In one embodiment, the present invention includes a de-serializer to receive serial data at a first rate and to output a parallel data frame corresponding to the serial data aligned to a frame alignment boundary in response to a phase control signal received from a feedback loop coupled between the de-serializer and a receiver logic coupled to an output of the de-serializer. Other embodiments are described and claimed.
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17. A system comprising:
a transmitter to transmit serial data to a receiver via a link; and
the receiver to receive the serial data and including:
a de-serializer to receive the serial data and to output therefrom a parallel data frame aligned to a frame alignment boundary in response to a phase control signal; and
a receiver logic coupled to the de-serializer to receive the parallel data frame from the de-serializer, wherein the receiver logic is to feedback the phase control signal to the de-serializer.
1. An apparatus comprising:
a de-serializer to receive serial data at a first rate and to output a parallel data frame corresponding to the serial data and having a bit width of N, wherein the de-serializer is to output the parallel data frame aligned to a frame alignment boundary in response to a phase control signal; and
a receiver logic coupled to the de-serializer to receive the parallel data frame from the de-serializer, wherein the receiver logic is to feedback the phase control signal to the de-serializer.
10. A method comprising:
receiving serial data in a de-serializer of a receiver;
converting the serial data to parallel data and providing the parallel data unaligned to a frame boundary from the de-serializer to a digital logic of the receiver;
receiving a load strobe signal in the de-serializer from the digital logic based on determination of the frame boundary in the digital logic; and
thereafter providing the parallel data from the de-serializer to the digital logic that is aligned to the frame boundary responsive to the load strobe signal.
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a frame boundary detector to receive the parallel data frame and to determine the frame alignment boundary based on a data pattern of the parallel data frame and to provide a digital set delay signal and a digital reset delay signal responsive to the detection;
a delay set circuit to generate a set signal and a reset signal both having a first state for a selected one of the plurality of flops of the output circuit, wherein the delay set circuit includes a first flop and a second flop, the first flop to receive the digital set delay signal at a set input and the second flop to receive the digital reset delay signal at a set input, wherein a data input to the first and second flops is at a predetermined logic level; and
a phase control circuit to generate the phase control signal at an output of a selected one a ring of flops responsive to receipt of the set signal and the reset signal of the first state by one of the ring of flops.
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In many communication protocols for computer and other systems, a high speed serial receiver is used to recover an incoming analog signal, e.g., received from an input line, and convert the obtained serial data stream into parallel frames. De-serialization is performed to convert the serial stream to parallel form so that it can be handled at lower speeds. In a conventional alignment process to align the serial stream to the correct frame alignment, the recovered data is accumulated and N alignment hypotheses (where N is the number of bits in a frame) are checked in digital circuitry to determine the correct alignment. Therefore, a processing latency of up to N−1 bits is introduced. The exact latency depends on the arbitrary timing difference between the two link partners, which can change on every link establishment.
A serial receiver typically includes an analog front end that processes the serial signal at high rate, a serial-to-parallel conversion block (de-serializer), and logic circuitry which processes the parallel data at a lower speed. Parallelization may be performed using a clock with an arbitrary phase. This arbitrary clock is not synchronized to a frame boundary. Therefore, when using a conventional digital alignment procedure it is required to take into account a processing latency of N−1 bits, which might be significant. As an example, in current communication protocols the frame width can exceed 100 bits. For example, the Peripheral Component Interconnect Express (PCI) Third Generation (Gen3) frame width is 130 bits and 10GBASE-KR frame width is 66 bits.
In various embodiments, a low latency architecture may be provided for high-speed serial devices. Embodiments may avoid a de-serialization associated latency by aligning an analog front end of a receiver to a frame boundary. That is, in various embodiments the de-serializer itself may output parallel data in frames that are aligned with a frame alignment boundary. In this way, the need for digital alignment can be avoided, and furthermore latency introduced by performing frame alignment in digital logic can be avoided. While the scope of the present invention is not limited in this regard, in some embodiments the receiver may be of a high speed serial physical (PHY) device.
Referring now to
As seen in
Thus as further seen in
As further seen in
Thus embodiments may control a de-serializer clock to ensure that it is aligned to the frame boundary. In one embodiment, this frame-aligned clock can be obtained by defining a dedicated serial-to-parallel architecture that supports such clock alignment, and a logic mechanism to set the desired clock phase. In this way, the de-serializer can cut the serial data into parallel frames in all possible alignments, while supporting alignment changes on-the-fly. While the scope of the present invention is not limited in this regard, the logic to set the desired clock phase may be based on a frame boundary search used for performing digital frame alignment. However, in this case a closed alignment loop may be coupled between receiver logic and the analog de-serializer, and thus a latency can be avoided. In this way, the digital logic is only responsible for monitoring the data and defining the required alignment, while the actual datapath alignment takes place in the analog domain.
De-serialization in accordance with an embodiment of the present invention may be based on a flexible parallelism of an incoming serial data stream. More specifically, de-serialization may be performed using a clock signal that has a phase controlled by a feedback circuit of the receiver logic. Although the scope of the present invention is not limited in this regard, this feedback circuit may operate to determine and set a delay responsive to received data to cause the de-serialization clock to operate and output a parallel data stream aligned to the frame alignment boundary.
Referring now to
In addition, logic 200 includes a feedback circuit 215 which may include various components in different embodiments. In general, feedback circuit 215 may operate to generate a phase control signal, also referred to herein as a load strobe signal, which is provided in a feedback path to the de-serializer to enable the de-serializer to output the parallel bitstream aligned to the frame alignment boundary.
In the implementation of
As seen, frame boundary detector 220 may receive the incoming parallel bitstream. In general, frame boundary detector 220 may operate to determine the correct frame alignment boundary. While the scope of the present invention is not limited this regard, frame boundary detector 220 may include one or more sensor circuits to compare an incoming parallel bitstream with a predetermined data pattern to identify a correct frame alignment boundary. To speed processing, more than one such sensor circuit may be present within frame boundary detector 220. For purposes of determining the correct phase at which to cut the data in the de-serializer, frame boundary detector 220 may output two sets of data, namely first and second set delay bitstreams. Specifically in the embodiment of
As seen in
These set and reset bit streams may be provided to a phase control circuit 240. In various embodiments, phase control circuit 240 may operate to generate a phase control signal, which may identify the location in the incoming serial bitstream received by de-serializer at the frame alignment boundary, enabling output of the parallel bit datastream that is aligned to the frame alignment boundary. Thus in various embodiments, the phase control signal may be a signal that acts as an output clock signal for the de-serializer. While shown with this particular implementation in the embodiment of
Referring now to
As discussed above, in different embodiments many different types of feedback circuits are possible. Referring now to
In general, these complementary flip-flops may provide a one shoot functionality for a delay setting. These two flip-flops may each output a logic zero except for a cycle of a de-serializer clock that corresponds to a shift of the clock cycle, namely the clock cycle that corresponds to the frame alignment boundary. For all but this shift value, the set inputs, DigSetDelay and DigResetDelay, are all set to logic zero. But for the position in the bitstream corresponding to the frame alignment boundary, the DigResetDelay may be set to a logic high level and only the corresponding bit of DigSetDelay is set to one. Accordingly, the outputs from flip-flops 310 and 320 may be at a logic low level for all but the bit cycle that corresponds to the frame alignment boundary. As will be discussed further below, these set and reset bit streams may be provided to a phase control circuit.
Referring now to
As further seen, each flip-flop 410 is clocked by a signal and furthermore is coupled to receive a set input and a reset input. Using a known timing relation between the CDR slow clock (DIG CLK) and the CDR fast clock (Link CLK), these set and reset inputs may be output by delay set circuit 300 of
Referring now to
Referring now to
As seen in
As a result, at block 730 the frame alignment boundary may be determined from the parallel data that is received in the digital logic. As an example, boundary detection logic may operate to determine a frame alignment boundary. When this boundary is validly determined, control passes to block 740 where a load strobe signal may be provided to the de-serializer. More specifically, this load strobe signal may correspond to a phase control signal to the cause the de-serializer to output parallel data that is aligned to a frame alignment boundary. Thus as seen at block 750, the de-serializer provides parallel data aligned to a frame alignment boundary that is responsive to this strobe signal. Thus according to various embodiments, by aligning frames in the analog domain, no digital alignment is required and therefore no latency is incurred. As such, the digital portion receives aligned frames and may immediately start processing on the received frames. While shown with this particular implementation in the embodiment of
Embodiments may be implemented in code and may be stored on a storage medium having stored thereon instructions which can be used to program a system to perform the instructions. The storage medium may include, but is not limited to, any type of disk including floppy disks, optical disks, optical disks, solid state drives (SSDs), compact disk read-only memories (CD-ROMs), compact disk rewritables (CD-RWs), and magneto-optical disks, semiconductor devices such as read-only memories (ROMs), random access memories (RAMs) such as dynamic random access memories (DRAMs), static random access memories (SRAMs), erasable programmable read-only memories (EPROMs), flash memories, electrically erasable programmable read-only memories (EEPROMs), magnetic or optical cards, or any other type of media suitable for storing electronic instructions.
While the present invention has been described with respect to a limited number of embodiments, those skilled in the art will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover all such modifications and variations as fall within the true spirit and scope of this present invention.
Lazar, Dror, Benhamou, Assaf, Shoor, Ehud
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