The C6654 and C6652
are high performance fixed- and floating-point DSPs that are based on TI's KeyStone multicore
architecture. Incorporating the new and innovative C66x DSP core, this device can run at a core
speed of up to 850 MHz for C6654 and 600 MHz for C6652. For developers of a broad range of applications, both
C6654 and C6652 DSPs enable a
platform that is power-efficient and easy to use. In addition, the C6654 and
C6652 DSPs are fully backward compatible with all
existing C6000™ family of fixed- and floating-point DSPs.
TI's KeyStone architecture provides a programmable platform integrating various
subsystems (C66x cores, memory subsystem, peripherals, and accelerators) and uses several
innovative components and techniques to maximize intradevice and interdevice communication that
lets the various DSP resources operate efficiently and seamlessly. Central to this architecture are
key components such as Multicore Navigator that allows for efficient data management between the
various device components. The TeraNet is a nonblocking switch fabric enabling fast and
contention-free internal data movement. The multicore shared memory controller allows access to
shared and external memory directly without drawing from switch fabric capacity.
For fixed-point use, the C66x core has 4× the multiply accumulate (MAC) capability of
C64x+ cores. In addition, the C66x core integrates floating-point capability and the per-core raw
computational performance is an industry-leading 27.2 GMACS per core and 13.6 GFLOPS per core (@850 MHz frequency). The C66x core can execute 8 single precision
floating-point MAC operations per cycle and can perform double- and mixed-precision operations and
is IEEE 754 compliant. The C66x core incorporates 90 new instructions (compared to the C64x+ core)
targeted for floating-point and vector math oriented processing. These enhancements yield sizeable
performance improvements in popular DSP kernels used in signal processing, mathematical, and image
acquisition functions. The C66x core is backward code-compatible with TI's previous generation
C6000 fixed- and floating-point DSP cores, ensuring software portability and shortened software
development cycles for applications migrating to faster hardware.
The C6654 and C6652 DSPs integrate a large amount of on-chip memory. In addition to 32KB
of L1 program and data cache, 1024KB of dedicated memory can be configured as mapped RAM or cache.
All L2 memories incorporate error detection
and error correction. For fast access to external memory, this device includes a 32-bit DDR-3
external memory interface (EMIF) running at a rate of 1066 MHz and has ECC DRAM support.
This family supports a number of high-speed standard interfaces, PCI Express Gen2, and Gigabit Ethernet (PCIe
and Gigabit Ethernet are not supported on the C6652). This family of DSPs also includes
I2C, UART, Multichannel Buffered Serial Port (McBSP), Universal Parallel
Port (uPP), and a 16-bit asynchronous EMIF, along with general-purpose CMOS IO.
The C6654 and C6652
devices have a complete set of development tools, which includes: an enhanced C compiler, an
assembly optimizer to simplify programming and scheduling, and a Windows® debugger interface for
visibility into source code execution.
TI’s KeyStone Multicore Architecture provides a high performance
structure for integrating RISC and DSP cores with application-specific coprocessors and I/O. The
KeyStone architecture is the first of its kind that provides adequate internal bandwidth for
nonblocking access to all processing cores, peripherals, coprocessors, and I/O. This internal
bandwidth is achieved with four main hardware elements: Multicore Navigator, TeraNet, and Multicore
Shared Memory Controller.
Multicore Navigator is an innovative packet-based manager that controls 8192 queues.
When tasks are allocated to the queues, Multicore Navigator provides hardware-accelerated dispatch
that directs tasks to the appropriate available hardware. The packet-based system on a chip (SoC)
uses the two Tbps capacity of the TeraNet switched central resource to move packets. The Multicore
Shared Memory Controller lets processing cores access shared memory directly without drawing from
the capacity of TeraNet, so packet movement cannot be blocked by memory access.
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