Contribution to the development of optical scanners with rotating or oscillating elements.
Duma, Virgil-Florin ; Nicolov, Mirela ; Szantho, Lucian 等
1. INTRODUCTION
There are a myriad applications of optical scanners, from remote
(e.g. airborne or satellite for surveillance, industrial) to input (e.g.
barcode reading, optical inspection, confocal microscopy, optical
coherence tomography (OCT), robot vision) and output ones (printing,
marking and engraving, rapid prototyping). There are several classes of
scanners: with rotating or oscillating mirrors, resonant, holographic,
acusto-optic and electro-optic (Bass, 1995).
A decade of our investigations addressed scanners with rotating
(plane or polygonal) or oscillating (galvanometer-based) mirrors
(Beiser, 1995). This paper will present the scope of our researches,
with a brief overview of the results obtained, both for 1D and 2D
scanning systems for several applications.
2. POLYGON SCANNERS FOR DIMENSIONAL, INDUSTRIAL MEASUREMENTS
The scheme of the dimensional (online, industrial) measurements
using rotating mirror scanners (Richter, 1992) is presented in figure 1.
As the mirror (2) rotates, the laser ray (1) is transformed into a
rotating one, that scans the first lens (3) and, thus, the probe space.
The emergent laser beam has to remain parallel to the optical axis
(O.A.) of both lenses (3). If this condition is fulfilled, than the time
interval [DELTA]t for which the photodetector (4) receives no light
signal will be a measure of the dimension "d" of the object in
the scanning direction:
d = h([t.sub.0] + [DELTA]t)-h([t.sub.0]) = h([[theta].sub.0] +
[DELTA][theta]) - h([[theta].sub.0]), [theta] = [omega]t (1)
where the scanning function (Fig. 1) h(t) represents the current
position of the ray in the scanned space (Duma, 2006):
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
h([theta]) = R[square root of 2] - e - R/cos[theta]+ e x tan[theta]
- L/tan2[theta] (1)
The graph of the scanning function is presented in figure 2. The
two pairs of angles are highlighted: [[theta].sub.1] and [[theta].sub.2]
= the angles for which the the laser ray reaches the margins of the
first lens; [[theta].sub.min] and [[theta].sub.min] = the angles
produced when the ray is reflected by the margins of a facet of the
polygon. A detailed analysis has been performed on this system (Duma,
2005), regarding these angles, the scanning velocity v=dh/dt, and the
duty cycle (the time efficiency of the system):
[eta] = [[theta].sub.2] - [[theta].sub.1]/[[theta].sub.max] -
[[theta].sub.min] = n [[theta].sub.2] - [[theta].sub.1]/2[pi]. (2)
The designing calculus that was our scope was thus obtained (Duma,
2007), more detailed than in literature (Beiser, 1991), with the
possibility of simplifying the first lens of the system. A problem that
was also addressed is obtaining a linear scan that is a constant problem
of scanners (Li, 1995). For the measuring system in figure 1, obtaining
a one-parameter functioning characteristic d([DELTA][theta]) has also
been solved (Duma, 2005), in several ways, both for the polygon-based
and for the monogon scanner, as the two-parameters function
d([[theta].sub.0], [DELTA][theta]) in Eq. (1) does not provide precision
in the measuring process.
3. GALVANOMETER-BASED SCANNERS
The resonant (Fig. 3) and the galvanometer scanner (GS), was
studied (Duma, 2008), with an enhanced duty cycle n with regard to the
state-of-the-art (Gadhok, 1999) and a linear scan on its active
portions. This solution was considered with regard to the scan
(oscillating) frequency that should be enhanced without a severe
decrease of [eta].
The dynamic equation of the mobile element is:
[??] + 2[xi][[omega].sub.0][??] + [[omega].sup.2.sub.0][theta] =
[M.sub.a](t)/J, (3)
[FIGURE 3 OMITTED]
where [[omega].sub.0] = [square root of K / J]; [xi] = c / 2
[square root of Jk] are the natural pulsation and the unitless damping
factor, respectevely. The command function is
i(t) = [M.sub.a](t) / BNS (4)
(B is the magnetic induction, N is the number of spires, and S is
the area of the surface of the mobile coil), where the active torque
results from Eq. (5):
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] (5)
Therefore the i(t) function is obtained by imposing a convenient
scanning function x(t), with linear active portions and fast
stop-and-return parts (Fig. 4). This is actually the ideal way a scan
should be performed for most applications.
The GS is somehow competing nowadays for high end applications,
i.e. biomedical ones: optical coherence tomography (OCT) and/or confocal
microscopy, with polygonal mirrors setups. 1D solutions that require a
fast scan have revitalized the use of polygons, e.g. for swept source
laser sources, with on-axis or off-axis (Oh, 2005) polygon scanners.
[FIGURE 4 OMITTED]
3. 2D SCANNING SYSTEMS
In figure 5 the scanning module of a confocal microscope is
presented, for which the scanning functions were developed (Duma, 2007).
The proper programming of the two 1D GSs used allow for the full scan of
the plane surface of the probe, in contrast with the non-linear, e.g.
cushion-like shaped of 2D scanned previously obtained (Li, 2008).
[FIGURE 5 OMITTED]
[FIGURE 6 OMITTED]
Another solution is the one of two polygon scanners (Sc 1 and 2) 2D
assembly, presented in figure 6 that will be studied based on the
analysis previously developed.
4. CONCLUSIONS
Our future work addresses improvements of the devices presented, as
the problem of increasing the duty cycle of galvoscanners for high scan
frequencies is still a problem and simpler lenses for systems with
polygon scanners must be obtained. Other applications of the polygon
scanners, both for the industrial domain, e.g. for marking, engraving
and robotics, and for high end applications, i.e. in biomedical imaging,
will be approached.
5. ACKNOWLEDGEMENT
The research is supported by the Romanian Education and Research
Ministry, within the PN II, Ideas Grant, NURC (National University
Research Council) code 1896/2008.
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