Abstract: An apparatus having a plurality of buffers, a first circuit and a second circuit is disclosed. The buffers are configured to store a plurality of frames to be transmitted in a plurality of respective lanes of a communication channel. The first circuit is configured to (i) generate a plurality of first groups from a first number of a plurality of samples, at least one of the first groups contains an initial portion of a given one of the samples, and (ii) generate a first of the frames by appending the first groups. The second circuit is configured to (i) receive a final portion of the given sample from the first circuit, (ii) generate a plurality of second groups from the final portion of the given sample and a second number of the samples and (iii) generate a second of the frames by appending the second groups.

Abstract: An apparatus includes a first circuit, a second circuit, and a third circuit. The first circuit may be configured to buffer a plurality of antenna carrier sample streams. The second circuit is coupled to the first circuit and may be configured to generate message data through pipelined processing and mapping of the antenna carrier samples. The third circuit is coupled to the second circuit and may be configured to generate a master frame in response to the processed and mapped message data.

Abstract: An apparatus includes a first circuit, a second circuit, and a third circuit. The first circuit may be configured to buffer a plurality of antenna carrier sample streams. The second circuit is coupled to the first circuit and may be configured to generate message data through pipelined processing and mapping of the antenna carrier samples. The third circuit is coupled to the second circuit and may be configured to generate a master frame in response to the processed and mapped message data.

Abstract: An apparatus having a plurality of buffers, a first circuit and a second circuit is disclosed. The buffers are configured to store a plurality of frames to be transmitted in a plurality of respective lanes of a communication channel. The first circuit is configured to (i) generate a plurality of first groups from a first number of a plurality of samples, at least one of the first groups contains an initial portion of a given one of the samples, and (ii) generate a first of the frames by appending the first groups. The second circuit is configured to (i) receive a final portion of the given sample from the first circuit, (ii) generate a plurality of second groups from the final portion of the given sample and a second number of the samples and (iii) generate a second of the frames by appending the second groups.

Abstract: An apparatus having a plurality of first circuits, a second circuit and a plurality of processor circuits is disclosed. Each first circuit is configured to store a plurality of samples corresponding to a plurality of channels. At least two of the samples having different widths. The second circuit is configured to store a plurality of frames each sized to contain two or more of the samples. The processor circuits are configured to (i) read the samples from the first circuits respectively, (ii) generate a transmit one of the frames by writing the samples to the second circuit based on one or more access pointers and (iii) pass control of the access pointers among the processor circuits.

Abstract: A system and method for storing variable width stack elements in a single memory stack is disclosed. In one example embodiment a first variable width stack element is split into one or more sub-elements. The width of the sub-elements may be less than or equal to a width of the single memory stack. A first memory pointer is created for providing an address of a first read pointer in the single memory stack. The first read pointer may provide an address corresponding to a first sub-element of the first variable width stack element. The first sub-element is written in a first available location in the single memory stack. A write pointer of the single memory stack is incremented when the first sub-element is written to the first available location on the single memory stack. The steps of writing and incrementing are repeated for a next sub-element until all of the sub-elements are stored in the single memory stack.

Abstract: A system and method for storing variable width stack elements in a single memory stack is disclosed. In one example embodiment a first variable width stack element is split into one or more sub-elements. The width of the sub-elements may be less than or equal to a width of the single memory stack. A first memory pointer is created for providing an address of a first read pointer in the single memory stack. The first read pointer may provide an address corresponding to a first sub-element of the first variable width stack element. The first sub-element is written in a first available location in the single memory stack. A write pointer of the single memory stack is incremented when the first sub-element is written to the first available location on the single memory stack. The steps of writing and incrementing are repeated for a next sub-element until all of the sub-elements are stored in the single memory stack.