This application is based upon and claims the benefit of priority of the prior Japanese Patent Application No. 2013-128527, filed on Jun. 19, 2013, the entire contents of which are incorporated herein by reference.
The embodiments discussed herein are related to a receiver circuit and to a receiving method.
It is demanded that the speed of signal transmission between LSI chips or a plurality of circuit blocks within housings and between the housings be increased.
A related art is disclosed in Japanese Laid-open Patent Publication No. 2004-312292 or in C. Ting, et al., “A Blind Baud-Rate ADC Based CDR”, ISSCC 2013, Session 7, Optical Transceivers and Silicon Photonics, 7.4.
According to an aspect of the embodiments, a receiver circuit includes: an input ADC configured to convert an input data signal to sample data in accordance with a clock; a boundary phase computation circuit configured to determine the boundary phase of the input data signal based on the sample data; an eye pattern computation circuit configured to compute a maximum amplitude phase of an eye pattern of the input data signal based on the sample data and the boundary phase; and a determination circuit configured to determine a value of the input data signal in the maximum amplitude phase based on the sample data and the maximum amplitude phase.
The object and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the claims.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, as claimed.
For improvement of system performance, it may be demanded that the performance of a memory, a processor, a switching LSI part, or the like and the speed of signal transmission between such parts be enhanced (an increase in a transmission capacity measured in bits per second and a decrease in the latency of transmission may be demanded). For example, an increase in the rate of signal transmission between a processor and memories, such as an SRAM and a DRAM, improves the performance of a computer (server). For servers and other devices, it is demanded that the data rate of intra-device and inter-device signal transmission/reception be increased in accordance with the improvement of performance of information processing devices such as communication backbone devices.
Data rates of I/Os of many integrated circuits may increase to a level between several gigabits per second and tens of gigabits per second in order to meet a demand for data rate enhancement. In a high-performance device, a large number of I/O ports having such a high data rate may be integrated into a single integrated circuit. High-speed I/Os include many analog circuits such as an amplifier circuit, an equalizer, or a timing generator circuit. However, the analog circuits may be replaced by digital circuits in order to provide increased ease of design and integrate many I/Os.
An input data signal, for example, received data, may be converted to digital data by an analog-to-digital converter and subjected to signal processing, such as equalization and timing generation, by digital circuits. A receiver circuit having the analog-to-digital converter reduces process variations or operating-temperature-induced changes in characteristics. Further, design productivity may be high because signal processing is mainly performed by the digital circuits. For example, the receiver circuit determines the phase relationship between a clock signal and received data from sample data that is sampled with a certain clock signal. In accordance with the determined phase relationship, the value of the received data in an optimum phase for distinguishing between 0 and 1 is interpolation-calculated and generated. Consequently, the value of the received data is determined in an appropriate phase even if a phase adjustment circuit having an analog-circuit-based clock generator circuit is not used.
Interpolated data of the received data is calculated on the assumption that the optimum phase for distinguishing between 0 and 1 is a phase shifted by a ½ unit interval (UI) from a transition timing at which the received data passes through an intermediate level. The optimum phase may not be the phase shifted by a ½ UI depending on the characteristics of an employed transmission line. The value of the received data, which is calculated in the phase that is shifted by a ½ UI, may not be an optimum value. Hence, the degradation of an error rate (BER) or a decrease in an operating speed may result.
Referring to
The receiver circuit depicted in
In accordance with a boundary code and data code output from the CRU 20, the second PI 13 generates, from the four phase reception clock signals, a clock signal and ½ UI shift clock signal that agree with the boundary of the received data Din.
The analog equalizer circuit 14 performs analog processing so as to equalize the input data signal Din. The ADC 15A samples the output of the analog equalizer circuit 14 in synchronization with the clock signal that agrees with the boundary output from the second PI 13, and converts the sampled output to boundary sample data. The ADC 15B samples the output of the analog equalizer circuit 14 in synchronization with the ½ UI shift clock signal output from the second PI 13, and converts the sampled output to ½ shift sample data. The above circuits may be analog processing circuits.
The DEMUX 16 converts the output of the ADCs 15A, 15B to parallel data. The CRU 20 includes a digital equalizer circuit 21, a phase detector (PD) 22, a filter 23, an adder circuit 24, an offset register 25, and a decision circuit (comparator) 26.
The digital equalizer circuit 21 performs digital processing so as to equalize sample data received from the DEMUX 16. The PD 22 detects difference data, which corresponds the phase difference between a boundary clock signal and the input data signal, from the sample data. The filter 23 performs averaging processing on the difference data of the PD 22 and outputs a boundary code in order to reduce a timing error. The adder circuit 24 adds an offset value that is stored in the offset register 25 and corresponds to a ½ shift amount to the boundary code, and outputs a data code. The decision circuit 26 checks whether the ½ shift sample data included in the output from the digital equalizer circuit 21 is greater than a reference value, determines the value of the input data signal, and recovers the data.
The receiver circuit depicted in
As mentioned above, if a clock signal subjected to a ½ UI phase shift is not in an optimum sampling phase, an offset amount may be set to a value different from a ½ UI phase shift amount. For example, an optimum offset amount may be determined during a period during which no actual operation is performed, for example, during a period of initialization, and stored as a fixed value. If, for instance, the phase of a data sampling clock is adjusted during an actual operation, the deviation from the optimum phase may become significant to cause an error.
The clock source (clk) 31 outputs a sampling clock signal that is to be used for reception processing. The frequency of the sampling clock signal may be approximate to that of the input data signal (received data) and irrelevant to the timing of the received data. For example, the receiver circuit depicted in
As depicted in
For example, in the receiver circuit depicted in
The blind CDR method makes it possible to calculate received data in an arbitrary phase from an ADC output without changing a sampling clock phase. Therefore, the blind CDR method may differ from a tracking CDR method.
In the receiver circuit, an interpolation process may be performed to estimate data between a plurality of sample data.
An interpolation computation section interpolation-computes the received data in an arbitrary phase φAVG based on the phase φAVG and a series of sample data a-d output from the ADC 32, for example, based on the interpolation arithmetic expression depicted in
The broken line in
For example, performing higher-order interpolation may reduce the error between an interpolated value and the actual waveform indicated by the broken line in
The interpolation arithmetic expression depicted in
Referring to
Using the interpolation arithmetic expression depicted in
The ADC 32 depicted in
The DI_B 33 depicted in
The B-B PD 34, which may be a boundary phase detection circuit, determines relevant transition time (phase) from boundary data. The filter 35 computes the transition (boundary) phase of the waveform of the input data signal (received data) by determining the average value of the boundary phase from the B-B PD 34.
The computed boundary phase is fed back to the DI_B 33. The DI_D 36, which may be a digital interpolation processing section for data, interpolates sample data output from the ADC 32, and determines the data value of a data phase output from the adder circuit 42. The DI_D 36 may perform an interpolation computation based on a plurality of adjacent sample data in accordance by using the interpolation arithmetic expression depicted in
The comparator 37 checks whether the data value in the maximum amplitude phase, which is derived from the interpolation computation performed by the DI_D 36, is greater than a reference value, determines the value of the input data signal, and outputs the determined value as output data Dout.
The control circuit 41 calculates the degree of voltage waveform (eye pattern) opening in an arbitrary phase from the sample data output from the ADC 32 and the boundary phase output from the filter 35, and determines a phase offset θ0(K) from which the maximum value (maximum amplitude) is obtained.
The adder circuit 42 adds the phase offset output from the control circuit 41 to the boundary phase output from the filter 35, and outputs a data phase that is the maximum amplitude phase.
The DI_Arb 51 performs interpolation processing by using the interpolation arithmetic expression depicted in
In accordance with the sample data and the boundary phase information, the control circuit 41 performs an interpolation computation to obtain the value of the received data (amplitude) while changing the phase offset, and determines a phase, which provides the maximum amplitude, as the maximum amplitude phase.
The phase providing the maximum amplitude value may be predicted to some extent from the sample data and the boundary phase. For example, it may be estimated that the phase providing the maximum amplitude value exists in the proximity of a phase intermediate between adjacent boundary phases and in the proximity of sample data having the maximum value among a plurality of sample data. Hence, three amplitudes, for example, the amplitude of a certain phase in the vicinity of the phase to be estimated, the amplitude of a phase preceding the certain phase, and the amplitude of a phase succeeding the certain phase, may be determined. Further, when the amplitude of the central phase is maximized, the central phase may be set as the maximum amplitude phase. If the amplitude of a phase on one side is great, the amplitude of a phase adjacent to the phase on the one side may be determined to determine a phase that provides the maximum value.
The control circuit 41 may operate even during signal transmission and continually set the optimum phase (background phase adjustment). Alternatively, the control circuit 41 may operate once during initialization for the start of signal transmission to set the optimum phase and subsequently retain that optimum phase.
The receiver circuit computes the received data in an arbitrary phase while changing the phase, and uses the received data in a phase that provides the greatest amplitude. The error rate may be improved or the receiver circuit may operate at an increased speed.
All examples and conditional language recited herein are intended for pedagogical purposes to aid the reader in understanding the invention and the concepts contributed by the inventor to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions, nor does the organization of such examples in the specification relate to a showing of the superiority and inferiority of the invention. Although the embodiment of the present invention has been described in detail, it should be understood that the various changes, substitutions, and alterations could be made hereto without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
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2013-128527 | Jun 2013 | JP | national |
Number | Name | Date | Kind |
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4475220 | Mattei et al. | Oct 1984 | A |
7295601 | Sinha et al. | Nov 2007 | B1 |
20140039823 | Raghupathy et al. | Feb 2014 | A1 |
Number | Date | Country |
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2004-312292 | Nov 2004 | JP |
Entry |
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Ting, et al., “A Blind Baud-Rate ADC-Based CDR,” ISSCC 2013, Session 7, Optical Transceivers and Silicon Photonics, 7.4, pp. 122-124. |
Number | Date | Country | |
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20140376675 A1 | Dec 2014 | US |