SMC Networks ARM720T_LH79520 User Manual
ARM720T_LH79520 – Sharp LH79520 SoC with ARM720T 32-bit RISC Processor
Improving and Extending Product Life-Cycles
Fast time to market is usually synonymous with a weaker feature set – a traditional trade-off. With FPGA-based system designs
you can have the best of both worlds. You can get your product to market quickly with a limited feature set, then follow-up with
more extensive features over time, upgrading the product while it is already in the field.
you can have the best of both worlds. You can get your product to market quickly with a limited feature set, then follow-up with
more extensive features over time, upgrading the product while it is already in the field.
This not only extends product life-cycles but also lowers the risk of entry, allowing new protocols to be added dynamically and
hardware bugs to be fixed without product RMA.
hardware bugs to be fixed without product RMA.
Creating Application-Specific Coprocessors
Algorithms can easily be moved between hardware and software implementations. This allows the design to be initially
implemented in software, later off-loading intensive tasks into dedicated hardware, in order to meet performance objectives.
Again, this can happen even after commitment to the board-level design.
implemented in software, later off-loading intensive tasks into dedicated hardware, in order to meet performance objectives.
Again, this can happen even after commitment to the board-level design.
Implementing Multiple Processors within a Single Device
Extra processors can be added within a single FPGA device, simply by modifying the design with which the device is
programmed. Once again, this can be achieved after the board-level design has been finalized and a commitment to production
made.
programmed. Once again, this can be achieved after the board-level design has been finalized and a commitment to production
made.
Lowering System Cost
Processors, peripherals, memory and I/O interfaces can be integrated into a single FPGA device, greatly reducing system
complexity and cost. Once the FPGA-based embedded application moves to 32-bit, cost becomes an even more powerful driver.
complexity and cost. Once the FPGA-based embedded application moves to 32-bit, cost becomes an even more powerful driver.
As large FPGAs become cheaper, both Hybrids and soft cores move into the same general cost area as dedicated processors.
At the heart of this argument is also the idea that once you have paid for the FPGA, any extra IP that you place in the device is
free functionality.
At the heart of this argument is also the idea that once you have paid for the FPGA, any extra IP that you place in the device is
free functionality.
Avoiding Processor Obsolescence
As products mature, processor supply may become an increasing problem, particularly where the processor is one of many
variants supplied by the semiconductor vendor. Switching to a new processor usually requires design software changes or
logical hardware changes.
variants supplied by the semiconductor vendor. Switching to a new processor usually requires design software changes or
logical hardware changes.
With FPGA implementations, the design can be easily moved to a different device with little or no change to the hardware logic
and probably no change to the application software. Peripherals are created dynamically in the hardware, so lack of availability
of specific processor variants is never a problem.
and probably no change to the application software. Peripherals are created dynamically in the hardware, so lack of availability
of specific processor variants is never a problem.
The ARM720T_LH79520
Altium Designer's support for the Sharp Bluestreak LH79520 offers you the best of both worlds – allowing you to create designs
that themselves reside within an FPGA device, whilst incorporating the processing power of the ARM720T within the physical
LH79520 device. Your design may simply provide an extension of the ARM720T to external memory and peripheral devices, the
interfacing to which is specified in the design downloaded to the FPGA. Alternatively, you may have a hybrid design, making
use not only of a physical processor (and member of the widely regarded ARM7 family), but also one or more 'soft' processors
defined within your FPGA design and resident on the target FPGA device. Performance critical code might typically be handled
by the physical processor.
that themselves reside within an FPGA device, whilst incorporating the processing power of the ARM720T within the physical
LH79520 device. Your design may simply provide an extension of the ARM720T to external memory and peripheral devices, the
interfacing to which is specified in the design downloaded to the FPGA. Alternatively, you may have a hybrid design, making
use not only of a physical processor (and member of the widely regarded ARM7 family), but also one or more 'soft' processors
defined within your FPGA design and resident on the target FPGA device. Performance critical code might typically be handled
by the physical processor.
The ARM720T is a 32-bit RISC machine that follows the classic RISC architecture previously described. It is a load/store
machine with 31 general purpose registers and 6 status registers.
machine with 31 general purpose registers and 6 status registers.
All instructions are 32-bits wide and most execute in a single clock cycle.
The ARM720T_LH79520 also features a user-definable amount of zero-wait state block RAM, with true dual-port access.
Wishbone Bus Interfaces
The ARM720T_LH79520 uses the Wishbone bus standard. This standard is formally described
as a “System-on-Chip Interconnection Architecture for Portable IP Cores”. The current standard
is the
as a “System-on-Chip Interconnection Architecture for Portable IP Cores”. The current standard
is the
, a copy of which is included as part of the software installation
and can be found by navigating to the Documentation Library » Designing with
FPGAs
section of the Knowledge Center panel.
Remember that the
ARM720T_LH79520 is the
'Wishbone wrapper' placed in your
FPGA design. The actual
ARM720T resides in the physical
LH79520 device – external to the
FPGA device to which that design
is targeted.
ARM720T_LH79520 is the
'Wishbone wrapper' placed in your
FPGA design. The actual
ARM720T resides in the physical
LH79520 device – external to the
FPGA device to which that design
is targeted.
The Wishbone standard is not copyrighted and resides in the public domain. It may be freely
copied and distributed by any means. Furthermore, it may be used for the design and production
of integrated circuit components without royalties or other financial obligations.
copied and distributed by any means. Furthermore, it may be used for the design and production
of integrated circuit components without royalties or other financial obligations.
CR0162 (v2.0) March 10, 2008
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