ATMEL AT40KEL040

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
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– 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
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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.
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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.
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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
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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).
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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
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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,
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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”
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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
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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
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4155I–AERO–06/06