A microdisplay integrated circuit (IC) includes a two-dimensional array of pixel cells formed on a semiconductor substrate. Each pixel cell may be adapted to control an electric field across an associated portion of liquid crystal material. The electric field may be modulated to change a state of the liquid crystal material in order to produce an image pixel of a desired pixel intensity for a given image frame. Current microdisplay IC packages attempt to protect microdisplay IC components and to provide an environment for proper operation thereof.
Microdisplay IC 10 includes semiconductor substrate 15. Substrate 15 may comprise single-crystal silicon or any other semiconductor substrate within which integrated electrical devices may be fabricated. In this regard, pixel cell array 20 is fabricated within the upper layers of semiconductor substrate 15. Pixel cell array 20 may be fabricated using currently- or hereafter-known masking, etching, and deposition techniques.
Each pixel cell 21 is associated with a pixel electrode 22. Pixel electrode 22 may comprise a reflective material such as aluminum for reflecting light incident thereto. One pixel electrode 22 may be used to selectively apply a voltage signal, or potential, to a region of light switching layer 25 with which it is in contact. In this regard, light switching layer 25 may comprise a layer of liquid crystal of any suitable type.
According to some embodiments, pixel electrodes 22 comprise an array of micromirrors, and light switching layer 35 may comprise air. Pixel electrodes 22 themselves may operate to switch light in such embodiments.
Electrode 30 may contact light switching layer 25 to complete an electric circuit to carry current through a voltage source (not shown), pixel cell 21, pixel electrodes 22, light switching layer 25, electrode 30, and back to the voltage source. In some embodiments, electrode 30 comprises Indium Tin Oxide.
As shown in
For purposes of the present description, microdisplay 10 will be described as including elements 15 through 30. Additionally, elements 20 through 30 will be generally referred to as imaging elements. A microdisplay IC according to some embodiments may comprise less or more imaging elements than shown in
In operation, a pixel cell 21 of pixel cell array 20 generates a voltage on an associated pixel electrode 22. The voltage is applied to a region of light switching layer 25 that is in contact with the associated pixel electrode 22. The applied voltage may, in conjunction with a voltage signal applied to electrode 30, create an electric field across the region of light switching layer 25. More specifically, a strength of the electric field is based on a potential difference between the applied potential and a potential of electrode 30. The region of light switching layer 25 reacts to the electric field according to its characteristic behavior.
In this regard, each region of light switching layer 25 may operate as an electrically-activated light filter. When subjected to a weak or no electric field, a region may impart no polarization rotation to light that is received through cover 35, thereby preventing the light from passing to the reflective surface of a pixel electrode 22 that is in contact with the region. When subjected to a stronger electric field, the region may rotate light received through cover 35 forty-five degrees as it passes through the region of light switching layer 25. The light then reflects off the reflective surface of the pixel electrode 22 and is rotated an additional forty-five degrees as it passes back through the region before exiting cover 35. A percentage of incoming light that is reflected back through cover 35 can therefore be varied by varying the strength of the electric field.
According to some embodiments, each region of light switching layer 25 controls an intensity of light returned through cover 35 based on the strength of an applied electric field. Some embodiments of light switching layer 25 direct light received through cover 35 using other techniques.
To form an image using microdisplay IC 10, a desired intensity is determined for each pixel of the image. Electric field intensities that correspond to the desired image pixel intensities are then applied to regions of light switching layer 25 that correspond to the image pixels. As a result, any light that is incident to cover 35 will reflect off of pixel electrodes 22 and exit from cover 35 toward an observer in accordance with the desired pixel intensities. Microdisplay IC 10 may display a moving image by rapidly displaying successive images. In such a case, the successive images may be referred to as image frames.
The intensities of pixels displayed by microdisplay IC 10 therefore depend in part upon the strength of the electric fields applied across corresponding regions of light switching layer 25. The strength of these fields depends in part on a distance between electrode 30 and pixel electrodes 22 that are in contact with the corresponding regions. This distance may be specified by the design of microdisplay IC 10. In a case that this distance is outside of designed tolerances for one or more pixels, pixel intensities displayed by microdisplay IC 10 may not correspond to desired pixel intensities.
The distance between one or more of pixel electrodes 22 and electrode 30 may fall outside of the designed tolerances if microdisplay IC is mechanically distorted. For example, some conventional systems bond the substrate of a microdisplay IC directly to a substantial chip carrier. The chip carrier may possess a coefficient of thermal expansion (CTE) that differs significantly from the CTE of the microdisplay IC. Heat generated by the microdisplay IC during operation may cause the chip carrier to expand at a different rate than the microdisplay IC, thereby causing mechanical distortion of the microdisplay IC.
Bonding agent 60 may couple microdisplay IC 10 to base 50. Bonding agent 50 may comprise one or more of thermal epoxy, thermal tape, thermal grease, thermal phase change material, and any other suitable bonding agent. Bonding agent 60 may be applied to one or both of a lower surface of substrate 15 and an upper surface of base 50 to couple microdisplay IC 10 to base 50.
As described with respect to
Chip carrier 80 may comprise ceramic and/or organic material. A material of chip carrier 80 may possess a CTE similar to that of semiconductor substrate 15. In some embodiments, the CTE of base 50 matches the CTE of semiconductor substrate 15 more closely than the CTE of chip carrier 80 matches the CTE of semiconductor substrate 15. Chip carrier 80 defines recess 82. Foot 84 bounds a bottom of recess 82. Foot 84 and chip carrier 80 may be composed of identical or different materials.
Recess 82 is adapted to receive packaging 40. Packaging 40 may mount within recess 82 via any bonding agent mentioned herein. In some embodiments, packaging 40, and more particularly base 50, is coupled to foot 84. The material of carrier 80 may provide a low thermal resistance path for cooling packaging 40 during operation. The material may also be yielding so as to absorb mechanical deflections of packaging 40. According to some embodiments, foot 84 is substantially less thick than packaging 40 and therefore the stiffness of packaging 40 dominates the stiffness of foot 84 when subjected to mechanically distorting forces.
Chip carrier 80 also includes conducting pads 86 for transmitting electrical signals to the imaging elements of microdisplay IC 10. Conducting pads 86 may be soldered onto chip carrier 80 and may also be fabricated thereon. In some embodiments, wire bonds couple conducting pads 86 to the imaging elements of microdisplay IC 10.
Control chip 88 may include driving elements for driving the imaging elements of microdisplay IC 10. Control chip 88 may also include an interface to an external source for receiving pixel image data from the source. The interface may also be used to receive and transmit signals used to synchronize the operation of microdisplay IC 10 with other elements of a display system.
Bonding agent 90 is depicted as thermal tape but may comprise any other agent for coupling heat sink 100 to chip carrier 80. Bonding agent 90 may contact at least a portion of foot 84 and heat sink 100. In such a case, a high thermal conductivity path may be established between microdisplay IC 10 and heat sink 100. Moreover, bonding agent 90 may provide mechanical isolation of microdisplay 10 from any differential expansion of heat sink 100.
Packaging 120 includes chip carrier 130, which in turn defines opening 135. Other elements of chip carrier 120 except may be identical to elements of chip carrier 80. Packaging 40 may be mounted within opening 135 via friction, a bonding agent, and/or mechanical elements (not shown). Bonding agent 90 may be coupled directly to base 50 and to heat sink 100, thereby possibly providing more efficient heat dissipation than some embodiments such as packaging 70.
At least a portion of the upper surface of semiconductor substrate 220 comprises bonding surface 230. As will be described in more detail, bonding surface 230 may be coupled to an associated portion of a chip carrier. Bonding surface 230 may be coated with a material suitable for bonding microdisplay IC 200 to a chip carrier. Bonding surface 230 comprises conductors 240 to carry electrical signals to the imaging elements of microdisplay IC 200. Bonding surface 230 and conductors 240 may be fabricated onto substrate 220 using currently- or hereafter-known fabrication techniques.
Initially, at 301, at least one set of imaging elements is fabricated on an upper surface of a semiconductor substrate.
A lower surface of wafer 310 is ground at 302 to reduce its thickness. In some embodiments, grinding yields a thin and relatively pliable wafer that may be 0.1 mm or less in thickness. The grinding may also allow wafer 310, which may not be flat and which may include residual mechanical stresses resulting from the fabrication process, to conform to a flat base.
A base is affixed to a lower surface of semiconductor wafer 310 at 303.
Base 320 may be affixed to wafer 310 so as to generate substantially negligible mechanical stress therebetween when the imaging elements are operated within a range of operating temperatures. According to some embodiments of this aspect, an epoxy is applied to one of base 320 and lower surface 315 of wafer 310. Base 320 and surface 315 are brought into contact with one another while at a temperature equal to at least one operating temperature of the imaging elements of wafer 310. When at such a temperature, wafer 310 and base 320 may expand (or contract) according to their respective CTEs. The epoxy is then cured at at least one operating temperature of the imaging elements. The curing may be a partial curing, with a final curing subsequently occurring at a higher temperature.
Process 300 may thereby result in unit 350 of
Due to their different CTEs, the interface of wafer 310 and base 320 may be subjected to significant mechanical stresses at other temperatures. These stresses may cause the unit comprised of wafer 310 and base 320, and the individual sub-units to warp into a substantially non-flat shape.
According to other embodiments of 303, base 320 is affixed to wafer 310 to substantially flatten wafer 310.
The previously-described embodiments of 303 may be combined with the present embodiment. Particularly, wafer 360 may be affixed to base 320 while at a temperature equal to at least one operating temperature of the imaging elements of wafer 360. Such a combination may reduce an amount of mechanical stress at an interface of wafer 360 and base 320 during operation of the imaging elements.
The unit resulting from process 300 may be diced into individual sub-units comprising a microdisplay IC coupled to a portion of base 320. These units may be more mechanically rigid than prior microdisplay IC packages. Moreover, each portion of base 320 may be configured to include a flex cable interface and electrical connections for delivering signals from flex cable to the imaging elements of an associated microdisplay IC.
Light source 402 provides light to display system 400. Light source 402 may comprise a 100W-500W lamp such as a metal halide lamp or an Ultra High Pressure (UHP) arc lamp. The light is received by lens 404, which transmits a uniform beam of light to optics 406. Optics 406 may include a dichroic filter for removing non-visible light from the beam of light. Optics 406 may also include one or more mirrors, color filters, and prisms for directing selected spectral bands of light to microdisplay package(s) 70.
Generally, optics 406 may project separate spectral bands of light (e.g., red, green, or blue light) to microdisplay package(s) 70. In some embodiments using three microdisplay packages 70, pixel imaging elements 25 of each microdisplay package 70 are set to imaging states that correspond to pixel intensities of red, green, or blue components of an image. Optics 406 project a corresponding spectral band onto each microdisplay package 70, receive reflected light that represents each of the three components of the image from the microdisplay packages 70, combine the reflected light into a single full-color image, and transmit the image to projector lens 408.
Projector lens 408 receives the transmitted image, which may measure less than an inch across. Projector lens 408 may magnify, focus, and project the image toward a projection screen (not shown). Display system 400 may be located on a same side of the projector screen as the intended audience (front projection), or the screen may be located between the audience and display system 400 (rear projection).
The several embodiments described herein are solely for the purpose of illustration. Embodiments may include any currently or hereafter-known versions of the elements described herein. Therefore, persons skilled in the art will recognize from this description that other embodiments may be practiced with various modifications and alterations.
Number | Name | Date | Kind |
---|---|---|---|
4905021 | Iizuka et al. | Feb 1990 | A |
5118361 | Fraas et al. | Jun 1992 | A |
5508740 | Miyaguchi et al. | Apr 1996 | A |
5600148 | Cole et al. | Feb 1997 | A |
5919329 | Banks et al. | Jul 1999 | A |
5997152 | Taninaka et al. | Dec 1999 | A |
6081305 | Sato et al. | Jun 2000 | A |
6187605 | Takasu et al. | Feb 2001 | B1 |
6494371 | Rekow et al. | Dec 2002 | B1 |
6556261 | Krusius et al. | Apr 2003 | B1 |
6556269 | Takiar et al. | Apr 2003 | B1 |
6590346 | Hadley et al. | Jul 2003 | B1 |
6610997 | Murade | Aug 2003 | B2 |
6639714 | Smith et al. | Oct 2003 | B2 |
6720206 | Choi | Apr 2004 | B2 |
6773958 | Wang | Aug 2004 | B1 |
6816385 | Alcoe | Nov 2004 | B1 |
6825059 | Fossum | Nov 2004 | B2 |
6891194 | Izumi | May 2005 | B2 |
6894853 | Haskett et al. | May 2005 | B2 |
6933604 | Sakamoto et al. | Aug 2005 | B2 |
6975512 | Ooi | Dec 2005 | B1 |
7034785 | Koma | Apr 2006 | B2 |
20010030725 | Shinohara et al. | Oct 2001 | A1 |
20020000630 | Coyle | Jan 2002 | A1 |
20020004251 | Roberts et al. | Jan 2002 | A1 |
20020101557 | Ono et al. | Aug 2002 | A1 |
20020149312 | Roberts et al. | Oct 2002 | A1 |
20020163006 | Yaganandan et al. | Nov 2002 | A1 |
20030095116 | Koyama | May 2003 | A1 |
20030136962 | Miyajima et al. | Jul 2003 | A1 |
20030213956 | Hioki et al. | Nov 2003 | A1 |
20040084778 | Hosoda et al. | May 2004 | A1 |
20040197967 | Chen | Oct 2004 | A1 |
20040222516 | Lin et al. | Nov 2004 | A1 |
20040234213 | Narayan et al. | Nov 2004 | A1 |
20050045974 | Hellekson et al. | Mar 2005 | A1 |
20050052606 | Lee et al. | Mar 2005 | A1 |
20050062167 | Huang et al. | Mar 2005 | A1 |
20050077616 | Ng et al. | Apr 2005 | A1 |
20050087754 | Erchak | Apr 2005 | A1 |
20050093134 | Tarn | May 2005 | A1 |
20050121768 | Edelstein et al. | Jun 2005 | A1 |
20060055864 | Matsumura et al. | Mar 2006 | A1 |
20060205102 | French et al. | Sep 2006 | A1 |
Number | Date | Country | |
---|---|---|---|
20050146003 A1 | Jul 2005 | US |