4. Electronic digital logic circuitry
  5. Multifunctional or programmable
  6. Array

Field programmable optical arrays

Electronic digital logic circuitry – Multifunctional or programmable – Array

Reexamination Certificate

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Details

C326S047000, C370S539000, C385S017000, C385S024000, C385S016000

Reexamination Certificate

active

06583645

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to semiconductor integrated circuit devices, more particularly to forming a field programmable gate array using optical signals and optical switches rather than or in combination with electrical signals and electrical switches.
BACKGROUND
As field programmable logic devices have become larger and more complex, there has been continuing demand for faster and lower power processing of signals. Until the present, the internal signals in a field programmable integrated circuit device as well as many other integrated circuit devices have been electrical signals carried by conductive metal or polysilicon lines. Transmission speed of these electrical signals is considerably slower than the speed of light. Thus, theoretically, the transmission speed can be increased.
A good overview of the state of the art of optical networking technology and components is provided by the textbook authored by Ramaswami and Sivarajan titled “Optical Networks: a Practical Perspective” (1998).
It is known to form optical conductors within integrated circuit devices. For example, as shown in
FIG. 1
, a well is formed in a semiconductor substrate comprised of an opaque material, typically gallium arsenide or indium phosphide. The well is then filled with a glass (SiO
2
) or glass-like material. A top layer of opaque material is then deposited over the glass material to form a waveguide. Wave guides typically have a width on the order of 1.8 microns.
It is also known to form optical switches within integrated circuit devices. By bringing wave guides close together, it is possible to use electrical potential to control switching between one wave guide and the other.
FIGS. 2A and 2B
shows such structures. In
FIG. 2A
, two wave guides
22
,
24
of the type just described are manufactured to have coupling sections very close together so that there is a thin opaque wall
27
made of semiconductor material between the two wave guides. Typically the two wave guides will be laid out close to each other in region
26
for a length L, known as the coupling length, where the exact value of the coupling length depends on process technology. As discussed in U.S. Pat. No. 6,259,834, the strength of the coupling is characterized by a coupling coefficient k such that in a distance j=&pgr;/2k all of the optical energy entering waveguide
22
is transferred by this coupling to waveguide
24
. If the coupling length L is equal to j, then with no voltage applied between the two waveguides, all optical energy is transferred.
The coupler works as follows. Assume light is traveling from left to right within wave guides
22
,
24
(light can of course travel in either direction). Because of quantum mechanical effects, light traveling in waveguide
22
can be transmitted through the thin opaque wall into waveguide
24
. By applying an electric field to electrodes
42
and
44
at the junction of the two wave guides in region
26
, the transmittance of light through the thin opaque wall
27
can be changed. Applying electric potential can cause anything from no transmission to full transmission to occur through the thin opaque wall
27
. In this manner, an electric field can be applied which will cause some or all of the light in channel
22
to be transmitted into channel
24
, where it will continue to propagate down the second waveguide. Light signals can travel simultaneously in both channels and be coupled by different amounts if other signals in the channels have different wavelengths. An opposite electric field can be applied to the thin opaque wall
27
, which will cause no light to be transmitted from waveguide
22
into waveguide
24
. In this case, light in waveguide
24
will simply propagate unchanged.
Since light can be divided between the two wave guides
22
and
24
, the optical coupler of
FIG. 2B
can serve to fan out a signal from terminal
3
to terminals
1
and
2
, as junctions in electrical wires are well known to do. Similarly, when light is propagated in the opposite direction, the structure of
FIG. 2B
can be used as a multiplexer, whereby voltages on electrodes
23
and
25
select which of the signals on terminals
1
and
2
is propagated to terminal
3
.
FIG. 3
shows another coupler. In this coupler, there are two wave guides
28
,
30
running parallel to each other, which are coupled by a resonant disc
32
that is bonded on top of the two wave guides. Light in one waveguide is transferred to the second waveguide through the resonant disc. Details of this light transfer and its control are described in IEEE Photonics Technology Letters, vol. 11, no. 8, August 1999, pages 1003-1005, and are not repeated here.
Micromirrors are also known for selecting optical pathways as in a multiplexer.
FIG. 4
shows such a structure. The multiplexer is made from three 2:1 optical switches
42
,
44
, and
46
, that are controlled by electrical signals to pass optical signals. The three switches
42
,
44
, and
46
are constructed in the same way. Optical switch
42
has two inputs
48
,
50
, one output
52
, and a control block
54
for altering which input signal is transmitted to the output. Switch
46
has two inputs
58
,
60
, an output
62
, and a control block
64
. Switch
44
has two inputs
66
,
68
, an output
70
, and a control block
72
. Output
52
of switch
42
is connected to input
58
of switch
46
, output
70
of switch
44
is connected to input
60
of switch
46
, and the four inputs
48
,
50
,
66
,
68
comprise the inputs to the 4:1 multiplexer with output
62
comprising the output of the 4:1 multiplexer. A static random access memory
56
provides control signals to the control blocks of each switch. By appropriately setting the values in SRAM
56
, any of the four optical input signals can be selected to be transmitted to the output of the 4:1 multiplexer. By adding additional 2:1 switches it is possible to create an N:1 optical switch multiplexer. Thus electrical signals control optical signals.
It is also known to use optical signals within an integrated circuit device to generate electrical signals. Torazawa in U.S. Pat. No. 6,259,308 describes an optical coupling semiconductor switching circuit with a light detector that receives a signal from a light emitting device and generates a voltage across an impedance circuit. Thus an electrical signal is generated from an optical signal.
U.S. Pat. No. 6,016,211 describes an opto-electronic array that receives optical signals at its inputs, converts those signals to electronic signals for switching purposes, switches the electronic signals appropriately, and then reconverts the electronic signals back to optical signals at its output. This has the advantage of providing flexibility in signal switching contained within the relatively small space of an integrated circuit device. But there is a loss of speed in comparison to maintaining the signals as optical signals.
It would be desirable to implement an FPGA that uses optical switching in an architecture having logic blocks, programmable interconnect lines and input/output blocks, where as many data signals as possible are carried optically for maximum speed and low power.
SUMMARY
According to the invention, an FPGA-like architecture uses data paths formed almost entirely of optical switches and optical channels, and control of the switches using electrical signals. This combination makes for both high speed data transmission and highly flexible configuration.
A typical FPGA uses lookup tables to provide a function of several (for example four) input signals. In order to provide the high speed of an optical device, the input signals must be optical, the output signal must be optical, and reading of a value from a lookup table must be done quickly.
According to the invention, the lookup table accesses optical signals (in one embodiment, a lookup table includes 16 switches for accessing optical signals, and one of the switches is selected by four input signals). The four input signals are electrical signals generated by

Bennett David W.

Inventor

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Mohan Sundararajarao

Inventor

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Wittig Ralph D.

Inventor

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Brown Scott R.

Attorney

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Tan Vibol

Examiner

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Tokar Michael

Examiner

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Xilinx , Inc.

Corporate Assignee

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Young Edel M.

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