Features • SRAM based FPGA Dedicated to Space Use • SEE Hardened Cells (configuration RAM, FreeRAM, DFF, JTAG, I/O buffers) Remove the need for Triple Modular Redundancy (TMR) • Produced on Rad Hard 0.35µm CMOS Process • Functionally and Pin Compatible with the Atmel Commercial and Military AT40K Series • High Performance • • • • • • • • • • • • • – 46K Available ASIC gates (50% typ. routable) – 60 MHz Internal Performance – 20 MHz System Performance – 30 MHz Array Multipliers – 18 ns FreeRAM™ access time – Internal Tri-state Capability in Each Cell FreeRAM – 18432 Bits of Distributed SRAM Independent of Logic Cells – Flexible, Single/Dual Port, Synchronous/Asynchronous 32x4 RAM blocks 8 Global Clocks and 4 Additional Dedicated PCI Clocks – Fast, Low Skew Clock Distribution – Programmable Rising/Falling Edge Transitions – Distributed Clock Shutdown Capability for Low Power Management Global Reset Option 384 PCI Compliant I/Os – Programmable Output Drive – Fast, Flexible Array Access Facilitates Pin Locking Package Options – MQFPF160 – MQFPF256 Design Software (System Designer) – Combination of Atmel internally developed tools, and industry standard design tools – Fast and Efficient Synthesis – Efficient Integration (Libraries, Interface, Full Back-annotation) – Over 75 Automatic Component Generators Create Thousands of Speed and Area Optimized Logic and RAM Functions – Automatic/Interactive Multi-chip Partitioning Supply Voltage 3.3V AT40KFL040 is a 5V Tolerant Version No Single Event Latch-up below a LET Threshold of 70 MeV/mg/cm2 Tested up to a Total Dose of 300 krads (Si) according to MIL STD 883 Method 1019 Quality Grades – QML -Q and -V with SMD 5962-03250 – ESCC with 9304/008 Design Kit (AT40KEL-DK) Including: – A Board with the RH FPGA (MQFPF160 or MQFPF256) – A configuration memory (AT17 Atmel EEPROM) – Design software and documentation – ISP cable and software Easy Migration to Atmel Gate Arrays for High Volume Production Note: Rad Hard Reprogrammable FPGAs with FreeRAM AT40KEL040 AT40KFL040 All features and characteristics described for AT40KEL040 in this document, also apply to the AT40KFL040 unless specified otherwise. 4155I–AERO–06/06 *** Table 1. AT40KEL040 Device Available ASIC Gates (50% typ. routable) Rows x Columns AT40KEL040 46K 48 x 48 Core Cells 2,304 Registers 3,056 RAM Bits 18,432 I/O (max) 384 Description The AT40KEL040 is a fully PCI-compliant, SRAM-based FPGA with distributed 18 ns programmable synchronous/asynchronous, dual port/single port SRAM, 8 global clocks, Cache Logic ability (partially or fully reconfigurable without loss of data), automatic component generators, and 46,000 ASIC gates. I/O counts range from 129 to 384 in Aerospace standard packages and support 3.3V. The AT40KFL040 is a 5V tolerant version. The AT40KEL040 is designed to quickly implement high performance, large gate count designs through the use of synthesis and schematic-based tools used Windows ® / Linux® platform. Atmel’s design tools provide easy integration with industry standard tools such as Synplicity, Modelsim and Leonardo Spectrum/Precision Synthesis. See the IDS datasheet for other supported tools. The AT40KEL040 can be used as a co-processor for high-speed (DSP/processorbased) designs by implementing a variety of compute-intensive, arithmetic functions. These include adaptive finite impulse response (FIR) filters, Fast Fourier Transforms (FFT), convolvers, interpolators and discrete-cosine transforms (DCT) that are required for video compression and decompression, encryption, convolution and other multimedia applications. Fast, Flexible and Efficient SRAM The AT40KEL040 FPGA offers a patented distributed 18 ns SRAM capability where the RAM can be used without losing logic resources. Multiple independent, synchronous or asynchronous, dual port or single port RAM functions (FIFO, scratch pad, etc.) can be created using Atmel’s macro generator tool. Fast, Efficient Array and Vector Multipliers The AT40KEL040’s patented 8-sided core cell with direct horizontal, vertical and diagonal cell-to-cell connections implements ultra fast array multipliers without using any busing resources. The AT40KEL040’s Cache Logic capability enables a large number of design coefficients and variables to be implemented in a very small amount of silicon, enabling vast improvement in system speed at much lower cost than conventional FPGAs. Cache Logic Design The AT40KEL040 is capable of implementing Cache Logic (Dynamic full/partial logic reconfiguration, without loss of data, on-the-fly) for building adaptive logic and systems. As new logic functions are required, they can be loaded into the logic cache without losing the data already there or disrupting the operation of the rest of the chip; replacing or complementing the active logic. The AT40KEL040 can act as a reconfigurable co-processor. Automatic Component Generators The AT40KEL040 FPGA family is capable of implementing user-defined, automatically generated, macros in multiple designs; speed and functionality are unaffected by the macro orientation or density of the target device. This enables the fastest, most predictable and efficient FPGA design approach and minimizes design risk by reusing already 2 AT40KEL040 4155I–AERO–06/06 AT40KEL040 proven functions. The Automatic Component Generators work seamlessly with industrystandard schematic and synthesis tools to create the fastest, most efficient designs available. The patented AT40KEL040 series architecture employs a symmetrical grid of small yet powerful cells connected to a flexible busing network. Independently controlled clocks and resets govern every column of cells. The array is surrounded by programmable I/O. Devices offer 46,000 usable ASIC gates, and have 3,056 registers. AT40K series FPGAs utilize a reliable 0.35µm single-poly, 4-metal CMOS process and are 100% factory-tested. Atmel’s PC- and workstation-based integrated development system (IDS) is used to create AT40KEL040 series designs. Multiple design entry methods are supported. The Atmel architecture was developed to provide the highest levels of performance, functional density and design flexibility in an FPGA. The cells in the Atmel array are small, efficient and can implement any pair of Boolean functions of (the same) three inputs or any single Boolean function of four inputs. The cell’s small size leads to arrays with large numbers of cells, greatly multiplying the functionality in each cell. A simple, high-speed busing network provides fast, efficient communication over medium and long distances. AT40KEL040 Configurator Statistics extracted from configuration bitstreams show that the maximum needed size is 1Mbit. In order to keep the maximum number of pins assigned to signals, it is recommended to use a serial configuration interface. This is the reason why Atmel proposes a 1Mbit serial EEPROM for configuring the AT40KEL040, the AT17LV010-10DP which is also a 3.3V bias chip. It is packaged into a 28-pin DIL Flat Pack 400mils wide. This memory has been tested for total dose under bias and unbiased conditions, exhibiting far better results when unbiased; this is the reason why it is recommended to switch off the memory when it is not in the configuration mode. In addition, heavy ions tests have shown that the data stored in the memory cells are not corrupted eventhough errors may be detected while downloading the bitstream; this is the result of the data serialization from the parallel memory plan; therefore, it is recommended to use the FPGA CRC while configuring it, and to resume the configuration when an error is detected. 3 4155I–AERO–06/06 The Symmetrical Array At the heart of the Atmel architecture is a symmetrical array of identical cells (Figure 1). The array is continuous from one edge to the other, except for bus repeaters spaced every four cells (Figure 2 on page 5). At the intersection of each repeater row and column is a 32 x 4 RAM block accessible by adjacent buses. The RAM can be configured as either a single-ported or dual-ported RAM(1), with either synchronous or asynchronous operation. Note: 1. The right-most column can only be used as single-port RAM. Figure 1. Symmetrical Array Surrounded by I/O Note: 4 = I/O Pad = Repeater Row = AT40K Cell = Repeater Column = FreeRAM AT40K has registered I/Os. Group enable every sector for tri-states on obuf’s. AT40KEL040 4155I–AERO–06/06 AT40KEL040 Figure 2. Floorplan (Representative Portion)(1) = Core Cell RAM RV RV RV RV RAM RV RV RV RV RAM RV RV RV RV RAM RH RH RH RH RH RH RH RH RH RH RH RH RH RH RH RH RAM RV RV RV RV RAM RV RV RV RV RAM RV RV RV RV RAM RH RH RH RH RH RH RH RH RH RH RH RH RH RH RH RH RAM RV RV RV RV RAM RV RV RV RV RAM RV RV RV RV RAM RH RH RH RH RH RH RH RH RH RH RH RH RH RH RH RH RAM RV RV RV Note: RV RAM RV RV RV RV RAM RV RV RV RV RAM 1. Repeaters regenerate signals and can connect any bus to any other bus (all pathways are legal) on the same plane. Each repeater has connections to two adjacent local-bus segments and two express-bus segments. This is done automatically using the integrated development system (IDS) tool. 5 4155I–AERO–06/06 The Busing Network Figure 3 on page 7 depicts one of five identical busing planes. Each plane has three bus resources: a local-bus resource (the middle bus) and two express-bus (both sides) resources. Bus resources are connected via repeaters. Each repeater has connections to two adjacent local-bus segments and two express-bus segments. Each local-bus segment spans four cells and connects to consecutive repeaters. Each express-bus segment spans eight cells and “leapfrogs” or bypasses a repeater. Repeaters regenerate signals and can connect any bus to any other bus (all pathways are legal) on the same plane. Although not shown, a local bus can bypass a repeater via a programmable pass gate allowing long on-chip tri-state buses to be created. Local/Local turns are implemented through pass gates in the cell-bus interface (see following page). Express/Express turns are implemented through separate pass gates distributed throughout the array. Some of the bus resource on the AT40KEL040 is used as a dual-function resource. Table 2 shows which buses are used in a dual-function mode and which bus plane is used. The AT40KEL040 software tools are designed to accommodate dual-function buses in an efficient manner. Table 2. Dual-function Buses Function Type Plane(s) Direction Cell Output Enable Local 5 Horizontal and Vertical RAM Output Enable Express 2 Vertical Bus full length at array edge Bus in first column to left of RAM block RAM Write Enable Express 1 Vertical Bus full length at array edge Bus in first column to left of RAM block RAM Address Express 1-5 Vertical Buses full length at array edge Buses in second column to left of RAM block RAM Data In Local 1 Horizontal RAM Data Out Local 2 Horizontal Clocking Express 4 Vertical Bus half length at array edge Set/Reset Express 5 Vertical Bus half length at array edge 6 Comments AT40KEL040 4155I–AERO–06/06 AT40KEL040 Figure 3. Busing Plane (One of Five) = AT40KEL040 AT40K/40KAL = Local/Local or Express/Express Turn Point = Row Repeater = Column Express Express bus bus Local bus 7 4155I–AERO–06/06 Cell Connections Figure 4(a) depicts direct connections between a cell and its eight nearest neighbors. Figure 4(b) shows the connections between a cell and five horizontal local buses (1 per busing plane) and five vertical local buses (1 per busing plane). CEL CEL plane 5 plane 4 plane 3 plane 2 plane 1 Figure 4. Cell Connections CEL plane 5 plane 4 plane 3 plane 2 plane 1 Horizontal busing plane WXYZL CEL CEL W X Y Z L CEL CEL Diagonal direct connect CEL CEL Orthogonal direct connect (a) Cell-to-cell Connections 8 Vertical busing plane CEL (b) Cell-to-bus Connections AT40KEL040 4155I–AERO–06/06 AT40KEL040 The Cell Figure 5 depicts the AT40KEL040 cell. Configuration bits for separate muxes and pass gates are independent. All permutations of programmable muxes and pass gates are legal. Vn (V1 - V5) is connected to the vertical local bus in plane n. Hn (H1 - H5) is connected to the horizontal local bus in plane n. A local/local turn in plane n is achieved by turning on the two pass gates connected to Vn and Hn. Pass gates are opened to let signals into the cell from a local bus or to drive a signal out onto a local bus. Signals coming into the logic cell on one local bus plane can be switched onto another plane by opening two of the pass gates. This allows bus signals to switch planes to achieve greater routability. Up to five simultaneous local/local turns are possible. The AT40KEL040 FPGA core cell is a highly configurable logic block based around two 3-input LUTs (8 x 1 ROM), which can be combined to produce one 4-input LUT. This means that any core cell can implement two functions of 3 inputs or one function of 4 inputs. There is a Set/Reset D flip-flop in every cell, the output of which may be tri-stated and fed back internally within the core cell. There is also a 2-to-1 multiplexer in every cell, and an upstream AND gate in the “front end” of the cell. This AND gate is an important feature in the implementation of efficient array multipliers. Figure 5. The Cell "1" NW NE SE SW "1" "1" X N E S W W Y Z X W Y FB 8X1 LUT 8X1 LUT OUT OUT "1" "0" "1" V1 V2 V3 V4 V5 H1 H2 H3 H4 H5 Pass gates 1 0 Z "1" OEH OEV D Q CLOCK RESET/SET Y X NW NE SE SW L N E S W X = Diagonal Direct connect or Bus Y = Orthogonal Direct Connector Bus W = Bus Connection Z = Bus Connection FB = Internal Feed back With this functionality in each core cell, the core cell can be configured in several “modes”. The core cell flexibility makes the AT40KEL040 architecture well suited to most digital design application areas (see Figure 6). 9 4155I–AERO–06/06 A B C D LUT Figure 6. Some Single Cell Modes Q (Registered) DQ and/or Q LUT SUM or A B C DQ SUM (Registered) LUT LUT and/or A B C D DSP/Multiplier Mode. This mode is used to efficiently DQ PRODUCT (Registered) implement array multipliers. An array multiplier is an array or of bitwise multipliers, each implemented as a full adder LUT and/or LUT Arithmetic Mode is frequently used in many designs. As can be seen in the figure, the AT40KEL040 core cell can implement a 1-bit full adder (2-input adder with both Carry In and Carry Out) in one core cell. Note that the sum output in this diagram is registered. This output could then be tri-stated and/or fed back into the cell. CARRY PRODUCT with an upstream AND gate. Using this AND gate and the diagonal interconnects between cells, the array multiplier structure fits very well into the AT40K architecture. CARRY DQ CARRY IN Q 2:1 MUX LUT and/or A B C Synthesis Mode. This mode is particularly important for the use of VHDL design. VHDL Synthesis tools generally will produce as their output large amounts of random logic functions. Having a 4-input LUT structure gives efficient random logic optimization without the delays associated with larger LUT structures. The output of any cell may be registered, tri-stated and/or fed back into a core cell. Counter Mode. Counters are fundamental to almost all digital designs. They are the basis of state machines, timing chains and clock dividers. A counter is essentially an increment by one function (i.e., an adder), with the input being an output (or a decode of an output) from the previous stage. A 1-bit counter can be implemented in one core cell. Again, the output can be registered, tri-stated and/or fed back. CARRY Q Tri-state/Mux Mode. This mode is used in many telecommunications applications, where data needs to be routed through more than one possible path. The output of the core cell is very often tri-statable for many inputs to many outputs data switching. EN 10 AT40KEL040 4155I–AERO–06/06 AT40KEL040 RAM 32 x 4 dual-ported RAM blocks are dispersed throughout the array as shown in Figure 7. A 4-bit Input Data Bus connects to four horizontal local buses distributed over four sector rows (plane 1). A 4-bit Output Data Bus connects to four horizontal local buses distributed over four sector rows (plane 2). A 5-bit Input Address Bus connects to five vertical express buses in same column. A 5-bit Output Address Bus connects to five vertical express buses in same column. Ain (input address) and Aout (output address) alternate positions in horizontally aligned RAM blocks. For the left-most RAM blocks, Aout is on the left and Ain is on the right. For the right-most RAM blocks, Ain is on the left and Aout is tied off, thus it can only be configured as a single port. For single-ported RAM, Ain is the READ/WRITE address port and Din is the (bi-directional) data port. Right-most RAM blocks can be used only for single-ported memories. WEN and OEN connect to the vertical express buses in the same column. Figure 7. RAM Connections (One Ram Block) CLK CLK CLK CLK Din Ain Dout Aout 32 x 4 RAM WEN OEN CLK Reading and writing of the 18 ns 32 x 4 dual-port FreeRAM are independent of each other. Reading the 32 x 4 dual-port RAM is completely asynchronous. Latches are transparent; when Load is logic 1, data flows through; when Load is logic 0, data is latched. These latches are used to synchronize Write Adress, Write Enable Not, and Din signals for a synchronous RAM. Each bit in the 32 x 4 dual-port RAM is also a transparent latch. The front-end latch and the memory latch together form an edge-triggered flip flop. When a nibble (bit = 7) is (Write) addressed and LOAD is logic 1 and WE is logic 0, 11 4155I–AERO–06/06 data flows through the bit. When a nibble is not (Write) addressed or LOAD is logic 0 or WE is logic 1, data is latched in the nibble. The two CLOCK muxes are controlled together; they both select CLOCK (for a synchronous RAM) or they both select “1” (for an asynchronous RAM). CLOCK is obtained from the clock for the sector-column immediately to the left and immediately above the RAM block. Writing any value to the RAM clear byte during configuration clears the RAM (see the “AT40K/40KAL Configuration Series” application note at www.atmel.com). Figure 8. RAM Logic CLOCK “1” 0 Ain Aout 1 1 Read Address 5 Load Latch Write Address 32 x 4 Dual-port RAM Load Latch 4 0 Load 5 WEN Din “1” “1” OE Write Enable NOT 4 Load Latch Din Dout Dout Clear RAM-Clear Byte Figure 9 on page 13 shows an example of a RAM macro constructed using AT40KEL040’s FreeRAM cells. The macro shown is a 128 x 8 dual-ported asynchronous RAM. Note the very small amount of external logic required to complete the address decoding for the macro. Most of the logic cells (core cells) in the sectors occupied by the RAM will be unused: they can be used for other logic in the design. This logic can be automatically generated using the macro generators. 12 AT40KEL040 4155I–AERO–06/06 4155I–AERO–06/06 Din Dout Din Dout WEN OEN Ain Aout WEN OEN Aout Ain Din WEN OEN Ain Dout Aout Din Dout Ain Local Buses Express Buses Dedicated Connections WEN OEN Aout Dout(7) Dout Ain Din(7) WEN OEN Aout Dout(6) Din Aout Dout(5) WEN OEN Ain Din(6) Dout Ain Dout(4) WEN OEN Aout Din(5) Din Aout Din(4) WEN OEN Ain Dout(3) Dout Din(3) Din Dout(2) Din(2) Dout Dout(1) Read Address Din(1) Din 2-to-4 Decoder Dout(0) 2-to-4 Decoder Din(0) Write Address WE AT40KEL040 Figure 9. RAM Example: 128 x 8 Dual-ported RAM (Asynchronous) 13 Clocking Scheme 14 There are eight Global Clock buses (GCK1 - GCK8) on the AT40KEL040 FPGA. Each of the eight dedicated Global Clock buses is connected to one of the dual-use Global Clock pins. Any clocks used in the design should use global clocks where possible: this can be done by using Assign Pin Locks to lock the clocks to the Global Clock locations. In addition to the eight Global Clocks, there are four Fast Clocks (FCK1 - FCK4), two per edge column of the array for PCI specification. Even the derived clocks can be routed through the Global network. Access points are provided in the corners of the array to route the derived clocks into the global clock network. The IDS software tools handle derived clocks to global clock connections automatically if used. Each column of an array has a “Column Clock mux” and a “Sector Clock mux”. The Column Clock mux is at the top of every column of an array and the Sector Clock mux is at every four cells. The Column Clock mux is selected from one of the eight Global Clock buses. The clock provided to each sector column of four cells is inverted, non-inverted or tied off to “0”, using the Sector Clock mux to minimize the power consumption in a sector that has no clocks. The clock can either come from the Column Clock or from the Plane 4 express bus (see Figure 10 on page 15). The extreme-left Column Clock mux has two additional inputs, FCK1 and FCK2, to provide fast clocking to left-side I/Os. The extreme-right Column Clock mux has two additional inputs as well, FCK3 and FCK4, to provide fast clocking to right-side I/Os. The register in each cell is triggered on a rising clock edge by default. Before configuration on power-up, constant “0” is provided to each register’s clock pins. After configuration on power-up, the registers either set or reset, depending on the user’s choice. The clocking scheme is designed to allow efficient use of multiple clocks with low clock skew, both within a column and across the core cell array. AT40KEL040 4155I–AERO–06/06 AT40KEL040 Figure 10. Clocking (for One Column of Cells) } “1” FCK (2 per Edge Column of the Array) GCK1 - GCK8 Column Clock Mux Sector Clock Mux Global Clock Line (Buried) Express Bus (Plane 4; Half length at edge) “1” Repeater Sector Clock Mux “1” “1” 15 4155I–AERO–06/06 Set/Reset Scheme 16 The AT40KEL040 family reset scheme is essentially the same as the clock scheme except that there is only one Global Reset. A dedicated Global Set/Reset bus can be driven by any User I/O, except those used for clocking (Global Clocks or Fast Clocks). The automatic placement tool will choose the reset net with the most connections to use the global resources. You can change this by using an RSBUF component in your design to indicate the global reset. Additional resets will use the express bus network. The Global Set/Reset is distributed to each column of the array. Like Sector Clock mux, there is Sector Set/Reset mux at every four cells. Each sector column of four cells is set/reset by a Plane 5 express bus or Global Set/Reset using the Sector Set/Reset mux (Figure 11 on page 17). The set/reset provided to each sector column of four cells is either inverted or non-inverted using the Sector Reset mux. The function of the Set/Reset input of a register is determined by a configuration bit in each cell. The Set/Reset input of a register is active low (logic 0) by default. Setting or Resetting of a register is asynchronous. Before configuration on power-up, a logic 1 (a high) is provided by each register (i.e., all registers are set at power-up). AT40KEL040 4155I–AERO–06/06 AT40KEL040 Figure 11. Set/Reset (for One Column of Cells) Each Cell has a programmable Set or Reset Sector Set/Reset Mux Repeater “1” Global Set/Reset Line (Buried) “1” Express Bus (Plane 5; Half length at edge) “1” “1” Any User I/O can drive Global Set/Reset line 17 4155I–AERO–06/06 I/O Structure AT40K has registered I/Os and group enable every sector for tri-states on obuf’s. Pad The I/O pad is the one that connects the I/O to the outside world. Note that not all I/Os have pads: the ones without pads are called Unbonded I/Os. The number of unbonded I/Os varies with the device size and package. These unbonded I/Os are used to perform a variety of bus turns at the edge of the array. Pull-up/Pull-down Each pad has a programmable pull-up and pull-down attached to it. This supplies a weak “1” or “0” level to the pad pin. When all other drivers are off, this control will dictate the signal level of the pad pin. The input stage of each I/O cell has a number of parameters that can be programmed either as properties in schematic entry or in the I/O Pad Attributes editor in IDS. CMOS The threshold level is a CMOS-compatible level. Schmitt A Schmitt trigger circuit can be enabled on the inputs. The Schmitt trigger is a regenerative comparator circuit that adds 1V hysteresis to the input. This effectively improves the rise and fall times (leading and trailing edges) of the incoming signal and can be useful for filtering out noise. Delays The input buffer can be programmed to include four different intrinsic delays as specified in the AC timing characteristics. This feature is useful for meeting data hold requirements for the input signal. Drive The output drive capabilities of each I/O are programmable. They can be set to FAST, MEDIUM or SLOW (using IDS tool). The FAST setting has the highest drive capability (16 mA at 3.3V) buffer and the fastest slew rate. MEDIUM produces a medium drive (12 mA at 3.3V) buffer, while SLOW yields a standard (4 mA at 3.3V) buffer. Tri-State The output of each I/O can be made tri-state (0, 1 or Z), open source (1 or Z) or open drain (0 or Z) by programming an I/O’s Source Selection mux. Of course, the output can be normal (0 or 1), as well. Source Selection Mux The Source Selection mux selects the source for the output signal of an I/O. See Figure 12 on page 21. Primary, Secondary and Corner I/Os The AT40KEL040 has three kinds of I/Os: Primary I/O, Secondary I/O and a Corner I/O. Every edge cell except corner cells on the AT40KEL040 has access to one Primary I/O and two Secondary I/Os. Primary I/O Every logic cell at the edge of the FPGA array has a direct orthogonal connection to and from a Primary I/O cell. The Primary I/O interfaces directly to its adjacent core cell. It also connects into the repeaters on the row immediately above and below the adjacent core cell. In addition, each Primary I/O also connects into the busing network of the three nearest edge cells. This is an extremely powerful feature, as it provides logic cells toward the center of the array with fast access to I/Os via local and express buses. It can be seen from the diagram that a given Primary I/O can be accessed from any logic cell on three separate rows or columns of the FPGA. See Figures 12a and 13a. Secondary I/O Every logic cell at the edge of the FPGA array has two direct diagonal connections to a Secondary I/O cell. The Secondary I/O is located between core cell locations. This I/O 18 AT40KEL040 4155I–AERO–06/06 AT40KEL040 connects on the diagonal inputs to the cell above and the cell below. It also connects to the repeater of the cell above and below. In addition, each Secondary I/O also connects into the busing network of the two nearest edge cells. This is an extremely powerful feature, as it provides logic cells toward the center of the array with fast access to I/Os via local and express buses. It can be seen from the diagram that a given Secondary I/O can be accessed from any logic cell on two rows or columns of the FPGA. See Figure 12a and Figure 13b. Corner I/O Logic cells at the corner of the FPGA array have direct-connect access to five separate I/Os: 2 Primary, 2 Secondary and 1 Corner I/O. Corner I/Os are like an extra Secondary I/O at each corner of the array. With the inclusion of Corner I/Os, an AT40KEL040 FPGA with n x n core cells always has 8n I/Os. As the diagram shows, Corner I/Os can be accessed both from the corner logic cell and the horizontal and vertical busing networks running along the edges of the array. This means that many different edge logic cells can access the Corner I/Os. See Figure 14. 19 4155I–AERO–06/06 Figure 12. South I/O (Mirrored for North I/O) “0” “1” DRIVE VCC TRI-STATE CELL “0” PULL-UP “1” PAD CELL SOURCE SELECT MUX DELAY SCHMITT TTL/CMOS GND PULL-DOWN CELL “0” “1” CELL DRIVE VCC TRI-STATE Primary I/OI/O (a)(a) Primary “0” PULL-UP “1” PAD SOURCE SELECT MUX DELAY SCHMITT TTL/CMOS GND PULL-DOWN CELL (b) Secondary I/O 20 AT40KEL040 4155I–AERO–06/06 AT40KEL040 Figure 13. West I/O (Mirrored for East I/O) TRI-STATE a. Primary I/0 VCC "0" "1" DRIVE CELL PULL-UP "0" "1" RST ICLK RST SCHMITT DELAY TTL/CMOS GND PULL-DOWN OCLK PAD CELL b. Secondary I/O 21 4155I–AERO–06/06 PAD VCC VCC PULL-DOWN PAD PULL-UP PULL-DOWN PULL-UP Figure 14. Northwest Corner I/O (Similar NE/SE/SW Corners) GND GND TTL/CMOS DRIVE SCHMITT DELAY TRI-ST ATE TTL/CMOS DRIVE SCHMITT DELAY TRI-ST ATE ICLK ICLK OCLK RST OCLK RST RST RST TRI-STATE "1" "0" "0" "1" "0" "1" "0" "1" RST DRIVE VCC "0" "1" PULL-UP "0" "1" RST OCLK PAD CELL CELL RST ICLK SCHMITT DELAY TTL/CMOS GND PULL-DOWN CELL 22 AT40KEL040 4155I–AERO–06/06 AT40KEL040 Electrical Characteristics Absolute Maximum Ratings* Operating Temperature.................................. -55°C to +125 °C Storage Temperature ..................................... -65°C to +150°C Junction Temperature .................................................. +150°C Voltage on Any Input Pin with Respect to Ground (1) ......-0.5V to 5.5V DC (KEL version) *Note: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those listed under operating conditions is not implied. Exposure to Absolute Maximum Rating conditions for extended periods of time may affect device reliability. ................................................ -0.5V to 7.0V DC (KFL version) Voltage on Any Output Pin with Respect to Ground .................................-0.5V to 5.5V DC Supply Voltage (VCC) ...........................................-0.5V to 5.5V ESD (RZAP = 1.5K, CZAP = 100 pF)................................. 4000V 1. For DC Input Voltage (VI) Minimum voltage of -0.5V DC, which may undershoot to -2.0V for pulses of less than 20 ns. DC and AC Operating Range Operating Temperature -55°C to +125°C 3.3V ± 0.3V VCC Power Supply High (VIHC) 70% VCC to VCC + 0.3V DC (KEL version) 70% VCC to 5.5V DC (KFL version) Low (VILC) -0.3V to 30% VCC DC Input Voltage Level (CMOS) 23 4155I–AERO–06/06 DC Characteristics Symbol Parameter VIH High-level Input Voltage VIL Low-level Input Voltage VOH VOL Conditions Min High-level Output Voltage Low-level Output Voltage IIH High-level Input Current IIL Low-level Input Current IOZH High-level Tri-state Output Leakage Current IOZL Low-level Tri-state Output Leakage Current Max Unit V TTL 2.0 V CMOS -0.3 30% VCC V TTL -0.3 0.8 V IOH = -4 mA VCC = 3.3V 2.4 V IOH = -12 mA VCC = 3.3V 2.4 V IOH = -16 mA VCC = 3.3V 2.4 V IOL = +4 mA VCC = 3.3V 0.4 V IOL = +12 mA VCC = 3.3V 0.4 V IOL = +16 mA VCC = 3.3V 0.4 V VIN = VCC max -5 With pull-down, VIN = VCC 20 VIN = VSS -5 With pull-up, VIN = VSS -300.0 75 -50 5 µA 300 µA 5 µA -20 µA Without pull-down, VOUT = VCC max -5 5 µA With pull-down, VOUT = VCC max 20 300 µA Without pull-up, VOUT = VSS -5 With pull-up, VOUT = VSS for CON ICC Standby Current Consumption Standby, unprogrammed CIN Input Capacitance(1) All pins Note: Typ 70% VCC CMOS -500 mA -150.0 -110 µA 1 5 mA 10 pF 1. Parameter based on characterization and simulation; it is not tested in production. Power-On Supply Requirements Atmel FPGAs require a minimum rated power supply current capacity to ensure proper initialization, and the power supply ramp-up time does not affect the current required. A fast ramp-up time requires more current than a slow ramp-up time. Table 3. Power-on Supply Requirements Note: Description Maximum Current(1)(2) Maximum Current Supply 1.2 A 1. Devices are guaranteed to initialize properly at 50% of the minimum current listed above. A larger capacity power supply may result in a larger initiallization current. 2. Ramp-up time is measured from 0V DC to 3.6V DC. Peak current required lasts less than 2 ms, and occurs near the internal power on reset threshold voltage. 24 AT40KEL040 4155I–AERO–06/06 AT40KEL040 AC Timing Characteristics Delays are based on fixed loads which are described in the notes. Maximum timing based on worst case: Vcc = 3.0V, temperature = 125°C. Minimum timing based on best case: Vcc = 3.6V, temperature = -55°C. Maximum delays are the average of tPDLH and tPDHL. Cell Function Parameter Path Value Unit Notes Core 2-input gate tPD (max) x/y -> x/y 2.9 ns 1 unit load 3-input gate tPD (max) x/y/z -> x/y 3.1 ns 1 unit load 3-input gate tPD (max) x/y/w -> x/y 3.5 ns 1 unit load 4-input gate tPD (max) x/y/w/z -> x/y 3.5 ns 1 unit load Fast carry tPD (max) y -> y 2.8 ns 1 unit load Fast carry tPD (max) x -> y 2.6 ns 1 unit load Fast crry tPD (max) y -> x 2.8 ns 1 unit load Fast carry tPD (max) x -> x 2.9 ns 1 unit load Fast carry tPD (max) w -> y 3.5 ns 1 unit load Fast carry tPD (max) w -> x 3.5 ns 1 unit load Fast carry tPD (max) z -> y 3.1 ns 1 unit load Fast carry tPD (max) z -> x 3.0 ns 1 unit load DFF tPD (max) Clk -> x/y 4.3 ns 1 unit load DFF tPD (max) R -> x/y 4.1 ns 1 unit load DFF tPD (max) S -> x/y 2.8 ns 1 unit load DFF tPD (max) q -> w 4.3 ns Incremental -> L tPD (max) x/y -> L 2.5 ns 1 unit load Local output enable tPZX (max) oe -> L 2.9 ns 1 unit load Local output enable tPXZ (max) oe -> L 0.9 ns AC Timing Characteristics All input I/O characteristics measured from VIH of 50% of VDD at the pad (CMOS threshold) to the internal VIH of 50% of VDD. All output I/O characteristics are measured as the average of tPDLH and tPDHL to the pad VIH of 50% of VDD. Cell Function Parameter Path Value Unit Notes Repeater tPD (max) L -> E 1.3 ns 1 unit load Repeater tPD (max) E -> E 1.3 ns 1 unit load Repeater tPD (max) L -> L 1.3 ns 1 unit load Repeater tPD (max) E -> L 1.3 ns 1 unit load Repeater tPD (max) E -> IO 0.7 ns 1 unit load Repeater tPD (max) L -> IO 0.7 ns 1 unit load Repeaters 25 4155I–AERO–06/06 Cell Function Parameter Path Value Unit Input tPD (max) Input Notes pad -> x/y 5.4 ns no extra delay tPD (max) pad -> x/y 7.6 ns 1 extra delay Input tPD (max) pad -> x/y 11.4 ns 2 extra delays Input tPD (max) pad -> x/y 14.9 ns 3 extra delays Output, slow tPD (max) x/y/E/L -> pad 16.0 ns 50 pf load Output, medium tPD (max) x/y/E/L -> pad 14.8 ns 50 pf load Output, fast tPD (max) x/y/E/L -> pad 11.2 ns 50 pf load Output, slow tPZX (max) oe -> pad 16.4 ns 50 pf load Output, slow tPXZ (max) oe -> pad 5.1 ns 50 pf load Output, medium tPZX (max) oe -> pad 14.1 ns 50 pf load Output, medium tPXZ (max) oe -> pad 9.1 ns 50 pf load Output, fast tPZX (max) oe -> pad 11.4 ns 50 pf load Output, fast tPXZ (max) oe -> pad 9.5 ns 50 pf load I/O 26 AT40KEL040 4155I–AERO–06/06 AT40KEL040 AC Timing Characteristics Clocks and Reset Input buffers are measured from a VIH of 1.5V at the input pad to the internal VIH of 50% of VCC. Maximum timings for clock input buffers and internal drivers are measured for rising edge delays only. Cell Function Parameter Path Value Unit GCK Input buffer tPD (max) FCK Input buffer tPD (max) Clock column driver Notes pad -> clock 3.3 ns rising edge clock pad -> clock 1.9 ns rising edge clock tPD (max) clock -> colclk 1.7 ns rising edge clock Clock sector driver tPD (max) colclk -> secclk 0.8 ns rising edge clock GSRN Input buffer tPD (max) colclk -> secclk 10.3 ns Global clock to output tPD (max) clock pad -> out 21.3 ns rising edge clock fully loaded clock tree rising edge DFF 20 mA output buffer 50 pf pin load Fast clock to output tPD (max) clock pad -> out 19.9 ns rising edge clock fully loaded clock tree rising edge DFF 20 mA output buffer 50 pf pin load Global Clocks and Set/Reset Notes: 1. 2. 3. 4. CMOS buffer delays are measured from a VIH of 1/2 VCC at the pad to the internal VIH at A. The input buffer load is constant. Buffer delay is to a pad voltage of 1.5V with one output switching. Parameter based on characterization and simulation; not tested in production. Exact power calculation is available in Atmel FPGA Designer software. 27 4155I–AERO–06/06 AC Timing Characteristics Cell Function Parameter Path Value Unit Write tWECYC (min) Write Write Notes cycle time 28 ns tWEL (min) we 6.5 ns pulse width low tWEH (min) we 6.5 ns pulse width high Asynchronous RAM Write tsetup (min) wr addr setup -> we 7.0 ns Write thold (min) wr addr hold -> we 0.0 ns Write tsetup (min) din setup -> we 6.5 ns Write thold (min) din hold -> we 0.0 ns Write thold (min) oe hold -> we 0.0 ns Write/Read tPD (max) din -> dout 14.1 ns Read tPD (max) rd addr -> dout 13.1 ns Read tPZX (max) oe -> dout 4.5 ns Read tPXZ (max) oe -> dout 4.5 ns Write tCYC (min) cycle time 28 ns Write tCLKL (min) clk 6.5 ns pulse width low pulse width high rd addr = wr addr Synchronous RAM Write tCLKH (min) clk 6.5 ns Write tsetup (min) we setup -> clk 5.0 ns Write thold (min) we hold -> clk 0.0 ns Write tsetup (min) wr addr setup -> clk 6.5 ns Write thold (min) wr addr hold -> clk 0.0 ns Write tsetup (min) wr data setup -> clk 5.1 ns Write thold (min) wr data hold -> clk 0.0 ns Write/Read tPD (max) din -> dout 14.1 ns rd addr = wr addr Write/Read tPD (max) clk -> dout 7.9 ns rd addr = wr addr Read tPD (max) rd addr -> dout 13.1 ns Read tPZX (max) oe -> dout 4.5 ns Read tPXZ (max) oe -> dout 4.5 ns 28 AT40KEL040 4155I–AERO–06/06 AT40KEL040 FreeRAM Asynchronous Timing Characteristics Single Port Write/Read Dual Port Write with Read Dual Port Read 29 4155I–AERO–06/06 FreeRAM Synchronous Timing Characteristics Single Port Write/Read tCLKH CLK tWCS tWCH tACS tACH WE 0 ADDR 1 3 2 OE tOXZ tDCS tDCH tOZX tAD DATA Dual Port Write with Read tCYC tCLKH tCLKL CLK tWCS tWCH tACS tACH WE 0 WR ADDR 1 tDCS 2 tDCH WR DATA RD ADDR = WR ADDR 1 tCD RD DATA 30 AT40KEL040 4155I–AERO–06/06 AT40KEL040 Dual Port Read 0 RD ADDR 1 OE tOZX tAD tOXZ DATA 31 4155I–AERO–06/06 Table 4. MQFP F-160 32 Pin Number Signal Pin Number Signal Pin Number Signal 34 I/O297_CS1_A2 68 I/O220 1 VCC 35 I/O292 69 I/O219_FCK3 2 I/O384_GCK8_A15 36 I/O291 70 GND 3 I/O383_A14 37 I/O290_GCK7_A1 71 I/O208 4 I/O382 38 I/O289_A0 72 I/O207 5 I/O381 39 GND 73 I/O206 6 I/O372_A13 40 TESTCLOCK 74 I/O205_D6 7 I/O371_A12 41 VCC 75 I/O196 8 I/O370 42 CCLK 76 I/O195 9 I/O369 43 I/O288_GCK6 77 I/O194_GCK5 10 GND 44 I/O287_D0 78 I/O193_D7 11 I/O360 45 I/O286 79 RESETN 12 I/O359 46 I/O285 80 VCC 13 I/O348_A11 47 I/O278 81 CON 14 I/O347_A10 48 I/O277_D1 82 GND 15 I/O344 49 I/O274 83 I/O192_GCK4 16 I/O343 50 I/O273 84 I/O191_D8 17 I/O338_A9 51 GND 85 I/O190 18 I/O337_A8 52 I/O262_FCK4 86 I/O189 19 VCC 53 I/O261 87 I/O184_D9 20 GND 54 I/O260 88 I/O183_D10 21 I/O336_A7 55 I/O259_D2 89 I/O180 22 I/O335_A6 56 I/O246 90 I/O179 23 I/O330 57 I/O245 91 GND 24 I/O329 58 I/O242_CHECK 92 I/O168 25 I/O328 59 I/O241_D3 93 I/O167 26 I/O326_A5 60 GND 94 I/O166_D11 27 I/O325_A4 61 VCC 95 I/O165_D12 28 I/O314 62 I/O240 96 I/O152 29 I/O313 63 I/O239_D4 97 I/O151 30 GND 64 I/O236 98 I/O146_D13 31 I/O304 65 I/O235 99 I/O145_D14 32 I/O303 66 I/O222_CS0 100 GND 33 I/O298_A3 67 I/O221_D5 101 VCC AT40KEL040 4155E–AERO–06/04 33 Pin Number Signal Pin Number Signal 102 I/O144_INIT 136 I/O69 103 I/O143_D15 137 I/O54 104 I/O138 138 I/O53 105 I/O137 139 I/O50 106 I/O124 140 I/O49 107 I/O123 141 VCC 108 I/O122 142 GND 109 I/O121 143 I/O48_A23 110 GND 144 I/O47_A22 111 I/O110 145 I/O44 112 I/O109 146 I/O43 113 I/O102_LDC 147 I/O28_A21 114 I/O101 148 I/O27_A20 115 I/O100 149 I/O26 116 I/O99 150 I/O25_FCK1 117 I/O98_HDC 151 GND 118 I/O97_GCK3 152 I/O16 119 M2 153 I/O15 120 VCC 154 I/O6_A19 121 M0 155 I/O5_A18 122 GND 156 I/O4 123 M1 157 I/O3 124 I/O96_GCK2 158 I/O2_A17 125 I/O95_OTS 159 I/O1_GCLK1_A16 126 I/O94 160 GND 127 I/O93 128 I/O90 129 I/O89 130 I/O84 131 I/O83 132 GND 133 I/O72_FCK2 134 I/O71 135 I/O70 AT40KEL040 4155E–AERO–06/04 Table 5. MQFP - F256 34 Pin Number Signal Pin Number Signal Pin Number Signal 34 IO335_A6 68 IO286 1 IO384_GCK8_A15 35 IO334 69 IO285 2 IO383_A14 36 IO330 70 IO282 3 IO382 37 IO329 71 GND 4 IO381 38 IO328 72 VCC 5 IO378 39 IO326_A5 73 IO278 6 IO377 40 IO325_A4 74 IO277_D1 7 GND 41 IO324 75 IO276 8 VCC 42 IO323 76 IO274 9 IO375 43 IO321 77 IO273 10 IO374 44 IO320 78 IO272 11 IO372_A13 45 IO318 79 IO270 12 IO371_A12 46 IO317 80 IO269 13 IO370 47 IO314 81 IO267 14 IO369 48 IO313 82 IO266 15 IO366 49 IO312 83 IO262_FCK4 16 IO365 50 IO311 84 IO261 17 IO362 51 IO308 85 IO260 18 IO360 52 IO307 86 IO259_D2 19 IO359 53 IO304 87 IO258 20 IO358 54 IO303 88 IO257 21 IO356 55 IO301 89 IO254 22 IO355 56 IO298_A3 90 IO253 23 IO353 57 GND 91 IO252 24 IO352 58 VCC 92 IO251 25 IO349 59 IO297_CS1_A2 93 IO248 26 IO348_A11 60 IO291 94 IO246 27 IO347_A10 61 IO292 95 IO245 28 IO346 62 IO290_GCK7_A1 96 IO242_CHECK 29 IO344 63 IO289_A0 97 IO241_D3 30 IO343 64 TESTCLOCK 98 IO240 31 IO338_A9 65 CCLK 99 IO239_D4 32 IO337_A8 66 IO288_GCK6 100 IO236 33 IO336_A7 67 IO287_D0 101 IO235 AT40KEL040 4155E–AERO–06/04 35 Pin Number Signal Pin Number Signal Pin Number Signal 102 IO234 136 VCC 170 IO131 103 IO232 137 IO184_D9 171 IO129 104 IO230 138 IO183_D10 172 IO128 105 IO228 139 IO181 173 IO124 106 IO227 140 IO180 174 IO123 107 IO225 141 IO179 175 IO122 108 IO224 142 IO177 176 IO121 109 IO222_CS0 143 IO174 177 IO120 110 IO221_D5 144 IO173 178 IO119 111 IO220 145 IO171 179 IO116 112 IO219_FCK3 146 IO168 180 IO115 113 IO216 147 IO167 181 IO113 114 IO215 148 IO166_D11 182 IO110 115 IO212 149 IO165_D12 183 IO109 116 IO208 150 IO163 184 IO101 117 IO207 151 IO162 185 GND 118 IO206 152 IO161 186 VCC 119 IO205_D6 153 IO158 187 IO102_LDC 120 IO204 154 IO157 188 IO99 121 GND 155 IO156 189 IO100 122 VCC 156 IO152 190 IO98_HDC 123 IO203 157 IO151 191 IO97_GCK3 124 IO196 158 IO150 192 M2 125 IO195 159 IO149 193 M0 126 IO194_GCK5 160 IO146_D13 194 M1 127 IO193_D7 161 IO145_D14 195 IO96_GCK2 128 RESETN 162 IO144_INIT 196 IO95_OTS 129 CON 163 IO143_D15 197 IO94 130 IO192_GCK4 164 IO141 198 IO93 131 IO191_D8 165 IO138 199 GND 132 IO190 166 IO137 200 VCC 133 IO189 167 IO136 201 IO90 134 IO186 168 IO134 202 IO89 135 GND 169 IO132 203 IO86 AT40KEL040 4155E–AERO–06/04 36 Pin Number Signal Pin Number Signal 204 IO85 238 IO29 205 IO84 239 IO28_A21 206 IO83 240 IO27_A20 207 IO80 241 IO26 208 IO79 242 IO25_FCK1 209 IO77 243 IO21 210 IO76 244 IO20 211 IO72_FCK2 245 IO18 212 IO71 246 IO16 213 IO70 247 IO15 214 IO69 248 IO13 215 IO67 249 GND 216 IO66 250 VCC 217 IO63 251 IO6_A19 218 IO62 252 IO5_A18 219 IO60 253 IO4 220 IO59 254 IO3 221 IO57 255 IO2_A17 222 IO56 256 IO1_GCLK1_A16 223 IO54 224 IO53 225 IO50 226 IO49 227 IO48_A23 228 IO47_A22 229 IO44 230 IO43 231 IO41 232 IO39 233 IO36 234 IO35 235 IO34 236 IO33 237 IO30 AT40KEL040 4155E–AERO–06/04 AT40KEL040 Part/Package Availability and User I/O Counts (Including Dual-function Pins) Package AT40KEL040 MQFPF 160 129 MQFPF 256 233 37 4155I–AERO–06/06 Ordering Information Part Number Package Version Temperature Range Quality Flow AT40KEL040KW1-E MQFPF160 5962-0325001QXC MQFPF160 3.3V 25°C Engineering Samples 3.3V -55° to +125°C QML Q 5962-0325001VXC MQFPF160 3.3V -55° to +125°C QML V 930400801 MQFPF160 3.3V -55° to +125°C ESCC AT40KEL040KZ1-E MQFPF256 3.3V 25°C Engineering Samples 5962-0325001QYC MQFPF256 3.3V -55° to +125°C QML Q 5962-0325001VYC MQFPF256 3.3V -55° to +125°C QML V 930400802 MQFPF256 3.3V -55° to +125°C ESCC AT40KFL040KW1-E MQFPF160 3.3V, 5V Tolerant 25°C Engineering Samples 5962-0325002QXC MQFPF160 3.3V, 5V Tolerant -55° to +125°C QML Q 5962-0325002VXC MQFPF160 3.3V, 5V Tolerant -55° to +125°C QML V AT40KFL040KW1-SCC MQFPF160 3.3V, 5V Tolerant -55° to +125°C ESCC AT40KFL040KZ1-E MQFPF256 3.3V, 5V Tolerant 25°C Engineering Samples 5962-0325002QYC MQFPF256 3.3V, 5V Tolerant -55° to +125°C QML Q 5962-0325002VYC MQFPF256 3.3V, 5V Tolerant -55° to +125°C QML V AT40KFL040KZ1-SCC MQFPF256 3.3V, 5V Tolerant -55° to +125°C ESCC 38 AT40KEL040 4155I–AERO–06/06 AT40KEL040 Package Drawing Multilayer Quad Flat Pack (MQFP) 160-pin - Front View 39 4155I–AERO–06/06 Multilayer Quad Flat Pack (MQFP) 256-pin - Front View 40 AT40KEL040 4155I–AERO–06/06 AT40KEL040 Datasheet Change Log Changes from 4155B 06/03 to 4155C 04/04 1. Addition of MQFP F256 package information 2. Pad/ Pin assignment updated. Table 4 on page 31. 3. Ordering information updated 4. Reference to design tools Changes from 4155C 06/03 to 4155D 04/04 1. Update of radiation hardness performance, page 1. Changes from 4155D 04/04 - to 4155E 06/04 1. Updated FreeRAM timing characteristics, Section “FreeRAM Asynchronous Timing Characteristics”, page 29. Changes from 4155E 06/04 to 4155F 06/04 1. Minor changes throughout the document. Changes from 4155F 06/04 to 4155G 05/05 1. Minor changes. Changes from 4155G 05/05 to 4155H 02/06 1. Added MQFP256 package. Changes from 4155H 02/06 to 4155I 06/06 1. Adding AT40KFL040 5V tolerant version. 2. Corrections on matrix decription. 41 4155I–AERO–06/06 Atmel Corporation 2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 487-2600 Regional Headquarters Europe Atmel Sarl Route des Arsenaux 41 Case Postale 80 CH-1705 Fribourg Switzerland Tel: (41) 26-426-5555 Fax: (41) 26-426-5500 Asia Room 1219 Chinachem Golden Plaza 77 Mody Road Tsimshatsui East Kowloon Hong Kong Tel: (852) 2721-9778 Fax: (852) 2722-1369 Japan 9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan Tel: (81) 3-3523-3551 Fax: (81) 3-3523-7581 Atmel Operations Memory 2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 436-4314 Microcontrollers 2325 Orchard Parkway San Jose, CA 95131, USA Tel: 1(408) 441-0311 Fax: 1(408) 436-4314 La Chantrerie BP 70602 44306 Nantes Cedex 3, France Tel: (33) 2-40-18-18-18 Fax: (33) 2-40-18-19-60 ASIC/ASSP/Smart Cards Zone Industrielle 13106 Rousset Cedex, France Tel: (33) 4-42-53-60-00 Fax: (33) 4-42-53-60-01 RF/Automotive Theresienstrasse 2 Postfach 3535 74025 Heilbronn, Germany Tel: (49) 71-31-67-0 Fax: (49) 71-31-67-2340 1150 East Cheyenne Mtn. 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