The present invention relates generally to an electronic apparatus (e.g., a laser range finder).
As a sensor for sensing an obstacle when a robot is autonomously moving or a sensor for sensing a person, there is, for example, a laser range finder (LRF).
Conventional laser range finders perform measurement of a time from when a laser light is output to when a reflected light, which is the laser light striking an object and being reflected, returns and calculates a distance to the object from a measurement result. The laser range finders, by changing a direction in which the laser light is output in a horizontal direction and a vertical direction, perform measurement of the distance to the object in an entirety of a range where measurement of the distance is performed (referred to hereinbelow as “scanning range”).
The conventional laser range finders comprise, for example, a laser diode (LD) that outputs the laser light, a mirror that adjusts an output direction of the laser light, a light-receiving element that receives the reflected light from the object, and a signal processing unit. As the minor that adjusts the output direction of the laser light, there is, for example, a mirror installed to a rotation mechanism, a polygon minor, a MEMS (Micro Electro Mechanical System) mirror, and the like. The signal processing unit outputs an output signal that causes the laser diode to output the laser light and accepts a light-receiving signal from the light-receiving element. The signal processing unit measures the distance to the object from a difference between a phase of the laser light output from the laser light and a phase of the reflected light received by the light-receiving element.
To precisely perform measurement of the distance by the conventional laser range finders, more accurately seeking an angle in the horizontal direction and an angle in the vertical direction of when the object is detected is desired.
As a method of seeking the angle in the vertical direction, there is disclosed, for example, a method that adds a light-receiving element to each end portion of a scanning range in a vertical direction and seeks a range of an amplitude from a timing at which the light-receiving elements detect a laser light (for example, see Patent Literature 1).
[Patent Literature 1] Japanese Unexamined Patent Application Publication No. 2005-77288
However, in the method described in Patent Literature 1, because a plurality of light-receiving elements needs to be provided, manufacturing costs increase.
A laser range finder according to one or more embodiments can more accurately seek a direction in which a laser light is output while suppressing manufacturing costs from increasing.
In one aspect, a laser range finder according to one or more embodiments of the present invention may comprise: a light source that outputs a laser light; a scanning unit that changes a direction in which the laser light is output; a reflective member having a reflective surface where a distance of an optical path from the light source to a position to which the laser light is irradiated changes according to the direction in which the laser light is output; a light-receiving unit that receives a first reflected light that is the laser light reflected by the reflective member; and a signal processing unit that calculates a distance from the light source to the reflective surface using the first reflected light received by the light-receiving unit and calculates the direction in which the laser light is output using this distance.
According to one or more embodiments, the laser range finder of the above configuration may comprise the reflective member having the reflective surface where the distance of the optical path from the light source (distance from the scanning unit) changes according to the direction in which the laser light is output. Therefore, for example, the direction in which the laser light is output can be sought by measuring the distance of the optical path between the light source and the reflective surface. Moreover, a calculation method of the distance of the optical path between the light source and the reflective surface is the same as that of a distance of an optical path between the light source and an object. Therefore, for example, a device configuration can be simplified.
According to one or more embodiments, the laser range finder of the above configuration includes a reflective member that is inexpensive compared to a light-receiving element and the like. As a result, for example, manufacturing costs can be suppressed from increasing.
According to one or more embodiments, for example, the scanning unit may be oriented to be on the optical path of the laser light, and the reflective surface may be a rectangular plane and may be disposed so a distance from the scanning unit to one short side of the rectangle is smaller than a distance from the scanning unit to the other short side of the rectangle.
According to one or more embodiments, with the laser range finder of the above configuration, the reflective surface may be rectangular. Therefore, for example, a shape of the reflective member can be made to be a simple shape.
According to one or more embodiments, the reflective member may be disposed to cause a line connecting the scanning unit and an end portion of the reflective member to parallel a long side of the reflective surface.
The laser range finder of the above configuration may be disposed to cause the line connecting the scanning unit and the end portion of the reflective member to parallel the long side of the reflective surface. Therefore, for example, it may be possible to make the laser light straddle the reflective surface substantially the same across every angle in a first direction. Thus, it may be possible to favorably perform calculation of an angle in a second direction.
According to one or more embodiments, the reflective member may be disposed more on an inner side than a line connecting the scanning unit and an opening portion of the casing.
With the laser range finder of the above configuration, the reflective member is disposed more on the inner side than the line connecting the scanning unit and the opening portion of the casing. Therefore, for example, it may be possible to suppress an influence of outside light.
According to one or more embodiments, the scanning unit may change the direction in which the laser light is output to a first direction and a second direction that intersects the first direction, and in a state where an angle in the first direction is maintained, change an angle in the second direction, and, afterward, by changing the angle in the second direction, two-dimensionally change the direction in which the laser light is output. The light-receiving unit may further receive a second reflected light, which is the laser light reflected by an object, and the signal processing unit, in a state where an angle in the second direction of when the light-receiving unit receives the second reflected light is maintained, calculate a distance from the light source to the reflective member using the first reflected light and, using this distance, calculate an angle in the first direction of when the first reflected light is received as an angle of the laser light in the first direction of when the second reflected light is received.
With the laser range finder of the above configuration, in the state where the angle in the first direction is maintained, the direction in which the laser light is output is changed to the second direction. Therefore, for example, it may be possible for the light-receiving unit to receive the first reflected light from the reflective member in a state where an angle in the first direction of when the object is detected is maintained. That is, an angle in the first direction from the first reflected light the light-receiving unit detects in the state where the angle in the first direction of when the object is detected is maintained is the same as the angle in the first direction of when the object is detected. Therefore, for example, the laser range finder of the above configuration can seek the angle in the first direction of when the object is detected by seeking the angle in the first direction from the first reflected light detected by the light-receiving unit.
According to one or more embodiments, the signal processing unit may calculate the distance based on a phase difference between a phase of the laser light and a phase of the light received by the light-receiving unit.
According to one or more embodiments, the signal processing unit may calculate an angle in the horizontal direction of when the object is detected using a timing at which the light-receiving unit receives the first reflected light and a time when the object is detected, the signal processing unit may acquire a timing at which the object is detected, detect an interval between the timing at which the light-receiving unit receives the first reflected light and a time when the laser light passes through the reflective member, calculate a sine wave indicating displacements in a direction of the laser light relative to time using this interval and a direction in which the reflective member is disposed, and calculate the direction of the laser light using the sine wave and the timing at which the object is detected.
With the laser range finder of the above configuration, for example, it may be possible to precisely calculate the angle in the second direction.
An electronic apparatus according to one or more embodiments may comprise a light source that outputs a laser light; a scanning unit that scans the laser light; a reflective member having a reflective surface that reflects the laser light; a light-receiving unit that receives a first reflected light reflected by the reflective member; and a signal processing unit that calculates a distance from the light source to the reflective surface using the first reflected light and determines a direction in which the laser light is output using this distance.
A method according to one or more embodiments may comprise scanning a laser light output by a light source; reflecting, with a reflective surface of a reflective member, the laser light; calculating a distance from the light source to the reflective surface using the reflected light; and determining, based on the calculated distance, a direction in which the laser light is output.
Embodiments of the present invention cause the direction in which the laser light is output to be more accurately sought while suppressing the manufacturing costs from increasing.
Embodiments according to the present invention will be described in detail below using the drawings. Each drawing does not necessarily strictly illustrate each dimension, each dimension ratio, and the like.
Numerical values, shapes, materials, components, disposition positions and connection modes of the components, steps, orders of the steps, and the like illustrated in the one or more embodiments of the present invention below are but examples and are not intended to limit the present invention.
(An Example)
A laser range finder of one or more embodiments of an example will be described based on
(1. Configuration of Laser Range Finder According to One or More Embodiments)
One or more embodiments of the example will be described with a monocular laser range finder 10 as an example but is not limited thereto. A lens through which a laser light output to an object is output and a lens that receives a reflected light from the object may be configured separately.
As illustrated in
Furthermore, the laser range finder 10 comprises, inside the casing 11, a modulated signal output unit 20, the laser diode 21, the perforated mirror 22, the MEMS mirror 23, a mirror drive unit 24, the light-receiving unit 25, and a signal processing unit 30.
(1-1. Modulated Signal Output Unit, Laser Diode, and Perforated Mirror)
The modulated signal output unit 20 generates a modulated signal for causing the laser diode 21 to output the laser light.
The laser diode 21 is an example of a light source that outputs the laser light, and it outputs the laser light according to the modulated signal output from the modulated signal output unit 20. The laser diode 21 is disposed inside the casing 11 and outputs the laser light toward the MEMS mirror 23.
The laser light output from the laser diode 21 passes through holes of the perforated mirror 22 and is reflected at the MEMS mirror 23. The laser light, after being reflected at the MEMS mirror 23, is output toward the outside from the object lens 12 provided in an opening portion of the casing 11 of the laser range finder 10. Alternatively, the laser light, after being reflected at the MEMS mirror 23, is reflected by the reflective member 27 provided in the casing 11 of the laser range finder 10.
A first reflected light, which is the laser light reflected by an object 40, is condensed in the object lens 12 provided in the opening portion of the casing 11. The first reflected light condensed by the object lens 12 is reflected toward the perforated mirror 22 at the MEMS mirror 23. The first reflected light is further reflected toward the light-receiving unit 25 at the perforated mirror 22. Moreover, a second reflected light reflected by the reflective member 27 is reflected toward the perforated mirror 22 at the MEMS minor 23. The first reflected light and the second reflected light reflected by the perforated minor 22 are received by the light-receiving unit 25.
As illustrated in
For example, the perforated mirror 22 includes a plate-like member having a reflective surface that reflects the light from the MEMS mirror 23 toward the light-receiving unit 25. In this plate-like member, a hole is formed that lets the laser light output from the laser diode 21 pass through as-is. Because the laser light that passes through the perforated mirror 22 is a focused light, it is possible to form a surface area of a cross section of the hole to be extremely small. Due to the reflected light from the object 40 being weak in intensity compared to the laser light, to secure a surface area of the reflective surface, a cross-sectional area of the hole small may be made.
(1-2. MEMS Minor and Minor Drive Unit)
The MEMS (Micro Electro Mechanical System) mirror 23 is an example of a scanning unit that scans the laser light output from the laser diode 21. The MEMS minor 23 changes a direction in which the laser light output from the laser diode 21 is output. The MEMS minor 23 is configured forming a minor that is a microscopic mechanical component on a silicon substrate forming an electronic circuit.
For the sake of description, the x-axis direction is described as a horizontal direction and the y-axis direction is described as a vertical direction, but these directions are directions of when the laser range finder 10 is used in an ideal posture, and the x-axis direction does not necessarily need to be parallel to the horizontal direction. Similarly, the y-axis direction does not necessarily need to be parallel to the vertical direction.
As illustrated in
The mirror portion 23a has a reflective surface that reflects the laser light output from the laser diode 21 and has a mechanism that rocks the reflective surface in the x-axis direction around an axis AY passing through a central portion of the mirror portion 23a. The mirror portion 23a is horizontally driven by a resonant frequency by a voltage supplied from the mirror drive unit 24. By this, the MEMS mirror 23 can horizontally scan at a high speed.
The mirror rocker 23b, by rocking an entirety of the mirror portion 23a around an axis AX orthogonal to the axis AY, drives the mirror unit 23a in the y-axis direction. The mirror rocker 23b vertically drives the mirror portion 23a by one line each time the mirror portion 23a rocks once in the x-axis direction. That is, vertical driving by the mirror rocker 23b is low-speed compared to horizontal driving in the mirror portion 23a.
A scanning range of the MEMS mirror 23 in the x-axis direction and the y-axis direction is designed to be slightly greater than a size of the opening portion formed in the upper surface of the casing 11.
The mirror drive unit 24 includes a rocker drive unit 24a and a vibrator drive unit 24b.
The rocker drive unit 24a generates a vertical drive current for vertically driving the mirror rocker 23b and outputs this to the mirror rocker 23b. Moreover, the rocker drive unit 24a accepts a width of the scanning range in the y-axis direction from a subtraction unit 36 of the signal processing unit 30 that will be described below and adjusts an amplitude of the vertical drive current according to this width.
The vibrator drive unit 24b generates a horizontal drive current for horizontally driving the mirror portion 23a and outputs this to the mirror portion 23a. Moreover, the vibrator drive unit 24b accepts an angle in the x-axis direction of when the object 40 is detected from a second angle calculation unit 37 of the signal processing unit 30 that will be described below and adjusts an amplitude of the horizontal drive current according to this angle in the x-axis direction.
As illustrated in
The scanning range in the x-axis direction changes due to a temperature change, aging deterioration, or the like. That is, as illustrated in
For example, as illustrated in
(1-3. Light-Receiving Unit)
The light-receiving unit 25 includes a light-receiving element that receives the light from the perforated mirror 22. The light-receiving element is provided with a light-receiving surface configured by a glass surface. The light-receiving unit 25 receives the second reflected light, which is the laser light reflected by the object 40 and modulated, and the first reflected light, which is the laser light reflected by the reflective member 27. With the light-receiving unit 25, the greater an intensity of the received light, the greater a voltage value of an output signal output to a distance calculation unit 31 of the signal processing unit 30.
Because the laser light from the MEMS mirror 23 is reflected and scattered at the object 40, an intensity of the second reflected light that returns into the laser range finder 10 becomes extremely small compared to that of the laser light. As a result, an amp may be provided at a subsequent stage of the light-receiving unit 25 and a previous stage of the signal processing unit 30, and the output signal of the light-receiving unit 25 may be amplified.
(1-4. Reflective Member)
The reflective member 27 is a member having a reflective surface 28 where a distance of an optical path from the laser diode 21 to a position to which the laser light is irradiated according to the direction in which the laser light is output—according to one or more embodiments of the example, a distance from the MEMS mirror 23—changes. The reflective surface 28 reflects the laser light output from the laser diode 21. As illustrated in
As illustrated in
The reflective member 27 is disposed so a long side is substantially parallel to the axis A1. As illustrated in
(1-5. Signal Processing Unit)
As illustrated in
The distance calculation unit 31 calculates the distance from the laser diode 21 to the object 40 and the distance from the laser diode 21 to the reflective member 27.
For example, the distance calculation unit 31 calculates a first distance from the laser diode 21 to the reflective member 27 using the first reflected light received by the light-receiving unit 25 and a second distance from the laser diode 21 to the object 40 using the second reflected light received by the light-receiving unit 25. A calculation method of the first distance and a calculation method of the second distance are the same.
To calculate the distance from the laser diode 21 to the object 40, for example, a time from when the laser light is output from the laser diode 21 to when the first reflected light is received by the light-receiving unit 25 is calculated based on a phase difference between a phase of the laser light output from the laser diode 21 and the first reflected light received by the light-receiving unit 25. The calculated time is a time it takes for the laser light to travel from the laser diode 21 to the object 40 and back. By multiplying the speed of light to a half of this time, the distance can be calculated. Similarly, the distance from the laser diode 21 to the reflective member 27 is calculated based on a phase difference between the phase of the laser light output from the laser diode 21 and the second reflected light received by the light-receiving unit 25.
Furthermore, calculation of the distance by the distance calculation unit 31 is performed by a timing of a control clock (timing of a count of a counter). A count value of the counter corresponds to time.
The reflective member detection unit 32 determines whether the distance calculated by the distance calculation unit 31 is the distance to the object 40 or the distance to the reflective member 27. The reflective member detection unit 32, in a situation where the distance is greater than a threshold Thr, determines the distance to be the distance to the object 40 and outputs this distance to the outside. The reflective member detection unit 32, in a situation where the distance is the threshold Thr or less, determines the distance to be the distance to the reflective member 27 and outputs this distance to the first angle calculation unit 33. The threshold Thr is, for example, a distance from the laser diode 21 to the opening portion of the casing 11. The threshold Thr is set to a value greater than a distance between the laser diode 21 and the reflective surface 28 of the reflective member 27 and smaller than a distance from the laser diode 21 to a surface on an outer side of the object lens 12.
The first angle calculation unit 33 acquires the distance between the MEMS minor 23 and the reflective surface 28 from the reflective member detection unit 32 and uses this distance to calculate (determines) the direction in which the laser light is output. According to one or more embodiments of the example, the first angle calculation unit 33 calculates the angle θVd in the y-axis direction of when the object 40 is detected. The first angle calculation unit 33 includes a storage unit that stores a relational expression between the distance and the angle in the y-axis direction of when the object 40 is detected. Instead of a relational expression, a table or the like indicating a relationship between the distance and the angle in the y-axis direction of when the object 40 is detected may be stored.
The minimum value detection unit 34 detects a minimum value (local minimum value) θVmin from a calculation result of the angle in the y-axis direction in the first angle calculation unit 33. The maximum value detection unit 35 detects a maximum value (local maximum value) θVmax from the calculation result of the angle in the y-axis direction in the first angle calculation unit 33. The subtraction unit 36 subtracts the minimum value θVmin detected in the minimum value detection unit 34 from the maximum value θVmax detected in the maximum value detection unit 35 and outputs this result to the rocker drive unit 24a of the minor drive unit 24.
The second angle calculation unit 37 calculates the angle in the x-axis direction of when the object 40 is detected using a timing of the light received by the light-receiving unit 25.
(2. Operations of Signal Processing Unit)
Operations of the signal processing unit 30 will be described using
(2-1. Distance Measurement Process)
As described above, the distance calculation unit 31 calculates the second distance, from the laser diode 21 to the object 40, or the first distance, from the laser diode 21 to the reflective member 27 (S11).
From the phase difference PhD in a period when the first reflected light reflected by the reflective member 27 is being received, the first distance between the laser diode 21 and the reflective surface 28 is calculated. Moreover, from the phase difference PhD in a period when the second reflected light reflected by the object 40 is being received, the second distance from the laser diode 21 to the object 40 is calculated. However, the first distance or the second distance is calculated by the same algorithm, and it is not distinguished whether a computation result is the first distance or the second distance.
The reflective member detection unit 32 determines whether the calculated distance is the distance to the object 40 or the distance to the reflective member 27 (S12).
In one or more embodiments of the example, the reflective member detection unit 32, in a situation where the calculated distance is greater than the threshold Thr, determines the calculated distance to be the distance to the object 40 and, in a situation where the calculated distance is the threshold Thr or less, determines the calculated distance to be the distance to the reflective surface 28. As described above, the threshold Thr is, for example, the distance from the laser diode 21 to the opening portion of the casing 11.
The reflective member detection unit 32, in the situation where the calculated distance is determined to be the distance to the object 40 (distance to the object 40 of S12), outputs the calculation result to the outside (S13). Moreover, the reflective member detection unit 32 outputs a time when the object 40 is detected to the second angle calculation unit 37 and the first angle calculation unit 33.
For example, in the situation of
The reflective member detection unit 32, in the situation where the calculated distance is determined to be the distance to the reflective surface 28 (distance to the reflective surface of S12), outputs the calculation result of the distance and a time when this distance is measured to the second angle calculation unit 37 and the first angle calculation unit 33.
For example, in the situation of
The distance r1 of the times t1 and t3 is a distance where the first distance from the MEMS minor 23 to the reflective member 27 becomes the smallest. The distance r2n of the times t(1+5n) and t(3+5n) is a distance where the first distance from the MEMS mirror 23 to the reflective member 27 becomes the greatest.
(2-2. Second Angle Calculation Process (Angle of X-Axis Direction))
The second angle calculation unit 37, when the calculation result of the distance is output from the reflective member detection unit 32, executes the second angle calculation process, which calculates the angle in the x-axis direction of when the object 40 is detected (S20).
Because the laser light folds back in the x-axis direction straddling the reflective surface 28, as illustrated in
The second angle calculation unit 37 seeks a timing at which the light-receiving unit 25 receives the first reflected light from the calculation result of the distance illustrated in
The second angle calculation unit 37 seeks an interval Δt between times when the two local minimum values appear from the calculation result of the distance illustrated in
From these conditions, the second angle calculation unit 37 seeks the graph of the sine wave illustrating the relationship between angle and time. For example, the second angle calculation unit 37 seeks a sine wave where an interval of an intersection with a straight line of an angle θ0 (length of a portion including the local minimum value) becomes the interval Δt.
A derivation method of the sine wave will be described below for, for the sake of description, as illustrated in
As illustrated in
The second angle calculation unit 37 sends the calculation result of the angle (θH1 or θH2) as feedback to the vibrator drive unit 24b of the minor drive unit 24 (S23). The vibrator drive unit 24b adjusts a horizontal drive signal output to the MEMS mirror 23 according to a feedback result so a scanning angle of the laser light in the x-axis direction, that is, a change amount per unit time of the angle of the laser light in the x-axis direction becomes constant.
By configuring in this manner, even in a situation where the deflection width of the laser light in the x-axis direction changes, it may be possible to accurately seek the angle in the x-axis direction of when the object 40 is detected. Moreover, it becomes possible to perform adjustment of the deflection width of the laser light in the x-axis direction.
(2-3. First Angle Calculation Process)
The first angle calculation unit 33, the minimum value detection unit 34, the maximum value detection unit 35, and the subtraction unit 36 execute the first angle calculation process that calculates the angle of the laser light in the y-axis direction of when the object 40 is detected and a deflection width of the laser light in the y-axis direction (S30).
The first angle calculation unit 33 calculates the angle of when the object 40 is detected from a relationship stored in advance between the distance to the reflective surface 28 and the angle (S31). The first angle calculation unit 33, in a state where the angle in the y-axis direction of when the object 40 is detected is maintained, uses the first reflected light of when the laser light straddles the reflective surface 28 to calculate the distance from the laser diode 21 to the reflective surface 28. Moreover, the first angle calculation unit 33 uses the calculated distance to seek an angle of the first reflected light in the y-axis direction from the relationship stored in advance between the distance to the reflective surface 28 and the angle. As described above, the angle of the first reflected light in the y-axis direction and the angle in the y-axis direction of when the object 40 is detected are the same. Therefore, by seeking the angle of the first reflected light in the y-axis direction, the angle in a y-direction of when the object 40 is detected can be calculated.
The minimum value detection unit 34, the maximum value detection unit 35, and the subtraction unit 36 derive a range of a deflection angle of the laser light in the y-axis direction (S32). Calculation of the deflection angle is performed at each two-dimensional scanning Specifically, first, by the minimum value detection unit 34, a minimum value is detected from the calculation result of the angle in the y-axis direction in the first angle calculation unit 33. Similarly, by the maximum value detection unit 35, a maximum value (local maximum value) is detected from the calculation result of the angle in the y-axis direction in the first angle calculation unit 33.
Furthermore, by the subtraction unit 36, the minimum value detected in the minimum value detection unit 34 is subtracted from the maximum value detected in the maximum value detection unit 35. A computation result of the subtraction unit 36 becomes the deflection width of the laser light in the y-axis direction.
The subtraction unit 36 sends the calculation result of the deflection width of the laser light in the y-axis direction as feedback to the rocker drive unit 24a of the mirror drive unit 24 (S33). The rocker drive unit 24a adjusts a vertical drive signal output to the MEMS mirror 23 according to a feedback result so a scanning angle of the laser light in the y-axis direction, that is, a change amount per unit time of an angle of the laser light in the y-axis direction becomes constant.
By configuring in this manner, even in a situation where the deflection width of the laser light in the y-axis direction changes, it may be possible to accurately seek the angle in the x-axis direction of when the object 40 is detected. Moreover, it may be possible to perform adjustment of the deflection width of the laser light in the y-axis direction.
(3. Effects)
The laser range finder 10 according to one or more embodiments of the example comprises the reflective member 27 having the reflective surface 28 where the distance from the laser diode 21 to the reflective surface 28 changes according to the angle of the laser light in the y-axis direction; therefore, it may be possible to seek the direction in which the laser light is output (angle in the y-axis direction) by seeking the distance from the laser diode 21 to the reflective member 27.
The laser range finder 10 according to one or more embodiments of the example comprises the relational expression or table that indicates the relationship between the distance from the MEMS minor 23 to the reflective surface 28 and the angle in the y-axis direction; therefore, the direction in which the laser light is output (angle in the y-axis direction) can be sought by a simple method.
The laser light is changed in the x-axis direction in the state where the angle in the y-axis direction is maintained; therefore, by using the first reflected light of the laser light that straddles the reflective member 27 in the state where the angle in the y-axis direction of when the object 40 is detected is maintained, the angle in the y-axis direction of when the object 40 is detected can be sought.
Furthermore, it becomes possible to seek the angle in the x-axis direction from the timing at which the first reflected light reflected by the reflective member 27 is received by the light-receiving unit 25.
The laser range finder 10 according to one or more embodiments of the example can use a conventional configuration for configurations other than that of the reflective member 27, and the reflective member 27 can be provided comparatively inexpensively. Therefore, manufacturing costs can be suppressed from increasing.
(4. Modified Example)
One or more embodiments of a modified example will be described using
In one or more embodiments of the modified example, a situation will be described where a shape of the reflective member 27 is different from that of the above one or more embodiment of the example.
The reflective member 27A illustrated in
The reflective member 27 illustrated in
With any of
The laser range finder according to one or more embodiments of the present invention is described above, but the present invention is not limited to those embodiments.
According to one or more embodiments, for example, the MEMS mirror 23 (scanning unit) may be a perforated mirror.
The present invention may be applied, instead of a monocular laser range finder, as a laser range finder where a lens through which the laser light output to the object 40 and a lens that receives the reflected light from the object 40 are configured separately.
Furthermore, the above one or more embodiments of the example and the above one or more embodiments of another example may be combined.
The above one or more embodiments of the example is applicable to a laser range finder that detects a distance of an object.
Although the disclosure has been described with respect to only a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that various other embodiments may be devised without departing from the scope of the present invention. Accordingly, the scope of the invention should be limited only by the attached claims.
10 laser range finder; 11 casing; 12 object lens; 20 modulated signal output unit; 21 laser diode; 22 perforated mirror; 23 MEMS mirror; 23a mirror portion; 23b mirror rocker; 24 mirror drive unit; 24a rocker drive unit; 24b vibrator drive unit; 25 light-receiving unit; 27, 27A, 27B, 27C reflective member; 28, 28a, 28b, 28c reflective surface; 30 signal processing unit; 31 distance calculation unit; 32 reflective member detection unit; 33 first angle calculation unit; 34 minimum value detection unit; 35 maximum value detection unit; 36 subtraction unit; 37 second angle calculation unit; 40 object; R1, R2 scanning range; W0, W1 waveform
Number | Date | Country | Kind |
---|---|---|---|
2014-127339 | Jun 2014 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
8368876 | Johnson | Feb 2013 | B1 |
8446571 | Fiess | May 2013 | B2 |
8688308 | Wu | Apr 2014 | B2 |
20060071578 | Drabe | Apr 2006 | A1 |
20090284190 | Matsubara | Nov 2009 | A1 |
20140218715 | Li | Aug 2014 | A1 |
Number | Date | Country |
---|---|---|
2005-077288 | Mar 2005 | JP |
2012078269 | Apr 2012 | JP |
Number | Date | Country | |
---|---|---|---|
20150369920 A1 | Dec 2015 | US |