FLEX 6000
Programmable Logic
Device Family
®
March 2001, ver. 4.1
Features...
Data Sheet
■
■
■
Provides an ideal low-cost, programmable alternative to highvolume gate array applications and allows fast design changes
during prototyping or design testing
Product features
–
Register-rich, look-up table- (LUT-) based architecture
–
OptiFLEX® architecture that increases device area efficiency
–
Typical gates ranging from 5,000 to 24,000 gates (see Table 1)
–
Built-in low-skew clock distribution tree
–
100% functional testing of all devices; test vectors or scan chains
are not required
System-level features
–
In-circuit reconfigurability (ICR) via external configuration
device or intelligent controller
–
5.0-V devices are fully compliant with peripheral component
interconnect Special Interest Group (PCI SIG) PCI Local Bus
Specification, Revision 2.2
–
Built-in Joint Test Action Group (JTAG) boundary-scan test
(BST) circuitry compliant with IEEE Std. 1149.1-1990, available
without consuming additional device logic
–
MultiVoltTM I/O interface operation, allowing a device to bridge
between systems operating at different voltages
–
Low power consumption (typical specification less than 0.5 mA
in standby mode)
–
3.3-V devices support hot-socketing
Table 1. FLEX 6000 Device Features
Feature
Typical gates (1)
EPF6010A
EPF6016
EPF6016A
EPF6024A
10,000
16,000
16,000
24,000
Logic elements (LEs)
880
1,320
1,320
1,960
Maximum I/O pins
102
204
171
218
3.3 V
5.0 V
3.3 V
3.3 V
Supply voltage (VCCINT)
Note:
(1)
The embedded IEEE Std. 1149.1 JTAG circuitry adds up to 14,000 gates in addition to the listed typical gates.
Altera Corporation
A-DS-F6000-04.1
1
FLEX 6000 Programmable Logic Device Family Data Sheet
...and More
Features
■
■
■
■
■
Powerful I/O pins
–
Individual tri-state output enable control for each pin
–
Programmable output slew-rate control to reduce switching
noise
–
Fast path from register to I/O pin for fast clock-to-output time
Flexible interconnect
–
FastTrack® Interconnect continuous routing structure for fast,
predictable interconnect delays
–
Dedicated carry chain that implements arithmetic functions such
as fast adders, counters, and comparators (automatically used by
software tools and megafunctions)
–
Dedicated cascade chain that implements high-speed, high-fanin logic functions (automatically used by software tools and
megafunctions)
–
Tri-state emulation that implements internal tri-state networks
–
Four low-skew global paths for clock, clear, preset, or logic
signals
Software design support and automatic place-and-route provided by
Altera’s development system for Windows-based PCs, Sun
SPARCstations, and HP 9000 Series 700/800
Flexible package options
–
Available in a variety of packages with 100 to 256 pins, including
the innovative FineLine BGATM packages (see Table 2)
–
SameFrameTM pin-compatibility (with other FLEX® 6000 devices)
across device densities and pin counts
–
Thin quad flat pack (TQFP), plastic quad flat pack (PQFP), and
ball-grid array (BGA) packages (see Table 2)
–
Footprint- and pin-compatibility with other FLEX 6000 devices
in the same package
Additional design entry and simulation support provided by
EDIF 2 0 0 and 3 0 0 netlist files, the library of parameterized modules
(LPM), Verilog HDL, VHDL, DesignWare components, and other
interfaces to popular EDA tools from manufacturers such as
Cadence, Exemplar Logic, Mentor Graphics, OrCAD, Synopsys,
Synplicity, VeriBest, and Viewlogic
Table 2. FLEX 6000 Package Options & I/O Pin Count
Device
100-Pin
TQFP
EPF6010A
71
100-Pin
FineLine BGA
EPF6024A
2
81
208-Pin
PQFP
240-Pin
PQFP
256-Pin
BGA
117
171
199
204
117
171
117
171
199
218
256-pin
FineLine BGA
102
EPF6016
EPF6016A
144-Pin
TQFP
81
171
219
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
General
Description
The Altera® FLEX 6000 programmable logic device (PLD) family provides
a low-cost alternative to high-volume gate array designs. FLEX 6000
devices are based on the OptiFLEX architecture, which minimizes die size
while maintaining high performance and routability. The devices have
reconfigurable SRAM elements, which give designers the flexibility to
quickly change their designs during prototyping and design testing.
Designers can also change functionality during operation via in-circuit
reconfiguration.
FLEX 6000 devices are reprogrammable, and they are 100% tested prior to
shipment. As a result, designers are not required to generate test vectors
for fault coverage purposes, allowing them to focus on simulation and
design verification. In addition, the designer does not need to manage
inventories of different gate array designs. FLEX 6000 devices are
configured on the board for the specific functionality required.
Table 3 shows FLEX 6000 performance for some common designs. All
performance values shown were obtained using Synopsys DesignWare or
LPM functions. Special design techniques are not required to implement
the applications; the designer simply infers or instantiates a function in a
Verilog HDL, VHDL, Altera Hardware Description Language (AHDL), or
schematic design file.
Table 3. FLEX 6000 Device Performance for Common Designs
Application
LEs Used
Performance
-1 Speed
Grade
-2 Speed
Grade
Units
-3 Speed
Grade
16-bit loadable counter
16
172
153
133
MHz
16-bit accumulator
16
172
153
133
MHz
24-bit accumulator
24
136
123
108
MHz
16-to-1 multiplexer (pin-to-pin) (1)
10
12.1
13.4
16.6
ns
16 × 16 multiplier with a 4-stage pipeline
592
84
67
58
MHz
Note:
(1)
This performance value is measured as a pin-to-pin delay.
Altera Corporation
3
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 4 shows FLEX 6000 performance for more complex designs.
Table 4. FLEX 6000 Device Performance for Complex Designs
Application
Note (1)
LEs Used
Performance
Units
-1 Speed
Grade
-2 Speed
Grade
-3 Speed
Grade
8-bit, 16-tap parallel finite impulse response
(FIR) filter
599
94
80
72
MSPS
8-bit, 512-point fast Fourier transform (FFT)
function
1,182
75
63
89
53
109
43
µS
MHz
a16450 universal asynchronous
receiver/transmitter (UART)
487
36
30
25
MHz
PCI bus target with zero wait states
609
56
49
42
MHz
Note:
(1)
The applications in this table were created using Altera MegaCoreTM functions.
FLEX 6000 devices are supported by Altera development systems; a
single, integrated package that offers schematic, text (including AHDL),
and waveform design entry, compilation and logic synthesis, full
simulation and worst-case timing analysis, and device configuration. The
Altera software provides EDIF 2 0 0 and 3 0 0, LPM, VHDL, Verilog HDL,
and other interfaces for additional design entry and simulation support
from other industry-standard PC- and UNIX workstation-based EDA
tools.
The Altera software works easily with common gate array EDA tools for
synthesis and simulation. For example, the Altera software can generate
Verilog HDL files for simulation with tools such as Cadence Verilog-XL.
Additionally, the Altera software contains EDA libraries that use devicespecific features such as carry chains which are used for fast counter and
arithmetic functions. For instance, the Synopsys Design Compiler library
supplied with the Altera development systems include DesignWare
functions that are optimized for the FLEX 6000 architecture.
The Altera development system runs on Windows-based PCs, Sun
SPARCstations, and HP 9000 Series 700/800.
f
4
See the MAX+PLUS II Programmable Logic Development System & Software
Data Sheet and the Quartus Programmable Logic Development System &
Software Data Sheet for more information.
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Functional
Description
The FLEX 6000 OptiFLEX architecture consists of logic elements (LEs).
Each LE includes a 4-input look-up table (LUT), which can implement any
4-input function, a register, and dedicated paths for carry and cascade
chain functions. Because each LE contains a register, a design can be easily
pipelined without consuming more LEs. The specified gate count for
FLEX 6000 devices includes all LUTs and registers.
LEs are combined into groups called logic array blocks (LABs); each LAB
contains 10 LEs. The Altera software automatically places related LEs into
the same LAB, minimizing the number of required interconnects. Each
LAB can implement a medium-sized block of logic, such as a counter or
multiplexer.
Signal interconnections within FLEX 6000 devices—and to and from
device pins—are provided via the routing structure of the FastTrack
Interconnect. The routing structure is a series of fast, continuous row and
column channels that run the entire length and width of the device. Any
LE or pin can feed or be fed by any other LE or pin via the FastTrack
Interconnect. See “FastTrack Interconnect” on page 17 of this data sheet
for more information.
Each I/O pin is fed by an I/O element (IOE) located at the end of each row
and column of the FastTrack Interconnect. Each IOE contains a
bidirectional I/O buffer. Each IOE is placed next to an LAB, where it can
be driven by the local interconnect of that LAB. This feature allows fast
clock-to-output times of less than 8 ns when a pin is driven by any of the
10 LEs in the adjacent LAB. Also, any LE can drive any pin via the row and
column interconnect. I/O pins can drive the LE registers via the row and
column interconnect, providing setup times as low as 2 ns and hold times
of 0 ns. IOEs provide a variety of features, such as JTAG BST support,
slew-rate control, and tri-state buffers.
Figure 1 shows a block diagram of the FLEX 6000 OptiFLEX architecture.
Each group of ten LEs is combined into an LAB, and the LABs are
arranged into rows and columns. The LABs are interconnected by the
FastTrack Interconnect. IOEs are located at the end of each FastTrack
Interconnect row and column.
Altera Corporation
5
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 1. OptiFLEX Architecture Block Diagram
IOEs
Row FastTrack
Interconnect
Row FastTrack
Interconnect
IOEs
Column FastTrack
Interconnect
Column FastTrack
Interconnect
Local Interconnect
(Each LAB accesses
two local interconnect
areas.)
Logic Elements
FLEX 6000 devices provide four dedicated, global inputs that drive the
control inputs of the flipflops to ensure efficient distribution of highspeed, low-skew control signals. These inputs use dedicated routing
channels that provide shorter delays and lower skews than the FastTrack
Interconnect. These inputs can also be driven by internal logic, providing
an ideal solution for a clock divider or an internally generated
asynchronous clear signal that clears many registers in the device. The
dedicated global routing structure is built into the device, eliminating the
need to create a clock tree.
Logic Array Block
An LAB consists of ten LEs, their associated carry and cascade chains, the
LAB control signals, and the LAB local interconnect. The LAB provides
the coarse-grained structure of the FLEX 6000 architecture, and facilitates
efficient routing with optimum device utilization and high performance.
6
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
The interleaved LAB structure—an innovative feature of the FLEX 6000
architecture—allows each LAB to drive two local interconnects. This
feature minimizes the use of the FastTrack Interconnect, providing higher
performance. An LAB can drive 20 LEs in adjacent LABs via the local
interconnect, which maximizes fitting flexibility while minimizing die
size. See Figure 2.
Figure 2. Logic Array Block
Row Interconnect
The row interconnect is
bidirectionally connected
to the local interconnect.
LEs can directly drive the row
and column interconnect.
To/From
Adjacent
LAB or IOEs
Local Interconnect
To/From
Adjacent
LAB or IOEs
The 10 LEs in the LAB are driven by two
local interconnect areas. The LAB can drive
two local interconnect areas.
Column Interconnect
In most designs, the registers only use global clock and clear signals.
However, in some cases, other clock or asynchronous clear signals are
needed. In addition, counters may also have synchronous clear or load
signals. In a design that uses non-global clock and clear signals, inputs
from the first LE in an LAB are re-routed to drive the control signals for
that LAB. See Figure 3.
Altera Corporation
7
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 3. LAB Control Signals
The dedicated input signals
can drive the clock and
asynchronous clear signals.
4
Dedicated Inputs
Input signals to the first
LE in an LAB (i.e., LE 1)
can be rerouted to drive
control signals within
the LAB.
LE 1
LABCTRL1/
SYNCLR
LABCTRL2
CLK1/SYNLOAD
CLK2
LAB-wide control signals
(SYNCLR and SYNLOAD
signals are used in counter mode).
Logic Element
An LE, the smallest unit of logic in the FLEX 6000 architecture, has a
compact size that provides efficient logic usage. Each LE contains a fourinput LUT, which is a function generator that can quickly implement any
function of four variables. An LE contains a programmable flipflop, carry
and cascade chains. Additionally, each LE drives both the local and the
FastTrack Interconnect. See Figure 4.
8
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 4. Logic Element
data1
data2
data3
data4
Look-Up
Table
(LUT)
Carry-In
Cascade-In
Carry
Chain
Cascade
Chain
Register Bypass
Programmable
Register
PRN
Q
LE-Out
D
CLRN
labctrl1
labctrl2
Chip-Wide Reset
Clear/ Preset
Logic
Clock
Select
labctrl3
labctrl4
Carry-Out
Cascade-Out
The programmable flipflop in the LE can be configured for D, T, JK, or SR
operation. The clock and clear control signals on the flipflop can be driven
by global signals, general-purpose I/O pins, or any internal logic. For
combinatorial functions, the flipflop is bypassed and the output of the
LUT drives the outputs of the LE. The LE output can drive both the local
interconnect and the FastTrack Interconnect.
The FLEX 6000 architecture provides two types of dedicated high-speed
data paths that connect adjacent LEs without using local interconnect
paths: carry chains and cascade chains. A carry chain supports high-speed
arithmetic functions such as counters and adders, while a cascade chain
implements wide-input functions such as equivalent comparators with
minimum delay. Carry and cascade chains connect LEs 2 through 10 in an
LAB and all LABs in the same half of the row. Because extensive use of
carry and cascade chains can reduce routing flexibility, these chains
should be limited to speed-critical portions of a design.
Altera Corporation
9
FLEX 6000 Programmable Logic Device Family Data Sheet
Carry Chain
The carry chain provides a very fast (0.1 ns) carry-forward function
between LEs. The carry-in signal from a lower-order bit drives forward
into the higher-order bit via the carry chain, and feeds into both the LUT
and the next portion of the carry chain. This feature allows the FLEX 6000
architecture to implement high-speed counters, adders, and comparators
of arbitrary width. Carry chain logic can be created automatically by the
Altera software during design processing, or manually by the designer
during design entry. Parameterized functions such as LPM and
DesignWare functions automatically take advantage of carry chains for
the appropriate functions.
Because the first LE of each LAB can generate control signals for that LAB,
the first LE in each LAB is not included in carry chains. In addition, the
inputs of the first LE in each LAB may be used to generate synchronous
clear and load enable signals for counters implemented with carry chains.
Carry chains longer than nine LEs are implemented automatically by
linking LABs together. For enhanced fitting, a long carry chain skips
alternate LABs in a row. A carry chain longer than one LAB skips either
from an even-numbered LAB to another even-numbered LAB, or from an
odd-numbered LAB to another odd-numbered LAB. For example, the last
LE of the first LAB in a row carries to the second LE of the third LAB in
the row. In addition, the carry chain does not cross the middle of the row.
For instance, in the EPF6016 device, the carry chain stops at the 11th LAB
in a row and a new carry chain begins at the 12th LAB.
Figure 5 shows how an n-bit full adder can be implemented in n + 1 LEs
with the carry chain. One portion of the LUT generates the sum of two bits
using the input signals and the carry-in signal; the sum is routed to the
output of the LE. Although the register can be bypassed for simple adders,
it can be used for an accumulator function. Another portion of the LUT
and the carry chain logic generates the carry-out signal, which is routed
directly to the carry-in signal of the next-higher-order bit. The final
carry-out signal is routed to an LE, where it is driven onto the FastTrack
Interconnect.
10
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 5. Carry Chain Operation
Carry-In
a1
LUT
s1
Register
b1
Carry Chain
LE 2
a2
LUT
Register
s2
b2
Carry Chain
LE 3
an
LUT
Register
sn
bn
Carry Chain
LE n + 1
LUT
Register
Carry-Out
Carry Chain
LE n + 2
Altera Corporation
11
FLEX 6000 Programmable Logic Device Family Data Sheet
Cascade Chain
The cascade chain enables the FLEX 6000 architecture to implement very
wide fan-in functions. Adjacent LUTs can be used to implement portions
of the function in parallel; the cascade chain serially connects the
intermediate values. The cascade chain can use a logical AND or logical
OR gate (via De Morgan’s inversion) to connect the outputs of adjacent
LEs. Each additional LE provides four more inputs to the effective width
of a function, with a delay as low as 0.5 ns per LE. Cascade chain logic can
be created automatically by the Altera software during design processing,
or manually by the designer during design entry. Parameterized functions
such as LPM and DesignWare functions automatically take advantage of
cascade chains for the appropriate functions.
A cascade chain implementing an AND gate can use the register in the last
LE; a cascade chain implementing an OR gate cannot use this register
because of the inversion required to implement the OR gate.
Because the first LE of an LAB can generate control signals for that LAB,
the first LE in each LAB is not included in cascade chains. Moreover,
cascade chains longer than nine bits are automatically implemented by
linking several LABs together. For easier routing, a long cascade chain
skips every other LAB in a row. A cascade chain longer than one LAB
skips either from an even-numbered LAB to another even-numbered
LAB, or from an odd-numbered LAB to another odd-numbered LAB. For
example, the last LE of the first LAB in a row cascades to the second LE of
the third LAB. The cascade chain does not cross the center of the row. For
example, in an EPF6016 device, the cascade chain stops at the 11th LAB in
a row and a new cascade chain begins at the 12th LAB.
Figure 6 shows how the cascade function can connect adjacent LEs to form
functions with a wide fan-in. In this example, functions of 4n variables are
implemented with n LEs. The cascade chain requires 3.4 ns to decode a
16-bit address.
12
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 6. Cascade Chain Operation
AND Cascade Chain
OR Cascade Chain
LE 2
d[3..0]
LUT
d[7..4]
LUT
d[(4n-1)..4(n-1)]
LUT
LE 2
d[3..0]
LUT
d[7..4]
LUT
d[(4n-1)..4(n-1)]
LUT
LE 3
LE 3
LE n + 1
LE n + 1
LE Operating Modes
The FLEX 6000 LE can operate in one of the following three modes:
■
■
■
Normal mode
Arithmetic mode
Counter mode
Each of these modes uses LE resources differently. In each mode, seven
available inputs to the LE—the four data inputs from the LAB local
interconnect, the feedback from the programmable register, and the
carry-in and cascade-in from the previous LE—are directed to different
destinations to implement the desired logic function. LAB-wide signals
provide clock, asynchronous clear, synchronous clear, and synchronous
load control for the register. The Altera software, in conjunction with
parameterized functions such as LPM and DesignWare functions,
automatically chooses the appropriate mode for common functions such
as counters, adders, and multipliers. If required, the designer can also
create special-purpose functions to use an LE operating mode for optimal
performance.
Figure 7 shows the LE operating modes.
Altera Corporation
13
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 7. LE Operating Modes
Normal Mode
Cascade-In
Carry-In
LE-Out
data1
data2
D
4-Input
LUT
data3
data4
PRN
Q
CLRN
Cascade-Out
Arithmetic Mode
Carry-In
Cascade-In
LE-Out
data1
data2
PRN
D
Q
3-Input
LUT
CLRN
3-Input
LUT
Cascade-Out
Carry-Out
Counter Mode
Cascade-In
Carry-In
LAB-Wide
Synchronous
Load (3)
LAB-Wide Synchronous
Clear (3)
(1)
data1 (2)
data2 (2)
3-Input
LUT
D
PRN
Q
LE-Out
data3 (data)
CLRN
3-Input
LUT
Carry-Out
Cascade-Out
Notes:
(1)
(2)
(3)
The register feedback multiplexer is available on LE 2 of each LAB.
The data1 and data2 input signals can supply a clock enable, up or down control, or register feedback signals for
all LEs other than the second LE in an LAB.
The LAB-wide synchronous clear and LAB-wide synchronous load affect all registers in an LAB.
14
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Normal Mode
The normal mode is suitable for general logic applications, combinatorial
functions, or wide decoding functions that can take advantage of a
cascade chain. In normal mode, four data inputs from the LAB local
interconnect and the carry-in are inputs to a 4-input LUT. The Altera
software automatically selects the carry-in or the DATA3 signal as one of
the inputs to the LUT. The LUT output can be combined with the cascadein signal to form a cascade chain through the cascade-out signal.
Arithmetic Mode
The arithmetic mode is ideal for implementing adders, accumulators, and
comparators. An LE in arithmetic mode uses two 3-input LUTs. One LUT
computes a 3-input function; the other generates a carry output. As shown
in Figure 7, the first LUT uses the carry-in signal and two data inputs from
the LAB local interconnect to generate a combinatorial or registered
output. For example, when implementing an adder, this output is the sum
of three signals: DATA1, DATA2, and carry-in. The second LUT uses the
same three signals to generate a carry-out signal, thereby creating a carry
chain. The arithmetic mode also supports simultaneous use of the cascade
chain.
The Altera software implements logic functions to use the arithmetic
mode automatically where appropriate; the designer does not have to
decide how the carry chain will be used.
Counter Mode
The counter mode offers counter enable, synchronous up/down control,
synchronous clear, and synchronous load options. The counter enable and
synchronous up/down control signals are generated from the data inputs
of the LAB local interconnect. The synchronous clear and synchronous
load options are LAB-wide signals that affect all registers in the LAB.
Consequently, if any of the LEs in a LAB use counter mode, other LEs in
that LAB must be used as part of the same counter or be used for a
combinatorial function. In addition, the Altera software automatically
places registers that are not in the counter into other LABs.
The counter mode uses two 3-input LUTs: one generates the counter data
and the other generates the fast carry bit. A 2-to-1 multiplexer provides
synchronous loading, and another AND gate provides synchronous
clearing. If the cascade function is used by an LE in counter mode, the
synchronous clear or load will override any signal carried on the cascade
chain. The synchronous clear overrides the synchronous load.
Altera Corporation
15
FLEX 6000 Programmable Logic Device Family Data Sheet
Either the counter enable or the up/down control may be used for a given
counter. Moreover, the synchronous load can be used as a count enable by
routing the register output into the data input automatically when
requested by the designer.
The second LE of each LAB has a special function for counter mode; the
carry-in of the LE can be driven by a fast feedback path from the register.
This function gives a faster counter speed for counter carry chains starting
in the second LE of an LAB.
The Altera software implements functions to use the counter mode
automatically where appropriate. The designer does not have to decide
how the carry chain will be used.
Internal Tri-State Emulation
Internal tri-state emulation provides internal tri-states without the
limitations of a physical tri-state bus. In a physical tri-state bus, the
tri-state buffers’ output enable (OE) signals select which signal drives the
bus. However, if multiple OE signals are active, contending signals can be
driven onto the bus. Conversely, if no OE signals are active, the bus will
float. Internal tri-state emulation resolves contending tri-state buffers to a
low value and floating buses to a high value, thereby eliminating these
problems. The Altera software automatically implements tri-state bus
functionality with a multiplexer.
Clear & Preset Logic Control
Logic for the programmable register’s clear and preset functions is
controlled by the LAB-wide signals LABCTRL1 and LABCTRL2. The LE
register has an asynchronous clear that can implement an asynchronous
preset. Either LABCTRL1 or LABCTRL2 can control the asynchronous clear
or preset. Because the clear and preset functions are active-low, the Altera
software automatically assigns a logic high to an unused clear or preset
signal. The clear and preset logic is implemented in either the
asynchronous clear or asynchronous preset mode, which is chosen during
design entry (see Figure 8).
16
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 8. LE Clear & Preset Modes
Asynchronous Clear
Asynchronous Preset
D
Q
CLRN
labctrl1 or
labctrl2
Chip-Wide Reset
D
PRN
Q
labctrl1 or
labctrl2
Chip-Wide Reset
Asynchronous Clear
The flipflop can be cleared by either LABCTRL1 or LABCTRL2.
Asynchronous Preset
An asynchronous preset is implemented with an asynchronous clear. The
Altera software provides preset control by using the clear and inverting
the input and output of the register. Inversion control is available for the
inputs to both LEs and IOEs. Therefore, this technique can be used when
a register drives logic or drives a pin.
In addition to the two clear and preset modes, FLEX 6000 devices provide
a chip-wide reset pin (DEV_CLRn) that can reset all registers in the device.
The option to use this pin is set in the Altera software before compilation.
The chip-wide reset overrides all other control signals. Any register with
an asynchronous preset will be preset when the chip-wide reset is asserted
because of the inversion technique used to implement the asynchronous
preset.
The Altera software can use a programmable NOT-gate push-back
technique to emulate simultaneous preset and clear or asynchronous load.
However, this technique uses an additional three LEs per register.
FastTrack Interconnect
In the FLEX 6000 OptiFLEX architecture, connections between LEs and
device I/O pins are provided by the FastTrack Interconnect, a series of
continuous horizontal and vertical routing channels that traverse the
device. This global routing structure provides predictable performance,
even for complex designs. In contrast, the segmented routing in FPGAs
requires switch matrices to connect a variable number of routing paths,
increasing the delays between logic resources and reducing performance.
Altera Corporation
17
FLEX 6000 Programmable Logic Device Family Data Sheet
The FastTrack Interconnect consists of column and row interconnect
channels that span the entire device. Each row of LABs is served by a
dedicated row interconnect, which routes signals between LABs in the
same row, and also routes signals from I/O pins to LABs. Additionally,
the local interconnect routes signals between LEs in the same LAB and in
adjacent LABs. The column interconnect routes signals between rows and
routes signals from I/O pins to rows.
LEs 1 through 5 of an LAB drive the local interconnect to the right, while
LEs 6 through 10 drive the local interconnect to the left. The DATA1 and
DATA3 inputs of each LE are driven by the local interconnect to the left;
DATA2 and DATA4 are driven by the local interconnect to the right. The
local interconnect also routes signals from LEs to I/O pins. Figure 9 shows
an overview of the FLEX 6000 interconnect architecture. LEs in the first
and last columns have drivers on both sides so that all LEs in the LAB can
drive I/O pins via the local interconnect.
Figure 9. FastTrack Interconnect Architecture
Row Interconnect (n Channels) (1)
2
2
5
5
22
10
5
5
22
10
2
2
20
5
5
20
5
5
5
5
5
5
10
10
To/From
Adjacent
LAB
5
10
10
10
LE 1
through
LE 5
5
10
10
10
LE 1
through
LE 5
10
5
10
5
10
5
10
LE 6
through
LE 10
10
Local Interconnect (32 Channels)
5
10
LE 6
through
LE 10
10
10
To/From
Adjacent
LAB
Column Interconnect (m Channels) (1)
Note:
(1)
18
For EPF6010A, EPF6016, and EPF6016A devices, n = 144 channels and m = 20 channels; for EPF6024A devices,
n = 186 channels and m = 30 channels.
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
A row channel can be driven by an LE or by one of two column channels.
These three signals feed a 3-to-1 multiplexer that connects to six specific
row channels. Row channels drive into the local interconnect via
multiplexers.
Each column of LABs is served by a dedicated column interconnect. The
LEs in an LAB can drive the column interconnect. The LEs in an LAB, a
column IOE, or a row interconnect can drive the column interconnect. The
column interconnect can then drive another row’s interconnect to route
the signals to other LABs in the device. A signal from the column
interconnect must be routed to the row interconnect before it can enter an
LAB.
Each LE has a FastTrack Interconnect output and a local output. The
FastTrack interconnect output can drive six row and two column lines
directly; the local output drives the local interconnect. Each local
interconnect channel driven by an LE can drive four row and two column
channels. This feature provides additional flexibility, because each LE can
drive any of ten row lines and four column lines.
In addition, LEs can drive global control signals. This feature is useful for
distributing internally generated clock, asynchronous clear, and
asynchronous preset signals. A pin-driven global signal can also drive
data signals, which is useful for high-fan-out data signals.
Each LAB drives two groups of local interconnects, which allows an LE to
drive two LABs, or 20 LEs, via the local interconnect. The row-to-local
multiplexers are used more efficiently, because the multiplexers can now
drive two LABs. Figure 10 shows how an LAB connects to row and
column interconnects.
Altera Corporation
19
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 10. LAB Connections to Row & Column Interconnects
Each LE FastTrack Interconnect
output can drive six row channels.
Each local channel
driven by an LE can
drive two column
channels.
Each LE output signal driving
the FastTrack Interconnect can
drive two column channels.
At each intersection,
four row channels can
drive column channels.
Row
Interconnect
Each local channel
driven by an LE can
drive four row channels.
Row interconnect
drives the local
interconnect.
LE
From Adjacent
Local Interconnect
LE
Local Interconnect
Column Interconnect
Any column channel can
drive six row channels.
An LE can be driven by any signal
from two local interconnect areas.
For improved routability, the row interconnect consists of full-length and
half-length channels. The full-length channels connect to all LABs in a
row; the half-length channels connect to the LABs in half of the row. In
addition to providing a predictable, row-wide interconnect, this
architecture provides increased routing resources. Two neighboring LABs
can be connected using a half-length channel, which saves the other half
of the channel for the other half of the row. One-third of the row channels
are half-length channels.
20
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 5 summarizes the FastTrack Interconnect resources available in
each FLEX 6000 device.
Table 5. FLEX 6000 FastTrack Interconnect Resources
Device
Rows
Channels per
Row
Columns
Channels per
Column
EPF6010A
4
144
22
20
EPF6016
EPF6016A
6
144
22
20
EPF6024A
7
186
28
30
In addition to general-purpose I/O pins, FLEX 6000 devices have four
dedicated input pins that provide low-skew signal distribution across the
device. These four inputs can be used for global clock and asynchronous
clear control signals. These signals are available as control signals for all
LEs in the device. The dedicated inputs can also be used as generalpurpose data inputs because they can feed the local interconnect of each
LAB in the device. Using dedicated inputs to route data signals provides
a fast path for high fan-out signals.
The local interconnect from LABs located at either end of two rows can
drive a global control signal. For instance, in an EPF6016 device, LABs C1,
D1, C22, and D22 can all drive global control signals. When an LE drives
a global control signal, the dedicated input pin that drives that signal
cannot be used. Any LE in the device can drive a global control signal by
driving the FastTrack Interconnect into the appropriate LAB. To minimize
delay, however, the Altera software places the driving LE in the
appropriate LAB. The LE-driving-global signal feature is optimized for
speed for control signals; regular data signals are better routed on the
FastTrack Interconnect and do not receive any advantage from being
routed on global signals. This LE-driving-global control signal feature is
controlled by the designer and is not used automatically by the Altera
software. See Figure 11.
Altera Corporation
21
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 11. Global Clock & Clear Distribution
(2)
LAB C1
Note (1)
4 (3)
LAB
(Repeated
Across
Device)
(4)
LAB C22
Dedicated
Inputs
Dedicated
Inputs
(2)
(4)
LAB D1
LAB D22
Notes:
(1)
(2)
(3)
(4)
The global clock and clear distribution signals are shown for EPF6016 and EPF6016A devices. In EPF6010A devices,
LABs in rows B and C drive global signals. In EPF6024A devices, LABs in rows C and E drive global signals.
The local interconnect from LABs C1 and D1 can drive two global control signals on the left side.
Global signals drive into every LAB as clock, asynchronous clear, preset, and data signals.
The local interconnect from LABs C22 and D22 can drive two global control signals on the right side.
22
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
I/O Elements
An IOE contains a bidirectional I/O buffer and a tri-state buffer. IOEs can
be used as input, output, or bidirectional pins. An IOE receives its data
signals from the adjacent local interconnect, which can be driven by a row
or column interconnect (allowing any LE in the device to drive the IOE) or
by an adjacent LE (allowing fast clock-to-output delays). A FastFLEXTM
I/O pin is a row or column output pin that receives its data signals from
the adjacent local interconnect driven by an adjacent LE. The IOE receives
its output enable signal through the same path, allowing individual
output enables for every pin and permitting emulation of open-drain
buffers. The Altera Compiler uses programmable inversion to invert the
data or output enable signals automatically where appropriate. Opendrain emulation is provided by driving the data input low and toggling
the OE of each IOE. This emulation is possible because there is one OE per
pin.
A chip-wide output enable feature allows the designer to disable all pins
of the device by asserting one pin (DEV_OE). This feature is useful during
board debugging or testing.
Figure 12 shows the IOE block diagram.
Figure 12. IOE Block Diagram
To Row or Column Interconnect
Delay
Chip-Wide Output Enable
From LAB Local Interconnect
From LAB Local Interconnect
Slew-Rate
Control
Altera Corporation
23
FLEX 6000 Programmable Logic Device Family Data Sheet
Each IOE drives a row or column interconnect when used as an input or
bidirectional pin. A row IOE can drive up to six row lines; a column IOE
can drive up to two column lines. The input path from the I/O pad to the
FastTrack Interconnect has a programmable delay element that can be
used to guarantee a zero hold time. Depending on the placement of the
IOE relative to what it is driving, the designer may choose to turn on the
programmable delay to ensure a zero hold time. Figure 13 shows how an
IOE connects to a row interconnect, and Figure 14 shows how an IOE
connects to a column interconnect.
Figure 13. IOE Connection to Row Interconnect
Row Interconnect
Any LE can drive
a pin through the
row and local
interconnect.
IOE
LAB
IOE
Up to 10 IOEs are on either
side of a row. Each IOE can
drive up to six row
channels, and each IOE data
and OE signal is driven by
the local interconnect.
FastFLEX I/O: An LE can drive a pin through the
local interconnect for faster clock-to-output times.
24
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 14. IOE Connection to Column Interconnect
Each IOE can drive two
column interconnect channels.
Each IOE data and OE signal is
driven to a local interconnect.
IOE
IOE
FastFLEX I/O: An
LE can drive a
pin through a local
interconnect for faster
clock-to-output times.
LAB
Any LE can drive a
pin through the row
and local interconnect.
Column Interconnect
Row Interconnect
SameFrame
Pin-Outs
3.3-V FLEX 6000 devices support the SameFrame pin-out feature for
FineLine BGA packages. The SameFrame pin-out feature is the
arrangement of balls on FineLine BGA packages such that the lower-ballcount packages form a subset of the higher-ball-count packages.
SameFrame pin-outs provide the flexibility to migrate not only from
device to device within the same package, but also from one package to
another. A given printed circuit board (PCB) layout can support multiple
device density/package combinations. For example, a single board layout
can support an EPF6016A device in a 100-pin FineLine BGA package or an
EPF6024A device in a 256-pin FineLine BGA package.
The Altera software packages provide support to design PCBs with
SameFrame pin-out devices. Devices can be defined for present and future
use. The Altera software packages generate pin-outs describing how to lay
out a board to take advantage of this migration (see Figure 15).
Altera Corporation
25
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 15. SameFrame Pin-Out Example
Printed Circuit Board
Designed for 256-Pin FineLine BGA Package
100-Pin
FineLine
BGA
256-Pin
FineLine
BGA
100-Pin FineLine BGA Package
(Reduced I/O Count or
Logic Requirements)
256-Pin FineLine BGA Package
(Increased I/O Count or
Logic Requirements)
Table 6 lists the 3.3-V FLEX 6000 devices with the SameFrame pin-out
feature.
Table 6. 3.3-V FLEX 6000 Devices with SameFrame Pin-Outs
Device
100-Pin FineLine BGA
256-Pin FineLine BGA
EPF6016A
v
v
EPF6024A
Output
Configuration
v
This section discusses slew-rate control, the MultiVolt I/O interface,
power sequencing, and hot-socketing for FLEX 6000 devices.
Slew-Rate Control
The output buffer in each IOE has an adjustable output slew-rate that can
be configured for low-noise or high-speed performance. A slower
slew-rate reduces system noise and adds a maximum delay of 6.8 ns. The
fast slew-rate should be used for speed-critical outputs in systems that are
adequately protected against noise. Designers can specify the slew-rate on
a pin-by-pin basis during design entry or assign a default slew rate to all
pins on a device-wide basis. The slew-rate setting affects only the falling
edge of the output.
26
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
MultiVolt I/O Interface
The FLEX 6000 device architecture supports the MultiVolt I/O interface
feature, which allows FLEX 6000 devices to interface with systems of
differing supply voltages. The EPF6016 device can be set for 3.3-V or 5.0-V
I/O pin operation. This device has one set of VCC pins for internal
operation and input buffers (VCCINT), and another set for output drivers
(VCCIO).
The VCCINT pins on 5.0-V FLEX 6000 devices must always be connected
to a 5.0-V power supply. With a 5.0-V VCCINT level, input voltages are at
TTL levels and are therefore compatible with 3.3-V and 5.0-V inputs.
The VCCIO pins on 5.0-V FLEX 6000 devices can be connected to either a
3.3-V or 5.0-V power supply, depending on the output requirements.
When the VCCIO pins are connected to a 5.0-V power supply, the output
levels are compatible with 5.0-V systems. When the VCCIO pins are
connected to a 3.3-V power supply, the output high is 3.3 V and is
therefore compatible with 3.3-V or 5.0-V systems. Devices operating with
VCCIO levels lower than 4.75 V incur a nominally greater timing delay of
tOD2 instead of tOD1.
On 3.3-V FLEX 6000 devices, the VCCINT pins must be connected to a
3.3-V power supply. Additionally, 3.3-V FLEX 6000A devices can interface
with 2.5-V, 3.3-V, or 5.0-V systems when the VCCIO pins are tied to 2.5 V.
The output can drive 2.5-V systems, and the inputs can be driven by 2.5V, 3.3-V, or 5.0-V systems. When the VCCIO pins are tied to 3.3 V, the
output can drive 3.3-V or 5.0-V systems. MultiVolt I/Os are not supported
on 100-pin TQFP or 100-pin FineLine BGA packages.
Table 7 describes FLEX 6000 MultiVolt I/O support.
Table 7. FLEX 6000 MultiVolt I/O Support
VCCINT
(V)
VCCIO
(V)
3.3
Input Signal (V)
Output Signal (V)
2.5
3.3
5.0
2.5
2.5
v
v
v
v
3.3
3.3
v
v
v
v (1)
5.0
3.3
v
v
5.0
5.0
v
v
3.3
5.0
v
v
v
v
v
Note:
(1)
Altera Corporation
When VCCIO = 3.3 V, a FLEX 6000 device can drive a 2.5-V device that has 3.3-V
tolerant inputs.
27
FLEX 6000 Programmable Logic Device Family Data Sheet
Open-drain output pins on 5.0-V or 3.3-V FLEX 6000 devices (with a pullup resistor to the 5.0-V supply) can drive 5.0-V CMOS input pins that
require a VIH of 3.5 V. When the open-drain pin is active, it will drive low.
When the pin is inactive, the trace will be pulled up to 5.0 V by the resistor.
The open-drain pin will only drive low or tri-state; it will never drive high.
The rise time is dependent on the value of the pull-up resistor and load
impedance. The IOL current specification should be considered when
selecting a pull-up resistor.
Output pins on 5.0-V FLEX 6000 devices with VCCIO = 3.3 V or 5.0 V (with
a pull-up resistor to the 5.0-V supply) can also drive 5.0-V CMOS input
pins. In this case, the pull-up transistor will turn off when the pin voltage
exceeds 3.3 V. Therefore, the pin does not have to be open-drain.
Power Sequencing & Hot-Socketing
Because FLEX 6000 family devices can be used in a mixed-voltage
environment, they have been designed specifically to tolerate any possible
power-up sequence. The VCCIO and VCCINT power planes can be powered
in any order.
Signals can be driven into 3.3-V FLEX 6000 devices before and during
power up without damaging the device. Additionally, FLEX 6000 devices
do not drive out during power up. Once operating conditions are reached,
FLEX 6000 devices operate as specified by the user.
IEEE Std.
1149.1 (JTAG)
Boundary-Scan
Support
All FLEX 6000 devices provide JTAG BST circuitry that comply with the
IEEE Std. 1149.1-1990 specification. Table 8 shows JTAG instructions for
FLEX 6000 devices. JTAG BST can be performed before or after
configuration, but not during configuration (except when you disable
JTAG support in user mode).
1
See Application Note 39 (IEEE 1149.1 (JTAG) Boundary-Scan
Testing in Altera Devices) for more information on JTAG BST
circuitry.
Table 8. FLEX 6000 JTAG Instructions
JTAG Instruction
Description
SAMPLE/PRELOAD Allows a snapshot of the signals at the device pins to be captured and examined during
normal device operation, and permits an initial data pattern to be output at the device pins.
EXTEST
Allows the external circuitry and board-level interconnections to be tested by forcing a test
pattern at the output pins and capturing test result at the input pins.
BYPASS
Places the 1-bit bypass register between the TDI and TDO pins, which allows the BST
data to pass synchronously through the selected device to adjacent devices during
normal device operation.
28
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
The instruction register length for FLEX 6000 devices is three bits. Table 9
shows the boundary-scan register length for FLEX 6000 devices.
Table 9. FLEX 6000 Device Boundary-Scan Register Length
Device
Boundary-Scan Register Length
EPF6010A
522
EPF6016
621
EPF6016A
522
EPF6024A
666
FLEX 6000 devices include a weak pull-up on JTAG pins.
f
See Application Note 39 (IEEE 1149.1 (JTAG) Boundary-Scan Testing in Altera
Devices) for more information.
Figure 16 shows the timing requirements for the JTAG signals.
Figure 16. JTAG Waveforms
TMS
TDI
t JCP
t JCH
t JCL
t JPSU
t JPH
TCK
tJPZX
t JPXZ
t JPCO
TDO
tJSSU
Signal
to Be
Captured
Signal
to Be
Driven
tJSZX
tJSH
tJSCO
tJSXZ
Table 10 shows the JTAG timing parameters and values for FLEX 6000
devices.
Altera Corporation
29
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 10. JTAG Timing Parameters & Values
Symbol
Generic Testing
Parameter
Min
Max
Unit
tJCP
TCK clock period
100
ns
tJCH
TCK clock high time
50
ns
tJCL
TCK clock low time
50
ns
tJPSU
JTAG port setup time
20
ns
tJPH
JTAG port hold time
45
tJPCO
JTAG port clock-to-output
25
tJPZX
JTAG port high impedance to valid output
25
ns
tJPXZ
JTAG port valid output to high impedance
25
ns
tJSSU
Capture register setup time
20
tJSH
Capture register hold time
45
tJSCO
Update register clock-to-output
35
ns
tJSZX
Update register high impedance to valid
output
35
ns
tJSXZ
Update register valid output to high
impedance
35
ns
ns
ns
ns
ns
Each FLEX 6000 device is functionally tested. Complete testing of each
configurable SRAM bit and all logic functionality ensures 100%
configuration yield. AC test measurements for FLEX 6000 devices are
made under conditions equivalent to those shown in Figure 17. Multiple
test patterns can be used to configure devices during all stages of the
production flow.
Figure 17. AC Test Conditions
Power supply transients can affect
AC measurements. Simultaneous
transitions of multiple outputs
should be avoided for accurate
464 Ω
measurement. Threshold tests must
(703 Ω)
not be performed under AC conditions.
[521 Ω]
Large-amplitude, fast-ground-current
transients normally occur as the
Device
device outputs discharge the load
Output
capacitances. When these transients
flow through the parasitic
inductance between the device
250 Ω
ground pin and the test system ground,
(8.06 kΩ)
significant reductions in observable
[481 Ω]
noise immunity can result. Numbers
Device input
without parentheses are for 5.0-V
rise and fall
devices or outputs. Numbers in
times < 3 ns
parentheses are for 3.3-V devices or
outputs. Numbers in brackets are for
2.5-V devices or outputs.
30
VCC
To Test
System
C1 (includes
JIG capacitance)
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Operating
Conditions
Tables 11 through 18 provide information on absolute maximum ratings,
recommended operating conditions, operating conditions, and
capacitance for 5.0-V and 3.3-V FLEX 6000 devices.
Table 11. FLEX 6000 5.0-V Device Absolute Maximum Ratings
Symbol
Parameter
Note (1)
Conditions
Min
Max
Unit
With respect to ground (2)
V
V CC
Supply voltage
–2.0
7.0
VI
DC input voltage
–2.0
7.0
V
I OUT
DC output current, per pin
–25
25
mA
T STG
Storage temperature
No bias
–65
150
°C
T AMB
Ambient temperature
Under bias
–65
135
°C
TJ
Junction temperature
PQFP, TQFP, and BGA packages
135
°C
Min
Max
Unit
Table 12. FLEX 6000 5.0-V Device Recommended Operating Conditions
Symbol
Parameter
Conditions
V CCINT
Supply voltage for internal logic
and input buffers
(3), (4)
4.75 (4.50)
5.25 (5.50)
V
V CCIO
Supply voltage for output buffers, (3), (4)
5.0-V operation
4.75 (4.50)
5.25 (5.50)
V
Supply voltage for output buffers, (3), (4)
3.3-V operation
3.00 (3.00)
3.60 (3.60)
V
–0.5
V CCINT + 0.5
V
0
V CCIO
V
VI
Input voltage
VO
Output voltage
TJ
Operating temperature
For commercial use
For industrial use
0
85
°C
–40
100
°C
tR
Input rise time
40
ns
tF
Input fall time
40
ns
Altera Corporation
31
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 13. FLEX 6000 5.0-V Device DC Operating Conditions
Symbol
Parameter
Notes (5), (6)
Conditions
Min
Typ
Max
Unit
V
V IH
High-level input voltage
2.0
V CCINT + 0.5
V IL
Low-level input voltage
–0.5
0.8
V OH
5.0-V high-level TTL output
voltage
I OH = –8 mA DC, V CCIO = 4.75 V (7)
2.4
V
3.3-V high-level TTL output
voltage
I OH = –8 mA DC, V CCIO = 3.00 V (7)
2.4
V
3.3-V high-level CMOS output
voltage
I OH = –0.1 mA DC, V CCIO = 3.00 V (7)
V CCIO – 0.2
V
5.0-V low-level TTL output
voltage
I OL = 8 mA DC, V CCIO = 4.75 V (8)
0.45
V
3.3-V low-level TTL output
voltage
I OL = 8 mA DC, V CCIO = 3.00 V (8)
0.45
V
3.3-V low-level CMOS output
voltage
I OL = 0.1 mA DC, V CCIO = 3.00 V (8)
0.2
V
II
Input pin leakage current
V I = V CC or ground (8)
–10
10
µA
I OZ
Tri-stated I/O pin leakage current V O = V CC or ground (8)
V CC supply current (standby)
V I = ground, no load
–40
40
µA
5
mA
V OL
I CC0
Table 14. FLEX 6000 5.0-V Device Capacitance
Symbol
Parameter
0.5
V
Note (9)
Max
Unit
C IN
Input capacitance for I/O pin
V IN = 0 V, f = 1.0 MHz
Conditions
8
pF
CINCLK
Input capacitance for dedicated input V IN = 0 V, f = 1.0 MHz
12
pF
C OUT
Output capacitance
8
pF
V OUT = 0 V, f = 1.0 MHz
Min
Notes to tables:
(1)
(2)
(9)
See the Operating Requirements for Altera Devices Data Sheet.
Minimum DC input is –0.5 V. During transitions, the inputs may undershoot to –2.0 V or overshoot to 7.0 V for
input currents less than 100 mA and periods shorter than 20 ns.
Numbers in parentheses are for industrial-temperature-range devices.
Maximum VCC rise time to 100 ms. VCC must rise monotonically.
Typical values are for T A = 25° C and V CC = 5.0 V.
These values are specified under the FLEX 6000 Recommended Operating Conditions shown in Table 12 on
page 31.
The IOH parameter refers to high-level TTL or CMOS output current.
The IOL parameter refers to low-level TTL, PCI, or CMOS output current. This parameter applies to open-drain pins
as well as output pins.
Capacitance is sample-tested only.
32
Altera Corporation
(3)
(4)
(5)
(6)
(7)
(8)
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 15. FLEX 6000 3.3-V Device Absolute Maximum Ratings
Symbol
Parameter
Note (1)
Min
Max
Unit
–0.5
4.6
V
DC input voltage
–2.0
5.75
V
I OUT
DC output current, per pin
–25
25
mA
T STG
Storage temperature
No bias
–65
150
°C
T AMB
Ambient temperature
Under bias
–65
135
°C
TJ
Junction temperature
PQFP, PLCC, and BGA packages
135
°C
V CC
Supply voltage
VI
Conditions
With respect to ground (2)
Table 16. FLEX 6000 3.3-V Device Recommended Operating Conditions
Min
Max
Unit
V CCINT
Symbol
Supply voltage for internal logic and (3), (4)
input buffers
Parameter
3.00 (3.00)
3.60 (3.60)
V
V CCIO
Supply voltage for output buffers,
3.3-V operation
(3), (4)
3.00 (3.00)
3.60 (3.60)
V
Supply voltage for output buffers,
2.5-V operation
(3), (4)
2.30 (2.30)
2.70 (2.70)
V
VI
Input voltage
VO
Output voltage
TJ
Operating temperature
Conditions
For commercial use
For industrial use
–0.5
5.75
V
0
V CCIO
V
0
85
°C
–40
100
°C
tR
Input rise time
40
ns
tF
Input fall time
40
ns
Altera Corporation
33
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 17. FLEX 6000 3.3-V Device DC Operating Conditions
Symbol
Parameter
Notes (5), (6)
Conditions
Min
Typ
Max
Unit
V IH
High-level input voltage
1.7
5.75
V
V IL
Low-level input voltage
–0.5
0.8
V
V OH
3.3-V high-level TTL output
voltage
I OH = –8 mA DC, V CCIO = 3.00 V (7)
3.3-V high-level CMOS output
voltage
2.5-V high-level output voltage
V OL
2.4
V
I OH = –0.1 mA DC, V CCIO = 3.00 V (7)
V CCIO – 0.2
V
I OH = –100 µA DC, V CCIO = 2.30 V (7)
2.1
V
I OH = –1 mA DC, V CCIO = 2.30 V (7)
2.0
V
I OH = –2 mA DC, V CCIO = 2.30 V (7)
1.7
V
3.3-V low-level TTL output
voltage
I OL = 8 mA DC, V CCIO = 3.00 V (8)
0.45
V
3.3-V low-level CMOS output
voltage
I OL = 0.1 mA DC, V CCIO = 3.00 V (8)
0.2
V
2.5-V low-level output voltage
I OL = 100 µA DC, V CCIO = 2.30 V (8)
0.2
V
I OL = 1 mA DC, V CCIO = 2.30 V (8)
0.4
V
I OL = 2 mA DC, V CCIO = 2.30 V (8)
0.7
V
10
µA
II
Input pin leakage current
V I = 5.3 V to ground (8)
I OZ
Tri-stated I/O pin leakage current V O = 5.3 V to ground (8)
I CC0
V CC supply current (standby)
Parameter
–10
V I = ground, no load
Table 18. FLEX 6000 3.3-V Device Capacitance
Symbol
–10
0.5
10
µA
5
mA
Note (9)
Max
Unit
C IN
Input capacitance for I/O pin
V IN = 0 V, f = 1.0 MHz
Conditions
8
pF
CINCLK
Input capacitance for dedicated input V IN = 0 V, f = 1.0 MHz
12
pF
C OUT
Output capacitance
8
pF
V OUT = 0 V, f = 1.0 MHz
Min
Notes to tables:
(1)
(2)
(9)
See the Operating Requirements for Altera Devices Data Sheet.
The minimum DC input voltage is –0.5 V. During transitions, the inputs may undershoot to –2.0 V or overshoot to
5.75 V for input currents less than 100 mA and periods shorter than 20 ns.
Numbers in parentheses are for industrial-temperature-range devices.
Maximum VCC rise time is 100 ms. VCC must rise monotonically.
Typical values are for T A = 25° C and V CC = 3.3 V.
These values are specified under Table 16 on page 33.
The IOH parameter refers to high-level TTL or CMOS output current.
The IOL parameter refers to low-level TTL, PCI, or CMOS output current. This parameter applies to open-drain pins
as well as output pins.
Capacitance is sample-tested only.
34
Altera Corporation
(3)
(4)
(5)
(6)
(7)
(8)
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 18 shows the typical output drive characteristics of 5.0-V and 3.3-V
FLEX 6000 devices with 5.0-V, 3.3-V, and 2.5-V VCCIO. When
VCCIO = 5.0 V on EPF6016 devices, the output driver is compliant with the
PCI Local Bus Specification, Revision 2.2 for 5.0-V operation. When
VCCIO = 3.3 V on the EPF6010A and EPF6016A devices, the output driver
is compliant with the PCI Local Bus Specification, Revision 2.2 for 3.3-V
operation.
Figure 18. Output Drive Characteristics
EPF6010A
EPF6016A
EPF6010A
EPF6016A
VCCINT = 3.3 V
VCCIO = 3.3 V
Room Temperature
100
75
Typical IO
Output
Current (mA)
VCCINT = 3.3 V
VCCIO = 2.5 V
Room Temperature
100
75
Typical IO
Output
Current (mA)
IOL
50
IOL
50
IOH
IOH
25
25
1
2
3
4
5
1
VO Output Voltage (V)
2
EPF6016
4
5
EPF6016
150
150
IOL
IOL
120
120
90
Typical IO
Output
Current (mA)
90
Typical IO
Output
Current (mA)
VCCINT = 5.0 V
VCCIO = 5.0 V
Room Temperature
60
1
2
VCCINT = 5.0 V
VCCIO = 3.3 V
Room Temperature
60
IOH
IOH
30
30
3
4
1
5
2
3 3.3
4
5
VO Output Voltage (V)
VO Output Voltage (V)
EPF6024A
EPF6024A
100
100
VCCINT = 3.3 V
VCCIO = 3.3 V
Room Temperature
75
Typical IO
Output
Current (mA)
VCCINT = 3.3 V
VCCIO = 2.5 V
Room Temperature
75
Typical IO
Output
Current (mA)
IOL
50
IOL
50
25
25
IOH
1
2
3
IOH
4
VO Output Voltage (V)
Altera Corporation
3
VO Output Voltage (V)
5
1
2
3
4
5
VO Output Voltage (V)
35
FLEX 6000 Programmable Logic Device Family Data Sheet
Timing Model
The continuous, high-performance FastTrack Interconnect routing
resources ensure predictable performance and accurate simulation and
timing analysis. This predictable performance contrasts with that of
FPGAs, which use a segmented connection scheme and therefore have
unpredictable performance.
Device performance can be estimated by following the signal path from a
source, through the interconnect, to the destination. For example, the
registered performance between two LEs on the same row can be
calculated by adding the following parameters:
■
■
■
■
LE register clock-to-output delay (tCO + tREG_TO_OUT)
Routing delay (tROW + tLOCAL)
LE LUT delay (tDATA_TO_REG)
LE register setup time (tSU)
The routing delay depends on the placement of the source and destination
LEs. A more complex registered path may involve multiple combinatorial
LEs between the source and destination LEs.
Timing simulation and delay prediction are available with the Simulator
and Timing Analyzer, or with industry-standard EDA tools. The
Simulator offers both pre-synthesis functional simulation to evaluate logic
design accuracy and post-synthesis timing simulation with 0.1-ns
resolution. The Timing Analyzer provides point-to-point timing delay
information, setup and hold time analysis, and device-wide performance
analysis.
Figure 19 shows the overall timing model, which maps the possible
routing paths to and from the various elements of the FLEX 6000 device.
36
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 19. FLEX 6000 Timing Model
tROW
Carry-In from
Previous LE
tLOCAL
Cascade-In from
Previous LE
tCASC_TO_OUT
tCARRY_TO_OUT
tDATA_TO_OUT
tREG_TO_OUT
tSU
tH
tCO
tCLR
tREG_TO_REG
tCASC_TO_REG
tCARRY_TO_REG
tDATA_TO_REG
tCOL
tC
tLD_CLR
tLEGLOBAL
tCARRY_TO_CARRY
tREG_TO_CARRY
tDATA_TO_CARRY
tDIN_D
tLABCARRY
tCARRY_TO_CASC
tCASC_TO_CASC
tREG_TO_CASC
tDATA_TO_CASC
LE
tLABCASC
tDIN_C
Carry-out to Carry-out to
Next LE in Next LE in
Same LAB Next LAB
tIOE
Cascade-out Cascade-out
to Next LE in to Next LE in
Same LAB
Next LAB
I/O Pin
tOD1
tOD2
tOD3
tXZ
tZX1
tZX2
tZX3
tIN
tIN_DELAY
IOE
Altera Corporation
37
FLEX 6000 Programmable Logic Device Family Data Sheet
Tables 19 through 21 describe the FLEX 6000 internal timing
microparameters, which are expressed as worst-case values. Using hand
calculations, these parameters can be used to estimate design
performance. However, before committing designs to silicon, actual
worst-case performance should be modeled using timing simulation and
timing analysis. Tables 22 and 23 describe FLEX 6000 external timing
parameters.
Table 19. LE Timing Microparameters
Note (1)
Symbol
Parameter
tREG_TO_REG
LUT delay for LE register feedback in carry chain
tCASC_TO_REG
Cascade-in to register delay
tCARRY_TO_REG
Carry-in to register delay
tDATA_TO_REG
LE input to register delay
tCASC_TO_OUT
Cascade-in to LE output delay
tCARRY_TO_OUT
Carry-in to LE output delay
tDATA_TO_OUT
LE input to LE output delay
tREG_TO_OUT
Register output to LE output delay
tSU
LE register setup time before clock; LE register recovery time after
asynchronous clear
tH
LE register hold time after clock
tCO
LE register clock-to-output delay
tCLR
LE register clear delay
tC
LE register control signal delay
tLD_CLR
Synchronous load or clear delay in counter mode
Conditions
tCARRY_TO_CARRY Carry-in to carry-out delay
tREG_TO_CARRY
Register output to carry-out delay
tDATA_TO_CARRY
LE input to carry-out delay
tCARRY_TO_CASC
Carry-in to cascade-out delay
tCASC_TO_CASC
Cascade-in to cascade-out delay
tREG_TO_CASC
Register-out to cascade-out delay
tDATA_TO_CASC
LE input to cascade-out delay
tCH
LE register clock high time
tCL
LE register clock low time
38
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 20. IOE Timing Microparameters
Note (1)
Symbol
Parameter
Conditions
tOD1
Output buffer and pad delay, slow slew rate = off, VCCIO = VCCINT
C1 = 35 pF (2)
tOD2
Output buffer and pad delay, slow slew rate = off, VCCIO = low voltage
C1 = 35 pF (3)
tOD3
Output buffer and pad delay, slow slew rate = on
C1 = 35 pF (4)
tXZ
Output buffer disable delay
C1 = 5 pF
C1 = 35 pF (2)
tZX1
Output buffer enable delay, slow slew rate = off, VCCIO = VCCINT
tZX2
Output buffer enable delay, slow slew rate = off, VCCIO = low voltage
C1 = 35 pF (3)
tZX3
IOE output buffer enable delay, slow slew rate = on
C1 = 35 pF (4)
tIOE
Output enable control delay
tIN
Input pad and buffer to FastTrack Interconnect delay
tIN_DELAY
Input pad and buffer to FastTrack Interconnect delay with additional delay
turned on
Table 21. Interconnect Timing Microparameters
Symbol
Note (1)
Parameter
Conditions
tLOCAL
LAB local interconnect delay
tROW
Row interconnect routing delay
(5)
tCOL
Column interconnect routing delay
(5)
tDIN_D
Dedicated input to LE data delay
(5)
tDIN_C
Dedicated input to LE control delay
tLEGLOBAL
LE output to LE control via internally-generated global signal delay
tLABCARRY
Routing delay for the carry-out of an LE driving the carry-in signal of a
different LE in a different LAB
tLABCASC
Routing delay for the cascade-out signal of an LE driving the cascade-in
signal of a different LE in a different LAB
(5)
Table 22. External Reference Timing Parameters
Symbol
Parameter
Conditions
t1
Register-to-register test pattern
(6)
tDRR
Register-to-register delay via 4 LEs, 3 row interconnects, and 4 local
interconnects
(7)
Altera Corporation
39
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 23. External Timing Parameters
Symbol
Parameter
Conditions
tINSU
Setup time with global clock at LE register
(8)
tINH
Hold time with global clock at LE register
(8)
tOUTCO
Clock-to-output delay with global clock with LE register using FastFLEX I/O
pin
(8)
Notes to tables:
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
Microparameters are timing delays contributed by individual architectural elements and cannot be measured
explicitly.
Operating conditions:
VCCIO = 5.0 V ± 5% for commercial use in 5.0-V FLEX 6000 devices.
VCCIO = 5.0 V ± 10% for industrial use in 5.0-V FLEX 6000 devices.
VCCIO = 3.3 V ± 10% for commercial or industrial use in 3.3-V FLEX 6000 devices.
Operating conditions:
VCCIO = 3.3 V ± 10% for commercial or industrial use in 5.0-V FLEX 6000 devices.
VCCIO = 2.5 V ± 0.2 V for commercial or industrial use in 3.3-V FLEX 6000 devices.
Operating conditions:
VCCIO = 2.5 V, 3.3 V, or 5.0 V.
These parameters are worst-case values for typical applications. Post-compilation timing simulation and timing
analysis are required to determine actual worst-case performance.
This timing parameter shows the delay of a register-to-register test pattern and is used to determine speed grades.
There are 12 LEs, including source and destination registers. The row and column interconnects between the
registers vary in length.
This timing parameter is shown for reference and is specified by characterization.
This timing parameter is specified by characterization.
Tables 24 through 28 show the timing information for EPF6010A and
EPF6016A devices.
Table 24. LE Timing Microparameters for EPF6010A & EPF6016A Devices (Part 1 of 2)
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tREG_TO_REG
1.2
1.3
1.7
ns
tCASC_TO_REG
0.9
1.0
1.2
ns
tCARRY_TO_REG
0.9
1.0
1.2
ns
tDATA_TO_REG
1.1
1.2
1.5
ns
tCASC_TO_OUT
1.3
1.4
1.8
ns
tCARRY_TO_OUT
1.6
1.8
2.3
ns
tDATA_TO_OUT
1.7
2.0
2.5
ns
tREG_TO_OUT
0.4
0.4
0.5
ns
tSU
0.9
1.0
1.3
ns
tH
1.4
1.7
2.1
ns
40
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 24. LE Timing Microparameters for EPF6010A & EPF6016A Devices (Part 2 of 2)
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tCO
0.3
0.4
0.4
ns
tCLR
0.4
0.4
0.5
ns
tC
1.8
2.1
2.6
ns
tLD_CLR
1.8
2.1
2.6
ns
tCARRY_TO_CARRY
0.1
0.1
0.1
ns
tREG_TO_CARRY
1.6
1.9
2.3
ns
tDATA_TO_CARRY
2.1
2.5
3.0
ns
tCARRY_TO_CASC
1.0
1.1
1.4
ns
tCASC_TO_CASC
0.5
0.6
0.7
ns
tREG_TO_CASC
1.4
1.7
2.1
ns
tDATA_TO_CASC
1.1
1.2
1.5
ns
tCH
2.5
3.0
3.5
ns
tCL
2.5
3.0
3.5
ns
Table 25. IOE Timing Microparameters for EPF6010A & EPF6016A Devices
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tOD1
1.9
2.2
2.7
ns
tOD2
4.1
4.8
5.8
ns
tOD3
5.8
6.8
8.3
ns
tXZ
1.4
1.7
2.1
ns
tXZ1
1.4
1.7
2.1
ns
tXZ2
3.6
4.3
5.2
ns
tXZ3
5.3
6.3
7.7
ns
tIOE
0.5
0.6
0.7
ns
tIN
3.6
4.1
5.1
ns
tIN_DELAY
4.8
5.4
6.7
ns
Altera Corporation
41
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 26. Interconnect Timing Microparameters for EPF6010A & EPF6016A Devices
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tLOCAL
0.7
0.7
1.0
ns
tROW
2.9
3.2
3.2
ns
tCOL
1.2
1.3
1.4
ns
tDIN_D
5.4
5.7
6.4
ns
tDIN_C
4.3
5.0
6.1
ns
tLEGLOBAL
2.6
3.0
3.7
ns
tLABCARRY
0.7
0.8
0.9
ns
tLABCASC
1.3
1.4
1.8
ns
Table 27. External Reference Timing Parameters for EPF6010A & EPF6016A Devices
Parameter
Device
Speed Grade
-1
Min
t1
Unit
-2
Max
Min
-3
Max
Min
Max
EPF6010A
37.6
43.6
53.7
ns
EPF6016A
38.0
44.0
54.1
ns
Table 28. External Timing Parameters for EPF6010A & EPF6016A Devices
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
tINSU
2.1 (1)
2.4 (1)
3.3 (1)
tINH
0.2 (2)
0.3 (2)
0.1 (2)
tOUTCO
2.0
7.1
2.0
8.2
2.0
Max
ns
ns
10.1
ns
Notes:
(1)
(2)
Setup times are longer when the Increase Input Delay option is turned on. The setup time values are shown with the
Increase Input Delay option turned off.
Hold time is zero when the Increase Input Delay option is turned on.
42
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Tables 29 through 33 show the timing information for EPF6016 devices.
Table 29. LE Timing Microparameters for EPF6016 Devices
Parameter
Speed Grade
-2
Min
Unit
-3
Max
Min
Max
tREG_TO_REG
2.2
2.8
ns
tCASC_TO_REG
0.9
1.2
ns
tCARRY_TO_REG
1.6
2.1
ns
tDATA_TO_REG
2.4
3.0
ns
tCASC_TO_OUT
1.3
1.7
ns
tCARRY_TO_OUT
2.4
3.0
ns
tDATA_TO_OUT
2.7
3.4
ns
tREG_TO_OUT
0.3
0.5
ns
tSU
1.1
1.6
tH
1.8
2.3
ns
ns
tCO
0.3
0.4
ns
tCLR
0.5
0.6
ns
tC
1.2
1.5
ns
tLD_CLR
1.2
1.5
ns
tCARRY_TO_CARRY
0.2
0.4
ns
tREG_TO_CARRY
0.8
1.1
ns
tDATA_TO_CARRY
1.7
2.2
ns
tCARRY_TO_CASC
1.7
2.2
ns
tCASC_TO_CASC
0.9
1.2
ns
tREG_TO_CASC
1.6
2.0
ns
tDATA_TO_CASC
1.7
2.1
ns
tCH
4.0
4.0
ns
tCL
4.0
4.0
ns
Table 30. IOE Timing Microparameters for EPF6016 Devices
Parameter
Speed Grade
-2
Min
Unit
-3
Max
Min
Max
tOD1
2.3
2.8
ns
tOD2
4.6
5.1
ns
Altera Corporation
43
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 30. IOE Timing Microparameters for EPF6016 Devices
Parameter
Speed Grade
-2
Min
Unit
-3
Max
Min
Max
tOD3
4.7
5.2
ns
tXZ
2.3
2.8
ns
tZX1
2.3
2.8
ns
tZX2
4.6
5.1
ns
tZX3
4.7
5.2
ns
tIOE
0.5
0.6
ns
tIN
3.3
4.0
ns
tIN_DELAY
4.6
5.6
ns
Table 31. Interconnect Timing Microparameters for EPF6016 Devices
Parameter
Speed Grade
-2
Min
Unit
-3
Max
Min
Max
tLOCAL
0.8
1.0
ns
tROW
2.9
3.3
ns
tCOL
2.3
2.5
ns
tDIN_D
4.9
6.0
ns
tDIN_C
4.8
6.0
ns
tLEGLOBAL
3.1
3.9
ns
tLABCARRY
0.4
0.5
ns
tLABCASC
0.8
1.0
ns
Table 32. External Reference Timing Parameters for EPF6016 Devices
Parameter
Speed Grade
-2
Min
Unit
-3
Max
Min
Max
t1
53.0
65.0
ns
tDRR
16.0
20.0
ns
44
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 33. External Timing Parameters for EPF6016 Devices
Parameter
Speed Grade
-2
Min
tINSU
3.2
tINH
0.0
tOUTCO
2.0
Unit
-3
Max
Min
Max
4.1
ns
0.0
7.9
ns
2.0
9.9
ns
Tables 34 through 38 show the timing information for EPF6024A devices.
Table 34. LE Timing Microparameters for EPF6024A Devices
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tREG_TO_REG
1.2
1.3
1.6
ns
tCASC_TO_REG
0.7
0.8
1.0
ns
tCARRY_TO_REG
1.6
1.8
2.2
ns
tDATA_TO_REG
1.3
1.4
1.7
ns
tCASC_TO_OUT
1.2
1.3
1.6
ns
tCARRY_TO_OUT
2.0
2.2
2.6
ns
tDATA_TO_OUT
1.8
2.1
2.6
ns
tREG_TO_OUT
0.3
0.3
0.4
ns
tSU
0.9
1.0
1.2
tH
1.3
1.4
1.7
ns
ns
tCO
0.2
0.3
0.3
ns
tCLR
0.3
0.3
0.4
ns
tC
1.9
2.1
2.5
ns
tLD_CLR
1.9
2.1
2.5
ns
tCARRY_TO_CARRY
0.2
0.2
0.3
ns
tREG_TO_CARRY
1.4
1.6
1.9
ns
tDATA_TO_CARRY
1.3
1.4
1.7
ns
tCARRY_TO_CASC
1.1
1.2
1.4
ns
tCASC_TO_CASC
0.7
0.8
1.0
ns
tREG_TO_CASC
1.4
1.6
1.9
ns
tDATA_TO_CASC
1.0
1.1
1.3
ns
tCH
2.5
3.0
3.5
ns
tCL
2.5
3.0
3.5
ns
Altera Corporation
45
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 35. IOE Timing Microparameters for EPF6024A Devices
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tOD1
1.9
2.1
2.5
ns
tOD2
4.0
4.4
5.3
ns
tOD3
7.0
7.8
9.3
ns
tXZ
4.3
4.8
5.8
ns
tXZ1
4.3
4.8
5.8
ns
tXZ2
6.4
7.1
8.6
ns
tXZ3
9.4
10.5
12.6
ns
tIOE
0.5
0.6
0.7
ns
tIN
3.3
3.7
4.4
ns
tIN_DELAY
5.3
5.9
7.0
ns
Table 36. Interconnect Timing Microparameters for EPF6024A Devices
Parameter
Speed Grade
-1
Min
Unit
-2
Max
Min
-3
Max
Min
Max
tLOCAL
0.8
0.8
1.1
ns
tROW
3.0
3.1
3.3
ns
tCOL
3.0
3.2
3.4
ns
tDIN_D
5.4
5.6
6.2
ns
tDIN_C
4.6
5.1
6.1
ns
tLEGLOBAL
3.1
3.5
4.3
ns
tLABCARRY
0.6
0.7
0.8
ns
tLABCASC
0.3
0.3
0.4
ns
Table 37. External Reference Timing Parameters for EPF6024A Devices
Parameter
Speed Grade
-1
Min
t1
46
Unit
-2
Max
45.0
Min
-3
Max
50.0
Min
Max
60.0
ns
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Table 38. External Timing Parameters for EPF6024A Devices
Parameter
Speed Grade
-1
Min
-2
Max
tINSU
2.0 (1)
tINH
0.2 (2)
tOUTCO
2.0
Unit
Min
-3
Max
2.2 (1)
2.0
Max
2.6 (1)
0.2 (2)
7.4
Min
ns
0.3 (2)
8.2
2.0
ns
9.9
ns
Notes:
(1)
(2)
Setup times are longer when the Increase Input Delay option is turned on. The setup time values are shown with the
Increase Input Delay option turned off.
Hold time is zero when the Increase Input Delay option is turned on.
Power
Consumption
The supply power (P) for FLEX 6000 devices can be calculated with the
following equations:
P = PINT + PIO
P = (ICCSTANDBY + ICCACTIVE) × VCC + PIO
Typical ICCSTANDBY values are shown as ICC0 in the “FLEX 6000 Device
DC Operating Conditions” table on pages 31 and 33 of this data sheet. The
ICCACTIVE value depends on the switching frequency and the application
logic. This value is based on the amount of current that each LE typically
consumes. The PIO value, which depends on the device output load
characteristics and switching frequency, can be calculated using the
guidelines given in Application Note 74 (Evaluating Power for Altera Devices).
The ICCACTIVE value can be calculated with the following equation:
µA
ICCACTIVE = K × fMAX × N × togLC × ----------------------------MHz × LE
Where:
fMAX =
N
=
togLC =
K
=
Maximum operating frequency in MHz
Total number of LEs used in a FLEX 6000 device
Average percentage of LEs toggling at each clock
(typically 12.5%)
Constant, shown in Table 39
Table 39. K Constant Values
Altera Corporation
Device
K Value
EPF6010A
14
EPF6016
88
EPF6016A
14
EPF6024A
14
47
FLEX 6000 Programmable Logic Device Family Data Sheet
This calculation provides an ICC estimate based on typical conditions with
no output load. The actual ICC should be verified during operation
because this measurement is sensitive to the actual pattern in the device
and the environmental operating conditions.
To better reflect actual designs, the power model (and the constant K in
the power calculation equations shown above) for continuous
interconnect FLEX devices assumes that LEs drive FastTrack Interconnect
channels. In contrast, the power model of segmented FPGAs assumes that
all LEs drive only one short interconnect segment. This assumption may
lead to inaccurate results, compared to measured power consumption for
an actual design in a segmented interconnect FPGA.
Figure 20 shows the relationship between the current and operating
frequency for EPF6010A, EPF6016, EPF6016A, and EPF6024A devices.
48
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Figure 20. ICCACTIVE vs. Operating Frequency
EPF6010A
EPF6016
1000
200
800
150
ICC Supply
Current
100
(mA)
ICC Supply
Current
(mA)
600
400
50
200
0
50
0
100
Frequency (MHz)
30
60
Frequency (MHz)
EPF6016A
EPF6024A
250
400
200
300
ICC Supply 150
Current
(mA)
ICC Supply
Current
(mA)
100
200
100
50
0
50
Frequency (MHz)
Device
Configuration &
Operation
f
Altera Corporation
100
0
50
100
Frequency (MHz)
The FLEX 6000 architecture supports several configuration schemes to
load a design into the device(s) on the circuit board. This section
summarizes the device operating modes and available device
configuration schemes.
See Application Note 116 (Configuring APEX 20K, FLEX 10K & FLEX 6000
Devices) for detailed information on configuring FLEX 6000 devices,
including sample schematics, timing diagrams, configuration options,
pins names, and timing parameters.
49
FLEX 6000 Programmable Logic Device Family Data Sheet
Operating Modes
The FLEX 6000 architecture uses SRAM configuration elements that
require configuration data to be loaded every time the circuit powers
up. This process of physically loading the SRAM data into a FLEX
6000 device is known as configuration. During initialization—a
process that occurs immediately after configuration—the device
resets registers, enables I/O pins, and begins to operate as a logic
device. The I/O pins are tri-stated during power-up, and before and
during configuration. The configuration and initialization processes
of a device are referred to as command mode; normal device operation
is called user mode.
SRAM configuration elements allow FLEX 6000 devices to be
reconfigured in-circuit by loading new configuration data into the
device. Real-time reconfiguration is performed by forcing the device
into command mode with a device pin, loading different
configuration data, reinitializing the device, and resuming usermode operation. The entire reconfiguration process requires less
than 100 ms and is used to dynamically reconfigure an entire system.
Also, in-field system upgrades can be performed by distributing new
configuration files.
Configuration Schemes
The configuration data for a FLEX 6000 device can be loaded with
one of three configuration schemes, which is chosen on the basis of
the target application. An EPC1 or EPC1441 configuration device or
intelligent controller can be used to control the configuration of a
FLEX 6000 device, allowing automatic configuration on system
power-up.
Multiple FLEX 6000 devices can be configured in any of the three
configuration schemes by connecting the configuration enable input
(nCE) and configuration enable output (nCEO) pins on each device.
Table 40 shows the data sources for each configuration scheme.
Table 40. Configuration Schemes
Configuration Scheme
Data Source
Configuration device
EPC1 or EPC1441 configuration device
Passive serial (PS)
BitBlasterTM, ByteBlasterMVTM, or MasterBlasterTM
download cables, or serial data source
Passive serial asynchronous BitBlaster, ByteBlasterMV, or MasterBlaster
(PSA)
download cables, or serial data source
50
Altera Corporation
FLEX 6000 Programmable Logic Device Family Data Sheet
Device PinOuts
Altera Corporation
See the Altera web site (http://www.altera.com) or the Altera Digital
Library for pin-out information.
51
FLEX 6000 Programmable Logic Device Family Data Sheet
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52
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Intel:
EPF6016ATI144-3N EPF6016AFC256-1 EPF6016ATI100-2 EPF6016TI144-3 EPF6010ATC100-3N
EPF6024AQC240-3N EPF6024AQC208-1N EPF6016ATC100-2 EPF6016QC240-3 EPF6016ATC100-3N
EPF6016AFC100-1 EPF6016QC208-3N EPF6024AFC256-2 EPF6016QC208-2 EPF6016AQC208-3
EPF6024AQC240-2 EPF6016TC144-3 EPF6016TC144-2 EPF6010ATC100-3 EPF6010ATC100-2 EPF6016ATC1443N EPF6024AQC208-1 EPF6016QC208-3 EPF6016AFC100-3 EPF6024ABC256-2 EPF6024AQC240-1N
EPF6016ATC100-1 EPF6016AQC208-1 EPF6024AFC256-1 EPF6010ATI100-2N EPF6010ATC100-1N
EPF6016BC256-3N EPF6016AQC208-2N EPF6024AQC240-1 EPF6024AQC208-3 EPF6010ATC144-2
EPF6016ATC144-3 EPF6016ATC100-3 EPF6016QC240-2N EPF6016BC256-3 EPF6024ATC144-1N
EPF6024ATC144-2N EPF6024AQC208-3N EPF6024ABC256-1 EPF6016ATI144-3 EPF6016QC240-3N
EPF6016BC256-2 EPF6016ATC100-2N EPF6016QC240-2 EPF6016ATC144-1N EPF6016TC144-2N
EPF6016TI144-2 EPF6024AQC240-2N EPF6016AFC256-2 EPF6010ATC100-1 EPF6016QC208-2N
EPF6016AQC208-2 EPF6024AQC208-2 EPF6010ATC144-3N EPF6016TI144-3N EPF6016ATC144-1
EPF6010ATC100-2N EPF6024AQC240-3 EPF6016QI208-3N EPF6024ATC144-2 EPF6024ATC144-3
EPF6024ABC256-3 EPF6010ATI100-2 EPF6024ATC144-3N EPF6016QI208-3 EPF6024AQC208-2N
EPF6016AFC256-3 EPF6016AQC208-1N EPF6024ATC144-1 EPF6016TC144-3N EPF6016ATC144-2N
EPF6010ATC144-3 EPF6016ATC144-2 EPF6016AQC208-3N EPF6016TI144-2N EPF6024ABC256-2N
EPF6024AFC256-3 EPF6016ATI100-2N EPF6010ATC144-1 EPF6016AFC100-2