Abstract: A modem configured to couple to a communication medium for establishing a communication channel thereon. The modem includes an interleaver component configurable as to interleaver parameters ‘I, D’ corresponding to block length and depth respectively. An interleaver memory buffers the communication channel. An interleaver controller controls writing to and reading from the memory of successive data elements of the communication channel with a quantity ‘I’ pairs of write and read pointers. Each pair or write and read pointers identifies memory locations corresponding with an input and output respectively of an associated one of ‘I’ virtual first-in-first-out (‘v-FIFO’) buffers in the memory. Control of the pointers required to read out the stored data elements in interleaved fashion is limited to shifting all pointers uniformly by one address block in each interleaver block cycle, which simplifies pointer management.

Abstract: A transceiver with a plurality of components coupled to one another to form a transmit path and a receive path for multi-tone modulation of user data across a communication medium. The transceiver includes a framer and a deframer. The framer is configured to momentarily suspend framing of user data before processing bits associated with tones targeted for reference data transport and injects the pre-agreed reference pattern therein, after which framing of user data resumes. The deframer is configured to momentarily suspend deframing of received user data bits before processing bits associated with tones targeted for transport of pre-agreed reference data and extracts the received reference bits thereof for comparison with the corresponding pre-agreed reference bits to determine errors therein, after which deframing of user data resumes.

Abstract: A bundler, un-bundler and sequencer for use in controlling and driving opposing sets of logical or physical modems to drive multiple-subscriber lines with multiple communication channels. The sequencer determines subscriber requirements such as maximum and minimum bandwidth and quality of service. The sequencer also determines bandwidth availability and status of multiple subscriber lines from which a bundle may be formed. The bundler couple to the sequencer and implement header or headerless insertion of multiple channels in round robin sequence into the X-DSL frames at data rates which correspond with subscriber requirements. The un-bundler reverses the process of the bundler and passes the appropriate packet data onto the corresponding network.

Abstract: A multi-tone transceiver including: a channel controller and a plurality of components forming a transmit path and a receive path. The channel controller configured to determine bit-loading for each successive symbol or tone set based on a 1st noise margin target for a first subset of tones in each tone set dedicated to transport of a robust communications channel (RCC) and based on a 2nd noise margin target less than the 1st noise margin target for remaining tones in each tone set dedicated to a standard communications channel (SCC). The plurality of components forming the transmit and receive paths are responsive to the channel controller to select for data modulated on a given tone at least one of smaller constellations and higher gain scaling levels when the given tone corresponds to an RCC tone as compared to an SCC tone, whereby the first set of tones dedicated to the RCC exhibit greater immunity to noise variations than the remaining tones dedicated to the SCC.

Abstract: A transceiver for communicating a multi-tone modulated communication channel on a subscriber line. The transceiver includes: a digital signal processor (DSP) with a Fourier transform module and an analog front end (AFE). The DSP determines an available range of frequencies on the subscriber line and expands or contracts the tone spacing of each of a fixed number “N” of tones accordingly by decreasing or increasing the processing interval associated with the Fourier transform of each tone set. The AFE performs digital-to-analog conversion of the multi-tone modulated communication channel at rates compatible with the processing interval of the Fourier transform module; whereby the range of frequencies spanned by the modulated tones on the subscriber line conforms to the available of frequencies on the subscriber line.

Abstract: A assembler extended instruction set architecture ISA is formed from a current ISA to which is added new instructions. Assembly of source code listing of a mixture of current and new assembly language instructions is accomplished by preprocessing the source code to create a temporary file that contains the old instructions and data directives for each of the new assembly instructions that have, as the data arguments, the object code equivalent of such new instruction. The temporary file is then applied to the old assembler to produce, for each of the old assembly language instructions, the corresponding object code. The result, after linking, is an executable, machine language program for the new ISA.

Abstract: A Fourier transform processor utilizing discrete circuits each of which is configurable for processing a wide range of sample sizes. A single pipeline supports multiplexed bi-directional transformations between for example the time and frequency domains. In an embodiment of the invention the Fourier Transform processor may be implemented as part of a digital signal processor (DSP). In this embodiment the DSP may implement both the discrete Fourier transform (DFT) and inverse discrete Fourier transform (IDFT) across a wide range of sample sizes and X-DSL protocols. Multiple channels, each with varying ones of the X-DSL protocols can be handled in the same session.

Abstract: The current invention provides a DSP which accommodates multiple current X-DSL protocols and is further configurable to support future protocols. The DSP is implemented with shared and dedicated hardware components on both the transmit and receive paths. The DSP implements both the discrete Fourier transform (DFT) and inverse discrete Fourier transform (IDFT) portions across a wide range of sample sizes and X-DSL protocols. Multiple channels, each with varying ones of the X-DSL protocols can be handled in the same session. The DSP offers the speed associated with hardware implementation of the transforms and the flexibility of a software only implementation. Traffic flow is regulated in the chip using a packet based schema in which each packet is associated with a specific channel of upstream and downstream data. Header and control information in each packet is used to govern the processing of each packet as it moves along either the transmit path or receive path.

Abstract: A method and apparatus for digital subscriber line (xDSL) communications between one or more digital signal processors (DSPs) and analog front ends (AFEs) each coupled to corresponding subscriber line(s). The apparatus transports channels of data between subscribers and the DSP(s). The apparatus includes a bus for the transport of digital data, a DSP AFE interfaces. The DSP interfaces couples the DSP to the bus. The DSP interface accepts downstream channels of digital data from the DSP and transmits packets each associated with a corresponding one of the downstream channels to the bus. Each of the packets identifies a targeted AFEs coupled to a selected one of the subscriber lines. The AFE interfaces each couple an associated one of the AFEs to the bus. Each of the AFE interfaces transmits selected packets to a selected one of the subscriber lines for the transport to the subscriber.

Abstract: The current invention provides a digital signal processor which supports multiple X-DSL protocols and a multiplicity of channels on a single chip. Each channel is packetized and each packet includes control information for controlling the performance of the components/modules on the transmit and receive path. Further flexibility is derived from an architecture which incorporates discrete and shared modules on the transmit path and the receive path. The transmit path and receive path modules are collectively controlled by control information in selected ones of the packets and operate on each channel's packets at an appropriate rate, and protocol for the channel. A digital signal processor (DSP) is disclosed which incorporates these features. The DSP exhibits a favorable form factor, and flexibility as to protocols and line codes, and numbers of channels supported.

Abstract: A system and method that implement a butterfly operation for a fast fourier transform operation in a processor using a matrix-vector-multiply instruction. A first set of inputs to the butterfly operation are defined as r1+j i1 and r2+j i2, and a twiddle factor Wn is defined as Wn=e−j2&pgr;/N=cos(2&pgr;/N)−j sin(2&pgr;/N)=a+jb. The butterfly operation stores r1, i1, r2 and i2 in a first set of registers and stores the twiddle factor in matrix registers. The matrix-vector-multiply instruction is executed between the matrix registers and the first set of registers.

Abstract: The present invention contemplates an improved multiplier circuit and method for reducing power consumption by reducing the number of transitions to the input of the multiplier. Each input to the multiplier is fixed for as long as possible by reordering the sequence of the multiplications to take advantage of duplicate input values. The intermediate results of each multiplication are stored in separate accumulators to obtain the final resultants. Power consumption is further reduced through a reduction in the number of transitions on the data bus linking the multiplier and the data register file containing the accumulators.

Abstract: A method and apparatus for re-generating debug commands is provided comprising a source program having embedded debug commands in a first distinguishable field, and an assembler. The assembler operates on the source code extracting the embedded debug commands and associated address information from the source code while generating object code. The debug commands are stored in a command file for use during simulation. A simulator executes the assembled object code in conjunction with a debugger which executes the stored debug commands as designated during the execution cycle. Upon the termination of a simulation run and the subsequent modification of the source program, the debug commands are automatically re-generated with correct addresses as determined during the subsequent assembly. When the edited source file is loaded, the break-points are cleared and a new command file is executed to insure that the break-points are relocated to the correct source lines.

Abstract: A repeat-bit based system and method for executing zero overhead loops, or repeat loops, in an information processing chip that does not require a repeat end register or a dedicated comparator. Executing repeat loops requires a processor to iterate N times a code fragment of loop instructions. All systems providing this capability must know when to refetch the first loop instruction at the end of a repeat. To do this, the present invention adds a repeat bit to the processor's instruction set. This bit is set by the assembler/compiler that generates the executable code fragment comprising the repeat loop. Where the repeat loop includes plural instructions, the assembler sets the repeat bit of the penultimate loop instruction. As each loop instruction is fetched, decoded and executed, the decoder detects the repeat bit and passes it to loop control circuitry.

Abstract: A modulo addition circuit generates a sequence of values within a specified range having a lower bound value and an upper bound value. The modulo addition circuit generates a first value by adding a displacement value to a previously defined starting value, and generates a second value by adding to or subtracting from the first generated value a modulo value. Both the first and second values are generated in a single computational cycle using a single address circuit. When the first generated value is in the range defined the lower bound and upper bound values, the modulo addition circuit outputs the first value; otherwise the modulo addition circuit outputs the second generated value. The value output by the modulo addition circuit is stored in a register so as to be available as the starting value in a next computational cycle.