Variable optical attenuator and method for improved linearity of optical signal attenuation versus actuation signal
First Claim
8. A method for controllably attenuating the transmission of a beam of light in a more linear relationship between applied power and decreased attenuation, comprising:
- a. providing a first optical waveguide, a second optical waveguide, a lens, and a semiconductor micro-electro-mechanical system, the system having a reflecting surface and an actuator;
b. the first optical waveguide for emitting a light beam towards the reflecting surface of the device;
c. the reflecting surface for reflecting the light beam, as received from the first optical waveguide, through lens and into the second waveguide;
d. the actuator for moving the reflecting surface from a zero actuation position through a range of motion to a minimum attenuation position, and wherein a pre-selected maximum attenuation of a transmission of the light beam from the first optical waveguide to the second optical waveguide is achieved when the reflecting surface is placed in the zero actuation position;
e. placing the reflecting surface in the zero actuation position;
f. providing power to the actuator and causing the actuator to move the reflecting surface and reducing the potential attenuation of the transmission of the light beam; and
g. emitting light from the first optical waveguide, whereby the light beam is transmitted through lens and into the second optical waveguide.
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Accused Products
Abstract
A variable optical attenuator, or VOA, and method of operation is provided. The operational method increases the linearity of the optical signal attenuation versus an applied actuator actuation signal and decreases the attenuation loss sensitivity to actuation signal noise and actuation signal uncertainty. A preferred embodiment has a light emitting waveguide and optionally an output waveguide, a focusing system, a mirror having a reflecting surface, and a mirror actuator. The mirror is operatively connected with a suspension element that returns the mirror to a highest attenuation, or zero actuation, position when the actuator fails to supply a minimal force to the mirror. The preferred embodiment provides better optical attenuation accuracy and enables reductions in both the complexity and cost of control circuitry of the VOA. The present invention may be implemented as a micro-electro-mechanical system, or MEMS, comprising a microstructure having a mirror and a collimator, where the MEMS is coupled to one or more optical fibers.
28 Citations
62 Claims
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8. A method for controllably attenuating the transmission of a beam of light in a more linear relationship between applied power and decreased attenuation, comprising:
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a. providing a first optical waveguide, a second optical waveguide, a lens, and a semiconductor micro-electro-mechanical system, the system having a reflecting surface and an actuator;
b. the first optical waveguide for emitting a light beam towards the reflecting surface of the device;
c. the reflecting surface for reflecting the light beam, as received from the first optical waveguide, through lens and into the second waveguide;
d. the actuator for moving the reflecting surface from a zero actuation position through a range of motion to a minimum attenuation position, and wherein a pre-selected maximum attenuation of a transmission of the light beam from the first optical waveguide to the second optical waveguide is achieved when the reflecting surface is placed in the zero actuation position;
e. placing the reflecting surface in the zero actuation position;
f. providing power to the actuator and causing the actuator to move the reflecting surface and reducing the potential attenuation of the transmission of the light beam; and
g. emitting light from the first optical waveguide, whereby the light beam is transmitted through lens and into the second optical waveguide. - View Dependent Claims (9, 10)
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12. A variable optical attenuator, comprising:
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a light channel, the light channel emitting a light beam;
a movable mirror having a reflecting surface, the reflecting surface for reflecting the light beam;
a collimating and focusing element, the element positioned to collimate the light beam into a collimated light beam as the light beam transmits from the light channel to the mirror, and the element positioned to focus the collimated light beam towards an output waveguide after reflection from the reflecting surface;
the output waveguide statically positioned relative to the collimating and focusing element to transmit the light beam reflected from the reflecting surface, the output waveguide for transmitting a portion of the reflected light beam out of the variable optical attenuator, wherein the magnitude of the portion of the reflected light beam transmitted by the output waveguide is substantially determined by a position of the reflecting surface; and
the reflecting surface having an angular range of motion from a zero actuation position to a minimum attenuation position, the zero actuation position providing approximately a predetermined attenuation of transmission of the light beam as reflected into the output waveguide, whereby attenuation of the light beam reflected into the output waveguide is more linearly controllable as the reflecting surface moves from the zero actuation position and to the minimum attenuation position. - View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26)
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27. A method for controllably attenuating the transmission of a beam of light in a more linear relationship between an actuation signal and decreased attenuation, comprising:
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a. providing an apparatus having a light beam channel, an output waveguide, a collimating and focusing element, and a mirror, the mirror having a reflecting surface;
b. the light beam channel for emitting a light beam towards the reflecting surface of the mirror and through the collimating and focusing element;
c. the collimating and focusing element for collimating the light beam into a light beam as the light beam transmits from the light beam channel to the reflecting surface, and the collimating and focusing element for focusing the light beam towards the output wave guide as the light beam transmits from the reflecting surface of the mirror and towards the output waveguide;
d. the reflecting surface for reflecting the light beam towards the collimating and focusing element;
e. the reflecting surface having an angular range of motion from a zero actuation position to a minimum attenuation position, and wherein a pre-selected maximum attenuation of a transmission of the light beam from the light beam channel to the output waveguide is achieved when the reflecting surface is placed in the zero actuation position;
f. placing the reflecting surface in the zero actuation position;
g. emitting light beam from the light beam channel;
h. collimating the light beam into a light beam within the collimating and focusing element;
i. transmitting the collimated light beam to the reflecting surface;
j. reflecting the light beam from the reflecting surface and through the collimating and focusing element;
k. focusing the light beam from the collimating and focusing lens and into the output waveguide, whereby the light beam is attenuated and transmitted into the output optical waveguide; and
l. reducing the attenuation of the transmission of the light beam by moving the reflecting surface away from the zero actuation position and towards the minimum attenuation position, whereby the attenuation of the light beam received by the output waveguide is attenuated in a more linear relationship to the angular movement of the reflecting surface. - View Dependent Claims (28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39)
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40. A variable optical attenuator, comprising:
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a light beam emitting waveguide, the light beam emitting waveguide for emitting a light beam;
a movable mirror having a reflecting surface, the reflecting surface for reflecting the light beam;
a collimating and focusing element, the element positioned to collimate the light beam into a light beam as the light beam transmits from the light channel to the mirror, and the element positioned to focus the light beam back towards the light beam emitting waveguide after reflection of the light beam from the reflecting surface;
the light beam emitting waveguide statically positioned relative to the collimating and focusing element to transmit light beam reflected from the reflecting surface;
the light beam emitting waveguide for transmitting a portion of the reflected light beam out of the variable optical attenuator, wherein the magnitude of the portion of the reflected light beam transmitted out of the variable optical attenuator by the light beam emitting waveguide is substantially determined by a position of the reflecting surface; and
the reflecting surface having an angular range of motion from a zero actuation position to a minimum attenuation position, the zero actuation position providing approximately a pre-determined attenuation of transmission of the light beam as reflected into the output waveguide, whereby attenuation of the light beam reflected into the output waveguide is more linearly controllable as the reflecting surface angularly moves from the zero actuation position and to the minimum attenuation position. - View Dependent Claims (1, 2, 3, 4, 5, 6, 7, 11, 41, 42, 43, 44, 45, 46, 47, 48, 49, 60, 61, 62)
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44-1. The apparatus of claim 41, wherein the actuator is selected from the group consisting of an electro-static actuator, a piezo-electric actuator, a thermo-mechanical actuator, an electromagnetic actuator, and a polymer actuator.
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50. A method for controllably attenuating the transmission of a beam of light in a more linear relationship between actuation and decreased attenuation, comprising:
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a. providing an apparatus having a light beam emitting waveguide, a collimating and focusing element, and a mirror, the mirror having a reflecting surface;
b. the light beam emitting waveguide for emitting a light beam towards the reflecting surface of the mirror and through the collimating and focusing element;
c. the collimating and focusing element for collimating the light beam into a light beam as the light beam transmits from the light beam emitting waveguide to the reflecting surface, and the collimating and focusing element for focusing the light beam back towards the light beam emitting waveguide as the light beam transmits from the reflecting surface of the mirror and towards the light beam emitting waveguide;
d. the reflecting surface for reflecting the light beam through the collimating element and back into the light beam emitting waveguide;
e. the reflecting surface having a range of angular motion from a zero actuation to a minimum attenuation position, and wherein a pre-selected maximum attenuation of a transmission of the light beam from the light beam emitting waveguide and back into the light beam emitting waveguide is achieved when the reflecting surface is placed in the zero actuation position;
f. placing the reflecting surface in the zero actuation position;
g. emitting light beam from the light beam emitting waveguide;
h. collimating the light beam into a light beam within the collimating and focusing element;
i. transmitting the collimated light beam to the reflecting surface;
j. reflecting the light beam from the reflecting surface and through the collimating and focusing element;
k. focusing the light beam from the collimating and focusing lens and into the light beam emitting waveguide, whereby the light beam is attenuated and transmitted through the collimating element and into the light beam emitting waveguide; and
l. reducing the attenuation of the transmission of the light beam by moving the reflecting surface from the zero actuation position and towards the minimum attenuation position, whereby the attenuation of the light beam reflected back into the light beam emitting waveguide is reduced in a more linear relationship to an angular movement of the reflecting surface. - View Dependent Claims (51, 52, 53, 54, 55, 56, 57, 59)
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Specification