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Claims  |
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What is claimed is:
1. A device for sensing linear displacements between a first member and a
second member, wherein the first member has a non-planar geometric shape,
wherein the second member has a substantially similar non-planar geometric
shape as the first member, wherein, from a first axis, the second member
substantially encompasses the first member, and wherein the sensed linear
displacements are along a first axis, the device comprises:
an optical code pattern disposed on a non-planar surface of the first
member, wherein the optical code pattern at least partially encircles the
first axis;
an encircling optical sensor arranged on the second member, wherein the
encircling optical sensor at least partially encircles the optical code
pattern, wherein the encircling optical sensor senses the optical code
pattern, and wherein the encircling optical sensor includes:
at least one light transmitting path, wherein the at least one light
transmitting path has a nonlinear geometry, and emits light on the optical
code pattern to reflect off the optical code pattern to produce, at least
a portion of the light off of the optical code pattern;
a plurality of light receiving paths, wherein each of the plurality of
light receiving paths has a nonlinear geometry, and wherein at least one
of the light receiving paths receives the at least a portion of the light
reflected off the optical code pattern emitted from the at least one light
transmitting path; and
a displacement calculation device, operably coupled to the encircling
optical sensor, wherein the displacement calculation device calculates the
displacement of the first member with respect to the second member.
2. A sensing device in accordance with claim 1 wherein the at least one
light transmitting path comprises a fiber-optic waveguide.
3. A sensing device in accordance with claim 1 wherein each of the
plurality of light receiving paths comprise fiber-optic waveguides.
4. A sensing device in accordance with claim 1 wherein the at least one
light transmitting path and the plurality of light receiving paths are
positioned on a common substrate.
5. A sensing device in accordance with claim 4 wherein each of the at least
one light transmitting path and the plurality of light receiving paths are
comprised of a first material and the common substrate is comprised of a
second material, wherein the first and second materials have a different
refractive index.
6. A sensing device in accordance with claim 5 wherein each of the at least
one light transmitting path and the plurality of light receiving paths are
formed by a groove on the substrate filled with a material comprising a
molded plastic material.
7. A sensing device in accordance with claim 6 wherein the molded plastic
material comprises a polysulphone plastic material.
8. A sensing device in accordance with claim 6 wherein the molded plastic
material and the common substrate are formed with materials having
substantially a same thermal coefficient of expansion.
9. A sensing device in accordance with claim 1 wherein said encircling
optical sensor is constructed of a horseshoe geometry.
10. A sensing device in accordance with claim 1 wherein the optical code
pattern comprises a Gray code.
11. A sensing device in accordance with claim 1 wherein each of the
plurality of light receiving paths are formed of a substantially tubular
geometry, wherein opposite the optical code pattern on the first member
the substantially tubular geometry commences at a first cross-sectional
area and progresses to a smaller cross-sectional area.
12. A sensing device in accordance with claim 1 wherein the device is
mounted in a shock absorber.
13. A sensing device in accordance with claim 1 wherein the first member
has a cylindrical shape.
14. A device for sensing linear displacements between a first member and a
second member, wherein the first member has a non-planar geometric shape,
wherein the second member has a substantially similar non-planar geometric
shape as the first member, wherein, from a first axis, the second member
substantially encompasses the first member, and wherein the sensed linear
displacements are along a first axis, the device comprises:
an optical code pattern disposed on a non-planar surface of the first
member, wherein the optical code pattern at least partially encircles the
first axis;
an encircling optical sensor arranged on the second member, wherein the
encircling optical sensor at least partially encircles the optical code
pattern, wherein the encircling optical sensor senses the optical code
pattern, and wherein the encircling optical sensor includes:
at least one light transmitting path, wherein the at least one light
transmitting path has a nonlinear geometry, and wherein a termination of
the at least one light transmitting path emits light on the optical code
pattern to reflect, non-normal to the optical code pattern to produce, at
least a portion of the light off of the optical code pattern, and wherein
the termination has a smaller cross-sectional area than a cross-sectional
area of the at least one light transmitting path;
a plurality of light receiving paths, wherein each of the plurality of
light receiving paths has a nonlinear geometry, and wherein at least one
of the light receiving paths receives the at least a portion of the light
reflected off the optical code pattern emitted from the at least one light
transmitting path; and
a displacement calculation device, operably coupled to the encircling
optical sensor, wherein the displacement calculation device calculates the
displacement of the first member with respect to the second member
dependent on the transmission of light from the at least one light
transmitting path, including the optical code pattern to at least one of
the plurality of light receiving paths.
15. A method for sensing linear displacements between a first member and a
second member, wherein the first member has a non-planar geometric shape,
wherein the second member has a substantially similar non-planar geometric
shape as the first member, wherein, from a first axis, the second member
substantially encompasses the first member, and wherein the linear
displacements are along the first axis, the method comprises the steps of:
disposing an optical code pattern on a non-planar surface of the first
member, wherein the optical code pattern at least partially encircles the
first axis and has a substantially similar non-planar surface as the first
member;
positioning an encircling optical sensor on the second member to at least
partially encircle the optical code pattern;
transmitting, by the encircling optical sensor, a light beam onto the
optical code pattern;
receiving, by the encircling optical sensor, a reflected portion of the
light beam; and
calculating the linear displacement of the first member with respect to the
second member based on the reflected portion of the light.
16. A device for indicating an axial position of a shaft, the device
comprising:
a coded longitudinal member principally oriented coincident with a first
axis, said coded longitudinal member having a digitized pattern disposed
thereon, wherein the digitized pattern comprises a plurality of tracks
disposed along a portion of an outer surface of said coded longitudinal
member, wherein the outer surface extends radially surrounding the first
axis, wherein each of the plurality of tracks includes a plurality of
reflective portions interdigitated with a plurality of non-reflective
portions, the tracks extending along a portion of the outer surface
longitudinally oriented with the first axis;
optical transceptive means oriented at least partially circumferentially
surrounding said coded longitudinal member, said optical transceptive
means including at least a light transmission path, and a plurality of
light reception paths, wherein the plurality of light reception paths are
positioned opposite the plurality of tracks such that a transception path
is completed between the at least a light transmission path, the plurality
of tracks of the digitized pattern, and the plurality of light reception
paths; and
a displacement calculation device, operably coupled to the optical
transceptive means, wherein said displacement calculation device
calculates the displacement of the optical transceptive means along said
coded longitudinal member dependent on the transception of light between
the at least a light transmission path, the plurality of tracks of the
digitized pattern, and the plurality of light reception paths. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention is generally directed to the field of absolute position
displacement sensors, and specifically for measurement of height of a
shock absorber in a vehicular suspension system.
BACKGROUND OF THE INVENTION
Contemporary position displacement sensors for vehicular shock absorbers
include those based on Hall-effect switches, and various forms of optical
sensors. Hall-effect switches provide low accuracy, must be mounted
outside of a shock absorber, and don't work in the presence of water.
The various forms of optical sensors including proximity type, and the
coaxial reflective type will not reliably operate at the extreme
temperatures found inside a shock absorber, which may exceed 160.degree.
Celsius.
What is needed is an improved sensor for measuring a displacement of a
shock absorber that is accurate and will work reliably under extreme
temperature conditions.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates a shock absorber and an optical sensor in accordance
with the present invention;
FIG. 2 illustrates a cross-sectional view of the shock absorber shown in
FIG. 1;
FIG. 3 illustrates a cross-sectional view of an encircling optical sensor
in accordance with the present invention;
FIGS. 4, 5, and 6 illustrate cross-sectional view of alternative encircling
optical sensors; and
FIG. 7 is a system block diagram illustrating details of the encircling
optical sensor and a displacement calculation device.
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
Generally, the present invention provides a method and apparatus for
sensing linear displacements between a first member and a second member.
In a preferred embodiment, the second member and the first member reside
on the same axis, where the second member substantially encompasses the
first member. To sense the linear displacements, an optical code pattern
is placed on the first member and an encircling optical sensor is placed
on the second member. The encircling optical sensor includes light
transmitting and receiving paths that transmit and receive light to/from
the optical code pattern. The light received from the optical code pattern
is sent to a displacement calculation device that determines the linear
displacement of the first member with respect to the second member. Using
this technique, linear displacements of the first member with respect to
the second member can be accurately measured in high temperature and
pressure environments without adversely affecting electrical components.
The present invention can be more fully described with reference to FIGS.
1-3. FIG. 1 illustrates a shock absorber 100 that includes a first member
101, a second member 102, an optical code pattern 103, an optical
transceptive means, or encircling optical sensor 104 with optical
waveguides.
Preferably, the first member 101 has a longitudinal cylindrical shape.
Also, preferably the optical code pattern 103 is comprised of a digitized
pattern containing a plurality of tracks disposed along a portion of an
outer surface of the first member 101. Each of the plurality of tracks
includes a plurality of reflective portions interdigitated with a
plurality of nonreflective portions.
The encircling optical sensor 104 includes optical waveguides comprising
multiple light transmitting paths 106, and light receiving paths 107.
A displacement calculation device 105 is placed outside of the shock
absorber. This displacement calculation device 105 contains electrical
components used to determine the linear displacement between the first 101
and second 102 members. It is located outside of the shock absorber
because the temperature is substantially lower and the electrical
components will operate much more reliably at these lower temperatures.
As a vehicle, having the just-described apparatus traverses over a road,
the two sections of the shock absorber, the first member 101, and the
second member 102, will be linearly displaced relative to each other.
Specifically, the first member 101 moves, while the second member 102 is
fixed with respect to the vehicle. The linear displacement transpires
parallel to a first axis 108.
For the purpose of providing a smooth ride, the displacement calculation
device 105 is needed to determine the height of the vehicle, in this case
the displacement between the first member 101 and the second member 102.
Then, the displacement calculation device 105 sends a displacement signal
to a suspension control system. The suspension control system calculates
the absolute height provided by the displacement signal, and adjusts the
vehicle height.
The shock absorber 100, with the above described linear displacement
apparatus, can be assembled by the following steps. First, a thin sheet
which contains an optical code pattern is either welded or adhesively
bonded on the external surface of the first member 101.
Second, the encircling optical sensor 104 is adhesively attached on a
sensor holder 109. Third, the sensor holder 109 is mechanically fixed on
the inner surface of the second member 102. The light transmitting paths
106, and the light receiving paths 107 of the encircling optical sensor
104, are coupled to the displacement calculation device 105 via a fiber
ribbon. 0f course, other interconnect approaches may be used.
Then the first member 101 is mounted to a suspension control arm which is
fixed to a wheel of the vehicle, while the second member 102 is firmly
fixed to a body of the vehicle. Therefore, when the vehicle traverses over
a road, the first member 101 moves up or down relative to the second
member 102 along the first axis 108.
To measure the linear displacements, the encircling optical sensor 104
transmits light, via a curved light transmitting path 106, to the optical
code pattern 103. Preferably, the optical code pattern 103 is comprised of
a Gray code. Optionally other binary codes may be used. Then, the light is
either reflected off, or absorbed by, the optical code pattern. If
reflected, the light is collected by a curved light receiving path 107. A
received signal state of logical "0" corresponds to no reflection, and a
received signal state of logical "1" corresponds to a reflection. The
remote displacement calculation device 105 both transmits the light and
receives the light to and from the encircling optical sensor 104. FIG. 2
illustrates a cross-sectional view of the shock absorber 100, and the
encircling optical sensor 104. As mentioned above, the light transmitting
path 106 transmits light to the optical code pattern 103 which reflects or
absorbs the transmitted light. Reference numbers 201,202, 203, and 204
illustrate various reflective sections of the optical code pattern 103.
Reference number 205 illustrates a non-reflective, or absorptive section
of the optical code pattern 103.
If the light is reflected off a reflective section, as shown by reference
number 200, it is reflected to the light receiving path 107. To provide a
sufficient quantity and focus of light transmitting onto the optical code
pattern 103, the transmitting path 106 is fabricated into a shape such
that it has a decreasing diameter facing the optical code pattern 103. A
larger diameter on the opposing side of the transmitting path 106, ensures
that higher percentage of light is coupled into the light transmitting
path 106 from the displacement calculation device 105. A substantially
tubular geometry or the light transmitting path 106 commences at a first
cross-sectional area and progresses to a smaller cross-sectional area as
is approaches the optical code pattern 103. Preferably, the diameter of
the path light transmitting 106 is tapered down into less than 0.4 mm.
This enables the light receiving path 107 to distinguish a series of 0.25
mm width reflective and non-reflective patterns comprising the optical
code pattern 103. Interestingly, the light receiving path 107 is also
formed of a waveguide having a substantially tubular geometry, terminated
with a cup, or funnel shape to collect a large amount of reflected light
off of the optical code pattern 103.
FIG. 3 illustrates a cross-sectional view of the encircling optical sensor
104. Several techniques can be applied to fabricate the encircling optical
sensor 104. Inexpensive fabrication methods include injection molding,
extruding, and stamping of plastics. Other methods include
photolithography of photo-imagable polymers, chemical etching, reactive
ion etching, and photosensitive polymers. The encircling optical sensor
104 is constructed of a horseshoe geometry. This enables it to be easily
assembled into the shock absorber. The encircling optical sensor 104
includes the light transmitting path 106, the light receiving path 107, a
substrate cover 301, and a substrate 300. The paths, 106 and 107 are
located surrounded inside of 300 and 301 which together function as a
substrate. Refractive indices of both paths 106 and 107 are higher than
that of the substrate 300 and the substrate cover 301. This ensures that
light propagates only inside of the paths 106 and 107 without optical
crosstalk. Preferably, the paths 106 and 107 are essentially formed as a
groove on the substrate filled with a material comprising a molded plastic
material. For instance, a dielectric material such as fluorinated
polysulphone which has a high refractive index. While the substrate 300
and the substrate cover 301 are composed of another polysulphone material
with a lower refractive index. That both materials are made from the same
base material is advantageous because they have a similar thermal
coefficient of expansion. Optionally, conductive materials such as metal
may be used to form the substrate 300 and the substrate cover 301 with
hollow light paths 106 and 107. Alternatively, the paths 106 and 107 may
be formed using a fiber-optic waveguide.
Notwithstanding the configuration shown in FIG. 3, various other
transmitting and receiving paths can be implemented. For example, the
transmitting and receiving paths 106 and 107 can be placed on alternative
substrates and covers, as shown in FIGS. 4, 5, and 6.
In FIG. 4, there is a singular light transmitting path 106' and multiple
light receiving paths 107'. The cover 301' contains a single transmitting
light emitted from the remote light source. The transmitted light is then
split into multiple beams at the inner circle of the encircling optical
sensor 104 to reflect off the code pattern 103. Rather than being
reflected at the same level as the transmitting path 106', the reflected
light is then guided down into the receiving paths 107' on the substrate
level 300'. Advantages of two-layer configuration include that only one
light source is needed. Second, the packaging size is reduced in the
direction which is perpendicular to the first axis 108 without optical
crosstalk.
In FIG. 5 a top level transmitting path 106", which is parallel to the
receiving paths 107" of the bottom layer, may be bent downward along the
first axis direction 108 into the receiving path at only the output end.
The transmitting path 106" can emerge into the receiving paths 107" to
form "coaxial" path. This design yields a greater transmission efficiency
while retaining the compactness of the design illustrated in FIG. 5.
Optionally, as shown in FIG. 6 the transmitting path 106'" can be bent down
and rotated certain angle around the first axis 108 so that the
transmitting 106'" and receiving 107'" paths are placed next to each other
on the same receiving path layer 300'".
A system block diagram of the encircling optical sensor 104, and the
displacement calculation device 105 is illustrated in FIG. 7. The
encircling optical sensor 104, is a passive optical element, as described
above. The encircling optical sensor 104 is located inside the shock
absorber and operates in a high temperature environment. The displacement
calculation device is located external to the shock absorber in a more
benign temperature environment compatible with electrical components.
Internal to the displacement calculation device 105 are a light source
701, and a group of 9 photodetectors 703. In the preferred embodiment, the
light source is comprised of a light-emitting diode. In this case one of
the encircling optical sensor designs shown in FIGS. 4, 5, or 6 would be
employed. Optionally, 9 light-emitting diodes could drive the encircling
optical sensor shown in FIG. 3. The photodetectors are comprised of
photodiodes, that are responsive to the same spectrum emitted by the
light-emitting diode. Also a Gray code converter 705 is employed to
convert the light received from the light receiving paths 107, and
detected by the photodetectors 703 to a binary output indicating linear
displacement between the members 101 and 102 to an external control
system. The external control system is not detailed here because of its
conventional nature.
As mentioned before, to determine the displacement between the first member
101 and the second member 102, the optical code pattern 103 such as a
nine-bit Gray code pattern, chosen to meet the required resolution for
this application, is mounted to the first member 101. The need for the
nine-bit Gray code pattern is detailed below. The Gray code is favorable
in this case because it changes only one bit for one digit displacement.
Since the beam size, transmitted from the transmitting path 106, is
relatively small (less than 0.4 mm in diameter), the luminance intensity
is usually low. To improve signal to noise ratio, contrast between
reflective and non-reflective codes 201-209 of the optical code pattern
103 have to be maximized. For example, optical code pattern 103 can be
constructed from an etched aluminum or stainless steel material, where the
etched area, is the non-reflective area. This non-reflective area is
filled with light absorbing material such as matte-finished black ink. The
unetched area is reflective to provide good light reflection. Similarly,
the optical code pattern 103 can be made by screen printed black and white
epoxy or paint, by photo-sensitive polymers, and by Mylar film.
As a working example of the above, assume that the shock absorber 100 is
mounted in a vehicle. The optical code pattern 103 is fixed around the
first member 101 of the shock absorber 100. Since the maximum travel range
between the first member 101 and the second member 102 is 100 mm, to
achieve a 0.25 mm resolution a nine-bit Gray code pattern is used. This
Gray code is constructed in the way that when the first member 101 and the
second member 102 are in a fully compressed position, the corresponding
Gray code is 000000000. This means that the light transmitted from the
light transmitting path 106 will not be reflected to the light receiving
paths 107, when the members 101 and 102 are in this fully compressed
position. When the shaft is in a fully extended position, the
corresponding Gray code is 100000000. This means that the light
transmitted from the light transmitting path 106 will be reflected to one
of the light receiving paths 107, when the members 101 and 102 are in this
fully extended position. Returning to FIG. 7 the light source 701
transmits light via the light transmitting path 106, via the light
transmitting path 106, off the Gray code encoded optical code pattern 103,
via one or more of the light receiving paths 107, to the photodetectors
703. An output signal from the photodetectors 703 is sent to the Gray code
converter 705, which produces a binary code representative of the linear
displacement 707 of the first member 101 with respect to the second member
102.
The present invention provides a method and apparatus for sensing linear
displacements between a first member 101 and a second member 102. The
device described in the preferred embodiment is mass produceable at a low
cost. Using injection molding, the encircling optical sensor 104 can be
molded to different shapes depending on specific applications. Moreover,
there is no restrictions on the size of the optical paths 106, and 107,
since the paths can be custom designed to achieve a required accuracy.
Furthermore, due to the robustness of this sensor, it can operate in a
very harsh, high temperature, automotive environment.
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Description |
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