Claims
- 1. A receiver circuit, comprising:
a differential analog feed forward equalizer (FFE) circuit for receiving a dispersion distorted analog signal and processing the received signal to generate an equalized analog data signal (dispersion compensated signal), the FFE being a finite impulse response (FIR) filter with adjustable tap weights, the tap weights having been set to provide dispersion compensation of the signal; and a differential clock and data recovery (CDR) circuit for receiving the equalized analog data signal and processing the received equalized analog data signal to generate a recovered clock signal and a retimed digital data signal, wherein the signals are differential signals, comprising the dispersion distorted analog signal; the equalized analog data signal; a signal providing the tap weights; the recovered clock signal; and the retimed digital data signal.
- 2. A receiver as described in claim 1, wherein the FFE circuit comprises:
a differential tapped delay line having a delay line input, “n−1” delay elements and “n” output taps, the delay line receiving the dispersion distorted analog signal at the delay line input and producing progressively delayed signals at the output taps; “n” differential analog multipliers, each having a multiplier signal input connected to the respective output tap of the delay line, a tap weight input and a multiplier output, producing a multiplied signal which is a product of the respective progressively delayed signal and the corresponding tap weight; a summing tree having at least two layers of differential analog adders, each adder having at least two adder inputs and an adder output; the first layer of adders having collectively at least “n” adder inputs connected to the outputs of the “n” differential multipliers; and each subsequent layer of adders having collectively a sufficient number of adder inputs to connect to the adder outputs of the preceding layer; the last layer of differential adders having a single adder, the output of said single adder being the FFE circuit output providing the equalized analog data signal, which is a sum of the “n” multiplied signals.
- 3. A receiver circuit as described in claim 2, wherein the physical layout of the FFE circuit is arranged so that the propagation delay from each of the “n” output taps of the delay line to the FFE circuit output is substantially the same.
- 4. A receiver circuit as described in claim 3, wherein the first layer of adders has collectively “n” adder inputs; and each subsequent layer of adders has collectively the same number of adder inputs as the number of adder outputs of the preceding layer.
- 5. A receiver circuit as described in claim 4, wherein the physical layout of the FFE circuit is arranged so that the lengths of interconnecting tracks between corresponding elements of the delay line and the “n” multipliers are substantially equal, and the lengths of interconnecting tracks between the outputs of the multipliers and inputs of the first layer adders are substantially equal, and the lengths of interconnecting tracks between the adder inputs of each subsequent layer of adders and the adder outputs of the preceding layer of adders are substantially equal.
- 6. A receiver circuit as described in claim 2, wherein each delay element of the differential tapped delay line introduces substantially the same delay.
- 7. A receiver circuit as described in claim 6, wherein the FFE circuit has two layers of adders, and each adder has “a” adder inputs, wherein a α≅{square root}{square root over (n)}, and “a” and “n” are integers.
- 8. A receiver circuit as described in claim 7, wherein n=9 and a=3.
- 9. A receiver as described in claim 1, wherein the FFE circuit comprises:
a differential tapped delay line having a delay line input, “n−1” delay elements and “n” output taps, the delay line receiving the dispersion distorted analog signal at the delay line input and producing progressively delayed signals at the output taps; “n” differential analog multipliers for multiplying the respective delayed signals with corresponding tap weights into “n” multiplied signals; a balanced summing tree having a plurality of differential analog adders for summing said “n” multiplied signals into the equalized analog data signal at the output of the summing tree, which is the output of the FFE; the balanced summing tree being arranged so that each multiplied signal is passing through the same number of adders before reaching the output of the FFE.
- 10. A receiver circuit as described in claim 1, wherein the FFE circuit comprises a differential tapped delay line having a plurality of passive delay elements, each delay element being a segment of a transmission line made of a pair of metal strips in the shape of a meander having folds; the transmission line being formed in a single layer and further having grounded posts inserted in the folds of the meander in said single layer; and a ground plane in another metal layer insulated from said single layer.
- 11. A receiver circuit as described in claim 10, wherein said single layer is the metallization layer providing the thickest metal of the substrate accommodating the FFE circuit.
- 12. A receiver circuit as described in claim 11, wherein said single layer is the top metallization layer of the substrate.
- 13. A receiver as described in claim 1, wherein the FFE circuit comprises:
a differential tapped delay line having a delay line input, “n−1” delay elements and “n” output taps, the delay line receiving the dispersion distorted analog signal at the delay line input and producing progressively delayed signals at the output taps, which inherently have progressively diminishing signal bandwidth; “n” differential multipliers for multiplying the respective delayed signals with corresponding tap weights into “n” multiplied signals; a selected number of the differential multipliers having means for partly or substantially compensating the diminishing signal bandwidth.
- 14. A receiver circuit as described in claim 13, wherein the FFE circuit further comprises a plurality of differential analog adders for summing said “n” multiplied signals into the equalized analog data signal at the output of the FFE; a selected number of the differential adders having means for substantially compensating the diminishing signal bandwidth, which remains after bandwidth compensation provided by the differential multipliers.
- 15. A receiver circuit as described in claim 1, the circuit being formed on a single semiconductor substrate.
- 16. A receiver circuit as described in claim 1, the circuit being manufactured in bipolar technology.
- 17. A receiver circuit as described in claim 1, the circuit being manufactured in MOSFET technology.
- 18. A differential analog feed forward equalizer (FFE) circuit, comprising:
a differential tapped delay line having a delay line input, “n−1” delay elements and “n” output taps, the delay line receiving a distorted analog signal at the delay line input and producing progressively delayed signals at the output taps; “n” differential analog multipliers, each having a multiplier signal input connected to the respective output tap of the delay line, a tap weight input and a multiplier output, producing a multiplied signal which is a product of the respective progressively delayed signal and the corresponding tap weight; a summing tree having at least two layers of differential analog adders, each adder having at least two adder inputs and an adder output; the first layer of adders having collectively at least “n” adder inputs connected to the outputs of the “n” differential multipliers; and each subsequent layer of adders having collectively a sufficient number of adder inputs to connect to the adder outputs of the preceding layer; the last layer of differential adders having a single adder, the output of said single adder being the FFE circuit output providing an equalized analog data signal (compensated signal), which is a sum of the “n” multiplied signals.
- 19. A differential analog feed forward equalizer (FFE) circuit, comprising:
a differential tapped delay line having a delay line input , “n−1” delay elements and “n” output taps, the delay line receiving a distorted analog signal at the delay line input and producing progressively delayed signals at the output taps; “n” differential analog multipliers for multiplying the respective delayed signals with corresponding tap weights into “n” multiplied signals; a balanced summing tree having a plurality of analog adders for summing said “n” multiplied signals into an equalized analog data signal (compensated signal) at the output of the summing tree, which is the output of the FFE; the balanced summing tree being arranged so that each multiplied signal is passing through the same number of adders before reaching the output of the FFE.
- 20. A FFE circuit as described in claim 19, the circuit being manufactured on a single substrate in one of the MOSFET and bipolar technology.
- 21. A semiconductor device, comprising a receiver circuit as described in claim 1.
- 22. A receiver circuit as described in claim 1, the circuit being manufactured in an electronic package.
- 23. A circuit board, comprising a receiver circuit as described in claim 1.
RELATED APPLICATIONS
[0001] The present application claims the benefit of U.S. Provisional Application Ser. No. 60/479,459 to Popescu et al, filed on Jun. 19, 2003, and entitled “High Speed Circuits for Electronic Dispersion Compensation (EDC)”.
[0002] The present application is related to the U.S. patent application Ser. No. ______ entitled “High Speed Circuits for Electronic Dispersion compensation” to Popescu et al, and the U.S. patent application Ser. No. ______ entitled “A Differential Receiver Circuit with Electronic Dispersion Compensation” to Popescu, Gradinaru et al, filed concurrently herewith and incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60479459 |
Jun 2003 |
US |