain the maximum scanning angle based on the above.

The calibration value acquisition unit 23 is a drive signal to be applied to the mirror drive unit 8 based on the maximum scanning angle obtained by the maximum scanning angle acquisition unit 22 and the strength of the horizontal drive signal when the maximum scanning angle is obtained. Obtain the strength calibration value. This calibration value indicates the horizontal signal strength to be applied to the first piezoelectric actuators 11a and 11b in order to maintain the maximum scanning angle in the horizontal direction (X-axis direction) at the planned value.

The calibration unit 21 instructs the drive signal supply unit 24, which supplies the drive signal to the mirror drive unit 8, to change the intensity of the horizontal drive signal to the calibration value.

FIG. 5 is used to explain a method of calculating the maximum scanning angle in the maximum scanning angle acquisition unit 22. In FIG. 5, the optical sensors 17a and 17b are directly arranged at the first detection position P1 and the second detection position P2 without going through the light guide unit 18, and the scanning light from the scanning mirror 7 is directly emitted from the optical sensor 17a. And 17b are shown.

The angle formed by the scanning light incident on the scanning mirror 7 and the reflected scanning light is defined as a deflection angle θ, and the deflection angle θ of the scanning light when the scanning mirror 7 is in the neutral position is defined as 0 °. Then, the directions of the positions of the optical sensors 17a and 17b represented by the deflection angles θ are defined as the angles θa and θb, respectively.

The angles θa and θb are slightly smaller than 1/2 (= A) of the maximum scanning angle 2A of the scanning light, as shown in FIG. That is, the first detection position P1 and the second detection position P2 are set on both sides within the range of the maximum scanning angle 2A.

Assuming that the time point at which the deflection angle becomes 0 ° for each scanning cycle T of the scanning light from the driven scanning mirror 7 is set as the reference time point S, the scanning light is 1 from one reference time point Sn to the next reference time point Sn + 1. In the scanning cycle T, the light is incident on the optical sensors 17b and 17a twice, respectively.

FIG. 6 shows this situation. The horizontal axis of FIG. 6 is the time axis. In the upper part of FIG. 6, a pulse-shaped detection signal output by the optical sensors 17b and 17a according to the incident of the scanning light is shown. The lower part shows the scanning phase. The scanning phase repeats a change from 0 ° to 360 ° in each scanning cycle T from one reference time point Sn to the next reference time point Sn + 1.

Since the scanning light is incident on the optical sensors 17b and 17a twice in each one scanning cycle T, two pulses Pb1, Pb2 and Pa1 and Pa2 corresponding to each are generated. The scanning range ± A (maximum deflection angle in one scanning period T) of the scanning light can be obtained as follows based on the rising point of these pulses and the frequency ω of the horizontal drive signal. The maximum scanning angle is twice A.

That is, assuming that the scanning mirror 7 is simply vibrated by a horizontal drive signal having a frequency ω and the elapsed time from the reference time point S is t, the deflection angle θ of the scanning light is represented by θ = Asinωt.

Here, after the passage of a certain reference time point Sn, the time from the time point t1 at which the pulse Pb1 first rises to the time point t2 at which the pulse Pb2 rises next is Δtb0, and after the passage of the time point t2, the time has passed the next reference time point Sn + 1. Let Δtb1 be the time until the time point t3 at which the pulse Pb1 first rises. Similarly, after the lapse of the reference time point Sn, the time from the time when the pulse Pa1 first rises (at the time of once incident) t4 to the time when the pulse Pa2 rises next (at the time of re-incident) t5 is Δta0, and the pulse is further increased from the time point t5. Let Δta1 be the time until t6 when Pa1 starts up.

Since Δtb0 + Δtb1 = Δta0 + Δta1 is equal to one scan period T,
ω = 2π / T = 2π / (Δtb0 + Δtb1) = 2π / (Δta0 + Δta1)
Is established.

Further, Δtb1 is the time from the time point t2 toward the time point t3 toward the optical sensor 17a, past the next reference time point Sn + 1, and the time point t3 at which the pulse Pb1 rises again. Therefore, the time for scanning from the reference time point Sn to the center of the optical sensor 17b, that is, the second detection position P2, that is, the time Δtb for the scanning light to scan the angle θb indicating the position of the optical sensor 17b described above is set.
Δtb = (1/2) * (Δtb1-T / 2)
= (1/2) * (Δtb1-π / ω)
= (1/4) * (Δtb1-Δtb0)
Will be. Note that Δtb0 is the time from the time point t1 at which the pulse Pb1 rises to the time t2 at the time when the pulse Pb2 rises next, but the time from the rise of the pulse Pb1 to the center position of the pulse Pb1 is from the rise of the pulse Pb2 to the pulse. It is substantially equal to the time to the center of Pb2. Therefore, Δtb0 is substantially equal to the time from when the scanning light is incident on the second detection position P2 until when the scanning light is then incident on the second detection position P2. The same applies to Δtb1.

Therefore,
θb / A = sin {ω * (1/4) * (Δtb1-Δtb0)}
And likewise
θa / A = sin {ω * (1/4) * (Δta1-Δta0)}
Will be. Since θb + θa is a set value due to the arrangement of the optical sensors 17a and 17b, the scanning range ± A is
A = (θb + θa) / [sin {ω * (1/4) * (Δtb1-Δtb0)} + sin {ω * (1/4) * (Δta1-Δta0)}]
Will be.

The maximum scanning angle acquisition unit 22 easily calculates and obtains the maximum scanning angle (2A) based on the time Δta0, Δta1, Δtb0, Δtb1, angle (θa + θb), and frequency ω using this equation. be able to.

In the configuration of the present embodiment, the scanning light from the light source 4 is reflected by the scanning mirror 7 of the deflection device 5, further reflected by the scanning light reflection mirror 6, and incident on the screen 2. During this time, the scanning mirror 7 is based on a horizontal drive signal having a frequency (horizontal scanning frequency) of, for example, about 30 kHz applied to the first piezoelectric actuators 11a and 11b from the drive signal supply unit 24, and the scan mirror 7 is connected to the first rotation axis 12. Simple vibration around.

That is, the optical scanning device 3 scans with scanning light at this horizontal scanning frequency. For this horizontal scanning frequency, the resonance frequency of the vibration system is selected so that the maximum scanning angle as large as possible can be obtained. The strength of the horizontal drive signal is set so that a horizontal scanning range ± A including the first detection position P1 and the second detection position P2 can be obtained.

In parallel with this, in the scanning mirror 7, the deflection angle of the scanning light is signaled based on the vertical driving signal having a vertical scanning frequency of, for example, about 60 Hz applied to the second piezoelectric actuator 14 from the drive signal supply unit 24. It is driven in proportion to the intensity (linear mode). It may be driven so as to make a simple vibration around the second rotation axis 15.

During this time, the scanning light output from the light source 4 is turned on / off (modulated) at the timing synchronized with the above-mentioned horizontal frequency and vertical frequency. As a result, drawing is performed on the screen 2 according to this modulation.

However, as described above, the maximum scanning angle of the scanning light by the scanning mirror 7 decreases with the lapse of the driving time of the scanning mirror 7. Therefore, the strength of the horizontal drive signal is calibrated so that a pattern of accurate dimensions is projected on the screen 2 at the start of operation of the projector 1 or at each calibration such as every drawing of one frame.

That is, at the time of each calibration, the maximum scanning angle acquisition unit 22 of the calibration unit 21 reaches t1 to t6 when the scanning light detection unit 16 detects that the scanning light is incident on the optical sensors 17a and 17b. Based on this, the maximum scanning angle 2A is acquired as described above. The calibration value acquisition unit 23 of the calibration unit 21 acquires the calibration value of the strength of the horizontal drive signal based on the obtained maximum scanning angle 2A.

The acquisition of this calibration value can be performed, for example, as follows. That is, the calibration values of the strength of the horizontal drive signal and the strength of the horizontal drive signal corresponding to various values of the maximum scanning angle 2A are acquired in advance as the strength-maximum scanning angle correspondence table. Then, at the time of calibration, the calibration value of the horizontal drive signal corresponding to the obtained maximum scanning angle 2A is acquired with reference to this table.

The calibration unit 21 notifies the drive signal supply unit 24 of the obtained calibration value. The drive signal supply unit 24 changes the set value of the strength of the horizontal drive signal supplied to the mirror drive unit 8 to the notified calibration value. This completes the calibration of the strength of the horizontal drive signal.

The vertical scanning is not performed at the resonance frequency, but is performed so that the deflection angle of the scanning light changes linearly with respect to the intensity of the vertical drive signal as described above. However, the strength of the vertical drive signal can also be calibrated in the same manner as in the case of the horizontal drive signal by using a sine wave as the drive signal for calibration and simply vibrating the scanning mirror 7.

As described above, according to the present embodiment, the strength of the drive signal can be appropriately calibrated only by providing the scanning light detection unit 16 that detects the scanning light incident on the first and second detection positions P1 and P2. can. Therefore, since the main hardware configuration does not require a servo light source or rearview mirror as in the past, it can be driven with a simple configuration while avoiding the complexity of the optical scanning device, deterioration of performance, and increase in power consumption. The signal strength can be properly calibrated.

FIG. 7 shows a main part of a projector provided with an optical scanning device according to another embodiment of the present invention. The light guide portion 18b of the projector 1b is provided from the slits 25 provided at the first detection position P1 and the second detection position P2 set on the scanning light reflection mirror 6b, and the scanning mirror 7 incident on each slit 25. It is composed of an optical element that guides the scanning light of the above to the optical sensor 17. The optical sensor 17 is provided at a position some distance from the scanning light reflection mirror 6 in the direction behind the scanning light reflection mirror 6.

As the optical element that guides the scanning light to the optical sensor 17, a diffuser plate 26 provided on the back surface side of each slit 25 in the scanning light reflection mirror 6 is used here. The optical element may be configured by using a reflection element or a transmission element.

By providing each slit 25 and the diffuser plate 26 in a vertically long shape corresponding to the range of vertical scanning, the maximum scanning angle in horizontal scanning can be obtained at any time point in the scanning period of one frame. Other configurations and operations are the same as in the case of the embodiments of FIGS. 1 to 6.

According to the present embodiment, the scanning light incident on the first detection position P1 and the second detection position P2 can be detected by utilizing the space behind the scanning light reflection mirror 6.

Although the embodiments of the present invention have been described above, the present invention is not limited thereto. For example, the optical scanning device of the present invention can be applied not only to a projector but also to a head-mounted display, a headlamp, a scanning distance measuring device, and the like.

Further, the scanning light reflection mirror may not be provided, or a correction lens or the like may be used instead of the scanning light reflection mirror. When the scanning light reflection mirror is not provided, the reflecting surface and the slit are not obstructed by the scanning light directly emitted from the scanning mirror to the screen at the first and second detection positions set between the scanning mirror and the screen. A frame-shaped holding member for holding the light can be adopted.

Further, the maximum scanning angle is not calculated, but is a correspondence table between the frequency of the driving signal at the time of detection of the scanning light by the scanning light detection unit obtained in advance by the calculation or the like and the frequency of the driving signal at the detection time, and the maximum scanning angle. It may be acquired based on.

1, 1b ... Projector, 2 ... Screen, 3, 3b ... Optical scanning device, 4 ... Light source, 5 ... Deflection device, 6, 6b ... Scanning light reflection mirror, 7 ... Scanning mirror, 8 ... Mirror drive unit, 9 ... Reflective surface, 10 ... 1st support, 11a, 11b ... 1st piezoelectric actuator, 12 ... 1st rotation axis, 13 ... 2nd support, 14 ... 2nd piezoelectric actuator, 15 ... 2nd rotation axis, 16, 16b ... Scanning light detection unit, 17, 17a, 17b ... Optical sensor, 18, 18b ... Light guide unit, 19 ... Beam splitter, 20 ... Light guide mirror, 21 ... Calibration unit, 22 ... Maximum scanning angle acquisition unit, 23 ... Calibration Value acquisition unit, 24 ... drive signal supply unit, 25 ... slit, 26 ... diffuser plate, P1 ... first detection position, P2 ... second detection position.

Claims (4)

Light source and
A scanning mirror that reflects and scans the light from the light source,
A scanning light reflection mirror that reflects the scanning light from the scanning mirror and projects a desired pattern in the direction in which the scanning light is reflected.
A mirror drive unit that can drive the scanning mirror so as to make a rotational simple vibration based on the applied drive signal.
A scanning light detection unit that detects the scanning light incident on the first detection position and the second detection position set on both sides within the range of the maximum scanning angle of the scanning light from the scanning mirror.
The time when the scanning light detection unit detects that the scanning light from the scanning mirror is incident on the first detection position and the second detection position due to the simple vibration of the scanning mirror due to the drive signal, and the drive signal. A calibration unit for calibrating the intensity of the drive signal applied to the mirror drive unit based on the frequency and intensity of the mirror drive unit is provided .
The scanning light detection unit is provided at the optical sensor and the first detection position and the second detection position set on the scanning light reflection mirror, respectively, and the scanning light reflection mirror is used as the reflection side of the scanning light. An optical scanning device comprising a slit penetrating from the front side to the back side of the above, and an optical element disposed on the back side of the scanning light reflection mirror and guiding the light passing through the slit to the optical sensor . The calibration unit includes a maximum scanning angle acquisition unit that acquires the maximum scanning angle based on the time point detected by the scanning light detection unit and the frequency of the drive signal at the time of detection.
A calibration value acquisition unit that obtains a calibration value of the intensity of the drive signal applied to the mirror drive unit based on the maximum scanning angle acquired by the maximum scanning angle acquisition unit and the intensity of the drive signal at the time of detection. The optical scanning apparatus according to claim 1, further comprising. The maximum scanning angle acquisition unit is
The time Δta0 from the time point t4 where the scanning light was once incident to the first detection position to the time point t5 when it was re-incident, and the time Δta1 from the time point t5 where the scanning light was re-incident to the time point t6 when it was further incident.
The time Δtb0 from the time point t1 when the scanning light was once incident to the second detection position to the time point t2 when it was re-incident, and the time Δtb1 from the time point t2 where the scanning light was re-incident to the time point t3 when it was further incident.
The angle (θa + θb) between the scanning light at the time of incident on the first detection position and the scanning light at the time of incident on the second detection position.
The optical scanning apparatus according to claim 2, wherein the maximum scanning angle (2A) is acquired based on the frequency ω of the driving signal. The optical scanning apparatus according to any one of claims 1 to 3, wherein the scanning light reflection mirror is a curved mirror composed of a curved surface or a scanning light reflection mirror that corrects distortion of the scanning light. ..

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