EPM3064ATI44-10N - Altera Corporation

Altera Corporation 1

MAX 3000A

Programmable Logic

Device Family

June 2006, ver. 3.5 Data Sheet

DS-MAX3000A-3.5

Features... ■High–performance, low–cost CMOS EEPROM–based programmable

logic devices (PLDs) built on a MAX® architecture (see Table 1)

■3.3-V in-system programmability (ISP) through the built–in

IEEE Std. 1149.1 Joint Test Action Group (JTAG) interface with

advanced pin-locking capability

– ISP circuitry compliant with IEEE Std. 1532

■Built–in boundary-scan test (BST) circuitry compliant with

IEEE Std. 1149.1-1990

■Enhanced ISP features:

– Enhanced ISP algorithm for faster programming

– ISP_Done bit to ensure complete programming

– Pull-up resistor on I/O pins during in–system programming

■High–density PLDs ranging from 600 to 10,000 usable gates

■4.5–ns pin–to–pin logic delays with counter frequencies of up to

227.3 MHz

■MultiVoltTM I/O interface enabling the device core to run at 3.3 V,

while I/O pins are compatible with 5.0–V, 3.3–V, and 2.5–V logic

levels

■Pin counts ranging from 44 to 256 in a variety of thin quad flat pack

(TQFP), plastic quad flat pack (PQFP), plastic J–lead chip carrier

(PLCC), and FineLine BGATM packages

■Hot–socketing support

■Programmable interconnect array (PIA) continuous routing structure

for fast, predictable performance

■Industrial temperature range

Table 1. MAX 3000A Device Features

Feature EPM3032A EPM3064A EPM3128A EPM3256A EPM3512A

Usable gates 600 1,250 2,500 5,000 10,000

Macrocells 32 64 128 256 512

Logic array blocks 2 4 8 16 32

Maximum user I/O

pins

34 66 98 161 208

tPD (ns) 4.5 4.5 5.0 7.5 7.5

tSU (ns) 2.9 2.8 3.3 5.2 5.6

tCO1 (ns) 3.0 3.1 3.4 4.8 4.7

fCNT (MHz) 227.3 222.2 192.3 126.6 116.3

2Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

...and More

Features

■PCI compatible

■Bus–friendly architecture including programmable slew–rate control

■Open–drain output option

■Programmable macrocell flipflops with individual clear, preset,

clock, and clock enable controls

■Programmable power–saving mode for a power reduction of over

50% in each macrocell

■Configurable expander product–term distribution, allowing up to

32 product terms per macrocell

■Programmable security bit for protection of proprietary designs

■Enhanced architectural features, including:

– 6 or 10 pin– or logic–driven output enable signals

– Two global clock signals with optional inversion

– Enhanced interconnect resources for improved routability

– Programmable output slew–rate control

■Software design support and automatic place–and–route provided

by Altera’s development systems for Windows–based PCs and Sun

SPARCstations, and HP 9000 Series 700/800 workstations

■Additional design entry and simulation support provided by EDIF

2 0 0 and 3 0 0 netlist files, library of parameterized modules (LPM),

Verilog HDL, VHDL, and other interfaces to popular EDA tools from

third–party manufacturers such as Cadence, Exemplar Logic, Mentor

Graphics, OrCAD, Synopsys, Synplicity, and VeriBest

■Programming support with the Altera master programming unit

(MPU), MasterBlasterTM communications cable, ByteBlasterMVTM

parallel port download cable, BitBlasterTM serial download cable as

well as programming hardware from third–party manufacturers and

any in–circuit tester that supports JamTM Standard Test and

Programming Language (STAPL) Files (.jam), Jam STAPL Byte-Code

Files (.jbc), or Serial Vector Format Files (.svf)

General

Description

MAX 3000A devices are low–cost, high–performance devices based on the

Altera MAX architecture. Fabricated with advanced CMOS technology,

the EEPROM–based MAX 3000A devices operate with a 3.3-V supply

voltage and provide 600 to 10,000 usable gates, ISP, pin-to-pin delays as

fast as 4.5 ns, and counter speeds of up to 227.3 MHz. MAX 3000A devices

in the –4, –5, –6, –7, and –10 speed grades are compatible with the timing

requirements of the PCI Special Interest Group (PCI SIG) PCI Local Bus

Specification, Revision 2.2. See Table 2.

Altera Corporation 3

MAX 3000A Programmable Logic Device Family Data Sheet

The MAX 3000A architecture supports 100% transistor-to-transistor logic

(TTL) emulation and high–density small-scale integration (SSI),

medium-scale integration (MSI), and large-scale integration (LSI) logic

functions. The MAX 3000A architecture easily integrates multiple devices

ranging from PALs, GALs, and 22V10s to MACH and pLSI devices.

MAX 3000A devices are available in a wide range of packages, including

PLCC, PQFP, and TQFP packages. See Table 3.

Note:

(1) When the IEEE Std. 1149.1 (JTAG) interface is used for in–system programming or

boundary–scan testing, four I/O pins become JTAG pins.

MAX 3000A devices use CMOS EEPROM cells to implement logic

functions. The user–configurable MAX 3000A architecture accommodates

a variety of independent combinatorial and sequential logic functions.

The devices can be reprogrammed for quick and efficient iterations

during design development and debugging cycles, and can be

programmed and erased up to 100 times.

Table 2. MAX 3000A Speed Grades

Device Speed Grade

–4 –5 –6 –7 –10

EPM3032A vvv

EPM3064A vvv

EPM3128A vvv

EPM3256A vv

EPM3512A vv

Table 3. MAX 3000A Maximum User I/O Pins Note (1)

Device 44–Pin

PLCC

44–Pin

TQFP

100–Pin

TQFP

144–Pin

TQFP

208–Pin

PQFP

256-Pin

FineLine

BGA

EPM3032A 34 34

EPM3064A 34 34 66

EPM3128A 80 96 98

EPM3256A 116 158 161

EPM3512A 172 208

4Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

MAX 3000A devices contain 32 to 512 macrocells, combined into groups

of 16 macrocells called logic array blocks (LABs). Each macrocell has a

programmable–AND/fixed–OR array and a configurable register with

independently programmable clock, clock enable, clear, and preset

functions. To build complex logic functions, each macrocell can be

supplemented with shareable expander and high–speed parallel

expander product terms to provide up to 32 product terms per macrocell.

MAX 3000A devices provide programmable speed/power optimization.

Speed–critical portions of a design can run at high speed/full power,

while the remaining portions run at reduced speed/low power. This

speed/power optimization feature enables the designer to configure one

or more macrocells to operate at 50% or lower power while adding only a

nominal timing delay. MAX 3000A devices also provide an option that

reduces the slew rate of the output buffers, minimizing noise transients

when non–speed–critical signals are switching. The output drivers of all

MAX 3000A devices can be set for 2.5 V or 3.3 V, and all input pins are

2.5–V, 3.3–V, and 5.0-V tolerant, allowing MAX 3000A devices to be used

in mixed–voltage systems.

MAX 3000A devices are supported by Altera development systems,

which are integrated packages that offer schematic, text—including

VHDL, Verilog HDL, and the Altera Hardware Description Language

(AHDL)—and waveform design entry, compilation and logic synthesis,

simulation and timing analysis, and device programming. The 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

software runs on Windows–based PCs, as well as Sun SPARCstation, and

HP 9000 Series 700/800 workstations.

fFor more information on development tools, see the MAX+PLUS II

Programmable Logic Development System & Software Data Sheet and the

Quartus Programmable Logic Development System & Software Data Sheet.

Functional

Description

The MAX 3000A architecture includes the following elements:

■Logic array blocks (LABs)

■Macrocells

■Expander product terms (shareable and parallel)

■Programmable interconnect array (PIA)

■I/O control blocks

The MAX 3000A architecture includes four dedicated inputs that can be

used as general–purpose inputs or as high–speed, global control signals

(clock, clear, and two output enable signals) for each macrocell and I/O

pin. Figure 1 shows the architecture of MAX 3000A devices.

Altera Corporation 5

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 1. MAX 3000A Device Block Diagram

Note:

(1) EPM3032A, EPM3064A, EPM3128A, and EPM3256A devices have six output enables. EPM3512A devices have

10 output enables.

Logic Array Blocks

The MAX 3000A device architecture is based on the linking of

high–performance LABs. LABs consist of 16–macrocell arrays, as shown

in Figure 1. Multiple LABs are linked together via the PIA, a global bus

that is fed by all dedicated input pins, I/O pins, and macrocells.

Each LAB is fed by the following signals:

■36 signals from the PIA that are used for general logic inputs

■Global controls that are used for secondary register functions

6 or 10

INPUT/GCLRn

6 or 10 Output Enables

(1)

6 or 10 Output Enables

(1)

36 36

I/O

Control

Block

LAB C LAB D

I/O

Control

Block

6 or 10

36 36

I/O

Control

Block

LAB A

Macrocells

1 to 16

LAB B

I/O

Control

Block

6 or 10

PIA

INPUT/GCLK1

INPUT/OE2/GCLK2

INPUT/OE1

2 to 16 I/O

2 to

2 to 16

Macrocells

17 to 32

Macrocells

33 to 48

Macrocells

49 to 64

6Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Macrocells

MAX 3000A macrocells can be individually configured for either

sequential or combinatorial logic operation. Macrocells consist of three

functional blocks: logic array, product–term select matrix, and

programmable register. Figure 2 shows a MAX 3000A macrocell.

Figure 2. MAX 3000A Macrocell

Combinatorial logic is implemented in the logic array, which provides

five product terms per macrocell. The product–term select matrix

allocates these product terms for use as either primary logic inputs (to the

OR and XOR gates) to implement combinatorial functions, or as secondary

inputs to the macrocell’s register preset, clock, and clock enable control

functions.

Two kinds of expander product terms (“expanders”) are available to

supplement macrocell logic resources:

■Shareable expanders, which are inverted product terms that are fed

back into the logic array

■Parallel expanders, which are product terms borrowed from adjacent

macrocells

The Altera development system automatically optimizes product–term

allocation according to the logic requirements of the design.

uct

elect

tri

36 Si

nal

m PI

16 Ex

ander

Product Term

LAB Local Arra

arallel Lo

ander

(

from other

macrocells

)

Shared Lo

ander

Clear

Select

Global

Clear

Global

Clocks

Clock/

Enable

Select

PRN

ENA

ister

pas

To I/

ontrol

Pro

rammable

iste

VCC

D/T

Altera Corporation 7

MAX 3000A Programmable Logic Device Family Data Sheet

For registered functions, each macrocell flipflop can be individually

programmed to implement D, T, JK, or SR operation with programmable

clock control. The flipflop can be bypassed for combinatorial operation.

During design entry, the designer specifies the desired flipflop type; the

Altera development system software then selects the most efficient

flipflop operation for each registered function to optimize resource

utilization.

Each programmable register can be clocked in three different modes:

■Global clock signal mode, which achieves the fastest clock–to–output

performance.

■Global clock signal enabled by an active–high clock enable. A clock

enable is generated by a product term. This mode provides an enable

on each flipflop while still achieving the fast clock–to–output

performance of the global clock.

■Array clock implemented with a product term. In this mode, the

flipflop can be clocked by signals from buried macrocells or I/O pins.

Two global clock signals are available in MAX 3000A devices. As shown

in Figure 1, these global clock signals can be the true or the complement of

either of the two global clock pins, GCLK1 or GCLK2.

Each register also supports asynchronous preset and clear functions. As

shown in Figure 2, the product–term select matrix allocates product terms

to control these operations. Although the product–term–driven preset

and clear from the register are active high, active–low control can be

obtained by inverting the signal within the logic array. In addition, each

dedicated global clear pin (GCLRn).

All registers are cleared upon power-up. By default, all registered outputs

drive low when the device is powered up. You can set the registered

outputs to drive high upon power-up through the Quartus®II software.

Quartus II software uses the NOT Gate Push-Back method, which uses an

additional macrocell to set the output high. To set this in the Quartus II

software, go to the Assignment Editor and set the Power-Up Level

assignment for the register to High.

8Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Expander Product Terms

Although most logic functions can be implemented with the five product

terms available in each macrocell, highly complex logic functions require

additional product terms. Another macrocell can be used to supply the

required logic resources. However, the MAX 3000A architecture also

offers both shareable and parallel expander product terms (“expanders”)

that provide additional product terms directly to any macrocell in the

same LAB. These expanders help ensure that logic is synthesized with the

fewest possible logic resources to obtain the fastest possible speed.

Shareable Expanders

Each LAB has 16 shareable expanders that can be viewed as a pool of

uncommitted single product terms (one from each macrocell) with

inverted outputs that feed back into the logic array. Each shareable

expander can be used and shared by any or all macrocells in the LAB to

build complex logic functions. Shareable expanders incur a small delay

(tSEXP). Figure 3 shows how shareable expanders can feed multiple

macrocells.

Figure 3. MAX 3000A Shareable Expanders

Shareable expanders can be shared by any or all macrocells in an LAB.

Macrocell

Product-Ter

Logic

oduc

erm Select Matrix

Macrocell

Product-Ter

Logic

36 Si

nals

m PI

hare

Expander

Altera Corporation 9

MAX 3000A Programmable Logic Device Family Data Sheet

Parallel Expanders

Parallel expanders are unused product terms that can be allocated to a

neighboring macrocell to implement fast, complex logic functions.

Parallel expanders allow up to 20 product terms to directly feed the

macrocell OR logic, with five product terms provided by the macrocell and

15 parallel expanders provided by neighboring macrocells in the LAB.

The Altera development system compiler can automatically allocate up to

three sets of up to five parallel expanders to the macrocells that require

additional product terms. Each set of five parallel expanders incurs a

small, incremental timing delay (tPEXP). For example, if a macrocell

requires 14 product terms, the compiler uses the five dedicated product

terms within the macrocell and allocates two sets of parallel expanders;

the first set includes five product terms, and the second set includes four

product terms, increasing the total delay by 2 × tPEXP.

Two groups of eight macrocells within each LAB (e.g., macrocells 1

through 8 and 9 through 16) form two chains to lend or borrow parallel

expanders. A macrocell borrows parallel expanders from lower–

numbered macrocells. For example, macrocell 8 can borrow parallel

expanders from macrocell 7, from macrocells 7 and 6, or from macrocells

7, 6, and 5. Within each group of eight, the lowest–numbered macrocell

can only lend parallel expanders and the highest–numbered macrocell can

only borrow them. Figure 4 shows how parallel expanders can be

borrowed from a neighboring macrocell.

10 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 4. MAX 3000A Parallel Expanders

Unused product terms in a macrocell can be allocated to a neighboring macrocell.

Programmable Interconnect Array

Logic is routed between LABs on the PIA. This global bus is a

programmable path that connects any signal source to any destination on

the device. All MAX 3000A dedicated inputs, I/O pins, and macrocell

outputs feed the PIA, which makes the signals available throughout the

entire device. Only the signals required by each LAB are actually routed

from the PIA into the LAB. Figure 5 shows how the PIA signals are routed

into the LAB. An EEPROM cell controls one input to a two-input AND gate,

which selects a PIA signal to drive into the LAB.

Preset

Clock

Clear

uct

elec

tri

Preset

Clock

Clear

uct

elec

tri

Macrocell

Product-

Term Logic

From

To Next

Macrocell

Product-

Term Logic

36 Signals

from PIA

16 Shared

Expanders

Altera Corporation 11

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 5. MAX 3000A PIA Routing

While the routing delays of channel–based routing schemes in masked or

FPGAs are cumulative, variable, and path–dependent, the MAX 3000A

PIA has a predictable delay. The PIA makes a design’s timing

performance easy to predict.

I/O Control Blocks

The I/O control block allows each I/O pin to be individually configured

for input, output, or bidirectional operation. All I/O pins have a tri–state

buffer that is individually controlled by one of the global output enable

signals or directly connected to ground or VCC. Figure 6 shows the I/O

control block for MAX 3000A devices. The I/O control block has 6 or

10 global output enable signals that are driven by the true or complement

of two output enable signals, a subset of the I/O pins, or a subset of the

I/O macrocells.

To LAB

PIA Signals

12 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 6. I/O Control Block of MAX 3000A Devices

Note:

(1) EPM3032A, EPM3064A, EPM3128A, and EPM3256A devices have six output enables. EPM3512A devices have

10 output enables.

When the tri–state buffer control is connected to ground, the output is

tri-stated (high impedance), and the I/O pin can be used as a dedicated

input. When the tri–state buffer control is connected to VCC, the output is

enabled.

The MAX 3000A architecture provides dual I/O feedback, in which

macrocell and pin feedbacks are independent. When an I/O pin is

configured as an input, the associated macrocell can be used for buried

logic.

from

Macrocell

Slew-Rate Control

to PIA

to Other I/O Pins

6 or 10 Global

Output Enable Signals (1)

PIA

VCC

Open-Drain Output

OE Select Multiplexer

GND

Altera Corporation 13

MAX 3000A Programmable Logic Device Family Data Sheet

In–System

Programma-

bility

MAX 3000A devices can be programmed in–system via an industry–

standard four–pin IEEE Std. 1149.1-1990 (JTAG) interface. In-system

programmability (ISP) offers quick, efficient iterations during design

development and debugging cycles. The MAX 3000A architecture

internally generates the high programming voltages required to program

its EEPROM cells, allowing in–system programming with only a single

3.3–V power supply. During in–system programming, the I/O pins are

tri–stated and weakly pulled–up to eliminate board conflicts. The pull–up

value is nominally 50 kΩ.

MAX 3000A devices have an enhanced ISP algorithm for faster

programming. These devices also offer an ISP_Done bit that ensures safe

operation when in–system programming is interrupted. This ISP_Done

bit, which is the last bit programmed, prevents all I/O pins from driving

until the bit is programmed.

ISP simplifies the manufacturing flow by allowing devices to be mounted

on a printed circuit board (PCB) with standard pick–and–place equipment

before they are programmed. MAX 3000A devices can be programmed by

downloading the information via in–circuit testers, embedded processors,

the MasterBlaster communications cable, the ByteBlasterMV parallel port

download cable, and the BitBlaster serial download cable. Programming

the devices after they are placed on the board eliminates lead damage on

high–pin–count packages (e.g., QFP packages) due to device handling.

MAX 3000A devices can be reprogrammed after a system has already

shipped to the field. For example, product upgrades can be performed in

the field via software or modem.

The Jam STAPL programming and test language can be used to program

MAX 3000A devices with in–circuit testers, PCs, or embedded processors.

fFor more information on using the Jam STAPL programming and test

language, see Application Note 88 (Using the Jam Language for ISP & ICR via

an Embedded Processor), Application Note 122 (Using Jam STAPL for ISP &

ICR via an Embedded Processor) and AN 111 (Embedded Programming Using

the 8051 and Jam Byte-Code).

The ISP circuitry in MAX 3000A devices is compliant with the IEEE Std.

1532 specification. The IEEE Std. 1532 is a standard developed to allow

concurrent ISP between multiple PLD vendors.

14 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Programming Sequence

During in-system programming, instructions, addresses, and data are

shifted into the MAX 3000A device through the TDI input pin. Data is

shifted out through the TDO output pin and compared against the

expected data.

Programming a pattern into the device requires the following six ISP

stages. A stand-alone verification of a programmed pattern involves only

stages 1, 2, 5, and 6.

1. Enter ISP. The enter ISP stage ensures that the I/O pins transition

smoothly from user mode to ISP mode. The enter ISP stage requires

1ms.

2. Check ID. Before any program or verify process, the silicon ID is

checked. The time required to read this silicon ID is relatively small

compared to the overall programming time.

3. Bulk Erase. Erasing the device in-system involves shifting in the

instructions to erase the device and applying one erase pulse of

100 ms.

4. Program. Programming the device in-system involves shifting in the

address and data and then applying the programming pulse to

program the EEPROM cells. This process is repeated for each

EEPROM address.

5. Verify. Verifying an Altera device in-system involves shifting in

addresses, applying the read pulse to verify the EEPROM cells, and

shifting out the data for comparison. This process is repeated for

each EEPROM address.

6. Exit ISP. An exit ISP stage ensures that the I/O pins transition

smoothly from ISP mode to user mode. The exit ISP stage requires

1ms.

Programming Times

The time required to implement each of the six programming stages can

be broken into the following two elements:

■A pulse time to erase, program, or read the EEPROM cells.

■A shifting time based on the test clock (TCK) frequency and the

number of TCK cycles to shift instructions, address, and data into the

device.

Altera Corporation 15

MAX 3000A Programmable Logic Device Family Data Sheet

By combining the pulse and shift times for each of the programming

stages, the program or verify time can be derived as a function of the TCK

frequency, the number of devices, and specific target device(s). Because

different ISP-capable devices have a different number of EEPROM cells,

both the total fixed and total variable times are unique for a single device.

Programming a Single MAX 3000A Device

The time required to program a single MAX 3000A device in-system can

be calculated from the following formula:

where: tPROG = Programming time

tPPULSE = Sum of the fixed times to erase, program, and

verify the EEPROM cells

CyclePTCK = Number of TCK cycles to program a device

fTCK =TCK frequency

The ISP times for a stand-alone verification of a single MAX 3000A device

can be calculated from the following formula:

where: tVER =Verify time

tVPULSE = Sum of the fixed times to verify the EEPROM cells

CycleVTCK = Number of TCK cycles to verify a device

tPROG tPPULSE

CyclePTCK

fTCK

--------------------------------+=

tVER tVPULSE

CycleVTCK

fTCK

--------------------------------+=

16 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

The programming times described in Tables 4 through 6 are associated

with the worst-case method using the enhanced ISP algorithm.

Tables 5 and 6 show the in-system programming and stand alone

verification times for several common test clock frequencies.

Table 4. MAX 3000A tPULSE & CycleTCK Values

Device Programming Stand-Alone Verification

tPPULSE (s) CyclePTCK tVPULSE (s) CycleVTCK

EPM3032A 2.00 55,000 0.002 18,000

EPM3064A 2.00 105,000 0.002 35,000

EPM3128A 2.00 205,000 0.002 68,000

EPM3256A 2.00 447,000 0.002 149,000

EPM3512A 2.00 890,000 0.002 297,000

Table 5. MAX 3000A In-System Programming Times for Different Test Clock Frequencies

Device fTCK Units

10 MHz 5 MHz 2 MHz 1 MHz 500 kHz 200 kHz 100 kHz 50 kHz

EPM3032A 2.01 2.01 2.03 2.06 2.11 2.28 2.55 3.10 s

EPM3064A 2.01 2.02 2.05 2.11 2.21 2.53 3.05 4.10 s

EPM3128A 2.02 2.04 2.10 2.21 2.41 3.03 4.05 6.10 s

EPM3256A 2.05 2.09 2.23 2.45 2.90 4.24 6.47 10.94 s

EPM3512A 2.09 2.18 2.45 2.89 3.78 6.45 10.90 19.80 s

Table 6. MAX 3000A Stand-Alone Verification Times for Different Test Clock Frequencies

Device fTCK Units

10 MHz 5 MHz 2 MHz 1 MHz 500 kHz 200 kHz 100 kHz 50 kHz

EPM3032A 0.00 0.01 0.01 0.02 0.04 0.09 0.18 0.36 s

EPM3064A 0.01 0.01 0.02 0.04 0.07 0.18 0.35 0.70 s

EPM3128A 0.01 0.02 0.04 0.07 0.14 0.34 0.68 1.36 s

EPM3256A 0.02 0.03 0.08 0.15 0.30 0.75 1.49 2.98 s

EPM3512A 0.03 0.06 0.15 0.30 0.60 1.49 2.97 5.94 s

Altera Corporation 17

MAX 3000A Programmable Logic Device Family Data Sheet

Programming

with External

Hardware

MAX 3000A devices can be programmed on Windows–based PCs with an

Altera Logic Programmer card, MPU, and the appropriate device adapter.

The MPU performs continuity checking to ensure adequate electrical

contact between the adapter and the device.

fFor more information, see the Altera Programming Hardware Data Sheet.

The Altera software can use text– or waveform–format test vectors created

with the Altera Text Editor or Waveform Editor to test the programmed

device. For added design verification, designers can perform functional

testing to compare the functional device behavior with the results of

simulation.

Data I/O, BP Microsystems, and other programming hardware

manufacturers also provide programming support for Altera devices.

fFor more information, see Programming Hardware Manufacturers.

IEEE Std.

1149.1 (JTAG)

Boundary–Scan

Support

MAX 3000A devices include the JTAG BST circuitry defined by IEEE

Std. 1149.1–1990. Table 7 describes the JTAG instructions supported by

MAX 3000A devices. The pin-out tables found on the Altera web site

(http://www.altera.com) or the Altera Digital Library show the location of

the JTAG control pins for each device. If the JTAG interface is not

required, the JTAG pins are available as user I/O pins.

Table 7. MAX 3000A JTAG Instructions

JTAG Instruction Description

SAMPLE/PRELOAD Allows a snapshot of signals at the device pins to be captured and examined during

normal device operation, and permits an initial data pattern 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 results 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 a selected device to adjacent devices during normal

device operation

IDCODE Selects the IDCODE register and places it between the TDI and TDO pins, allowing the

IDCODE to be serially shifted out of TDO

USERCODE Selects the 32–bit USERCODE register and places it between the TDI and TDO pins,

allowing the USERCODE value to be shifted out of TDO

ISP Instructions These instructions are used when programming MAX 3000A devices via the JTAG ports

with the MasterBlaster, ByteBlasterMV, or BitBlaster cable, or when using a Jam STAPL

file, JBC file, or SVF file via an embedded processor or test equipment

18 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

The instruction register length of MAX 3000A devices is 10 bits. The

IDCODE and USERCODE register length is 32 bits. Tables 8 and 9 show

the boundary–scan register length and device IDCODE information for

MAX 3000A devices.

Notes:

(1) The most significant bit (MSB) is on the left.

(2) The least significant bit (LSB) for all JTAG IDCODEs is 1.

fSee Application Note 39 (IEEE 1149.1 (JTAG) Boundary–Scan Testing in Altera

Devices) for more information on JTAG BST.

Table 8. MAX 3000A Boundary–Scan Register Length

Device Boundary–Scan Register Length

EPM3032A 96

EPM3064A 192

EPM3128A 288

EPM3256A 480

EPM3512A 624

Table 9. 32–Bit MAX 3000A Device IDCODE Value Note (1)

Device IDCODE (32 bits)

Version

(4 Bits)

Part Number (16 Bits) Manufacturer’s

Identity (11 Bits)

1 (1 Bit)

(2)

EPM3032A 0001 0111 0000 0011 0010 00001101110 1

EPM3064A 0001 0111 0000 0110 0100 00001101110 1

EPM3128A 0001 0111 0001 0010 1000 00001101110 1

EPM3256A 0001 0111 0010 0101 0110 00001101110 1

EPM3512A 0001 0111 0101 0001 0010 00001101110 1

Altera Corporation 19

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 7 shows the timing information for the JTAG signals.

Figure 7. MAX 3000A JTAG Waveforms

Table 10 shows the JTAG timing parameters and values for MAX 3000A

devices.

Table 10. JTAG Timing Parameters & Values for MAX 3000A Devices

Symbol 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 ns

tJPCO JTAG port clock to output 25 ns

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 ns

tJSH Capture register hold time 45 ns

tJSCO Update register clock to output 25 ns

tJSZX Update register high impedance to valid output 25 ns

tJSXZ Update register valid output to high impedance 25 ns

TDO

TCK

tJPZX tJPCO

tJPH

tJPXZ

tJCP

tJPSU

t JCL

tJCH

TDI

TMS

Signal

to Be

Captured

Signal

to Be

Driven

tJSZX

tJSSU tJSH

tJSCO tJSXZ

20 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Programmable

Speed/Power

Control

MAX 3000A devices offer a power–saving mode that supports low-power

operation across user–defined signal paths or the entire device. This

feature allows total power dissipation to be reduced by 50% or more

because most logic applications require only a small fraction of all gates to

operate at maximum frequency.

The designer can program each individual macrocell in a MAX 3000A

device for either high–speed or low–power operation. As a result,

speed-critical paths in the design can run at high speed, while the

remaining paths can operate at reduced power. Macrocells that run at low

power incur a nominal timing delay adder (tLPA) for the tLAD, tLAC, tIC,

tACL, tEN, tCPPW and tSEXP parameters.

Output

Configuration

MAX 3000A device outputs can be programmed to meet a variety of

system–level requirements.

MultiVolt I/O Interface

The MAX 3000A device architecture supports the MultiVolt I/O interface

feature, which allows MAX 3000A devices to connect to systems with

differing supply voltages. MAX 3000A devices in all packages can be set

for 2.5–V, 3.3–V, or 5.0–V I/O pin operation. These devices have one set of

VCC pins for internal operation and input buffers (VCCINT), and another

set for I/O output drivers (VCCIO).

The VCCIO pins can be connected to either a 3.3–V or 2.5–V power supply,

depending on the output requirements. When the VCCIO pins are

connected to a 2.5–V power supply, the output levels are compatible with

2.5–V systems. When the VCCIO pins are connected to a 3.3–V power

supply, the output high is at 3.3 V and is therefore compatible with 3.3-V

or 5.0–V systems. Devices operating with VCCIO levels lower than 3.0 V

incur a nominally greater timing delay of tOD2 instead of tOD1. Inputs can

always be driven by 2.5–V, 3.3–V, or 5.0–V signals.

Table 11 summarizes the MAX 3000A MultiVolt I/O support.

Note:

(1) When VCCIO is 3.3 V, a MAX 3000A device can drive a 2.5–V device that has 3.3–V

tolerant inputs.

Table 11. MAX 3000A MultiVolt I/O Support

VCCIO Voltage Input Signal (V) Output Signal (V)

2.5 3.3 5.0 2.5 3.3 5.0

2.5 vvvv

3.3 vvvvvv

Altera Corporation 21

MAX 3000A Programmable Logic Device Family Data Sheet

Open–Drain Output Option

MAX 3000A devices provide an optional open–drain (equivalent to

open-collector) output for each I/O pin. This open–drain output enables

the device to provide system–level control signals (e.g., interrupt and

write enable signals) that can be asserted by any of several devices. It can

also provide an additional wired–OR plane.

Open-drain output pins on MAX 3000A devices (with a pull-up resistor to

the 5.0-V supply) can drive 5.0-V CMOS input pins that require a high VIH.

When the open-drain pin is active, it will drive low. When the pin is

inactive, the resistor will pull up the trace to 5.0 V, thereby meeting CMOS

requirements. 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

Slew–Rate Control

The output buffer for each MAX 3000A I/O pin has an adjustable output

slew rate that can be configured for low–noise or high–speed

performance. A faster slew rate provides high–speed transitions for

high-performance systems. However, these fast transitions may introduce

noise transients into the system. A slow slew rate reduces system noise,

but adds a nominal delay of 4 to 5 ns. When the configuration cell is

turned off, the slew rate is set for low–noise performance. Each I/O pin

has an individual EEPROM bit that controls the slew rate, allowing

designers to specify the slew rate on a pin–by–pin basis. The slew rate

control affects both the rising and falling edges of the output signal.

Design Security All MAX 3000A devices contain a programmable security bit that controls

access to the data programmed into the device. When this bit is

programmed, a design implemented in the device cannot be copied or

retrieved. This feature provides a high level of design security because

programmed data within EEPROM cells is invisible. The security bit that

controls this function, as well as all other programmed data, is reset only

when the device is reprogrammed.

Generic Testing MAX 3000A devices are fully tested. Complete testing of each

programmable EEPROM bit and all internal logic elements ensures 100%

programming yield. AC test measurements are taken under conditions

equivalent to those shown in Figure 8. Test patterns can be used and then

erased during early stages of the production flow.

22 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 8. MAX 3000A AC Test Conditions

Operating

Conditions

Tables 12 through 15 provide information on absolute maximum ratings,

recommended operating conditions, DC operating conditions, and

capacitance for MAX 3000A devices.

To Test

System

C1 (includes jig

capacitance)

Device input

rise and fall

times < 2 ns

Device

Output

703 Ω

620 Ω

[521 Ω]

[481 Ω]

Power supply transients can affect AC

measurements. Simultaneous transitions

of multiple outputs should be avoided for

accurate measurement. Threshold tests

must not be performed under AC

conditions. Large–amplitude, fast–

ground–current transients normally occur

as the device outputs discharge the load

capacitances. When these transients flow

through the parasitic inductance between

the device ground pin and the test system

ground, significant reductions in

observable noise immunity can result.

Numbers in brackets are for 2.5–V

outputs. Numbers without brackets are for

3.3–V devices or outputs.

Table 12. MAX 3000A Device Absolute Maximum Ratings Note (1)

Symbol Parameter Conditions Min Max Unit

VCC Supply voltage With respect to ground (2) –0.5 4.6 V

VIDC input voltage –2.0 5.75 V

IOUT DC output current, per pin –25 25 mA

TSTG Storage temperature No bias –65 150 ° C

TAAmbient temperature Under bias –65 135 ° C

TJJunction temperature PQFP and TQFP packages, under bias 135 ° C

Altera Corporation 23

MAX 3000A Programmable Logic Device Family Data Sheet

Table 13. MAX 3000A Device Recommended Operating Conditions

Symbol Parameter Conditions Min Max Unit

VCCINT Supply voltage for internal logic and

input buffers

(10) 3.0 3.6 V

VCCIO Supply voltage for output drivers,

3.3–V operation

3.0 3.6 V

Supply voltage for output drivers,

2.5–V operation

2.3 2.7 V

VCCISP Supply voltage during ISP 3.0 3.6 V

VIInput voltage (3) –0.5 5.75 V

VOOutput voltage 0 VCCIO V

TAAmbient temperature Commercial range 0 70 ° C

Industrial range –40 85 ° C

TJJunction temperature Commercial range 0 90 ° C

Industrial range (11) –40 105 ° C

tRInput rise time 40 ns

tFInput fall time 40 ns

Table 14. MAX 3000A Device DC Operating Conditions Note (4)

Symbol Parameter Conditions Min Max Unit

VIH High–level input voltage 1.7 5.75 V

VIL Low–level input voltage –0.5 0.8 V

VOH 3.3–V high–level TTL output

voltage

IOH = –8 mA DC, VCCIO = 3.00 V (5) 2.4 V

3.3–V high–level CMOS output

voltage

IOH = –0.1 mA DC, VCCIO = 3.00 V (5) VCCIO – 0.2 V

2.5–V high–level output voltage IOH = –100 µA DC, VCCIO = 2.30 V (5) 2.1 V

IOH = –1 mA DC, VCCIO = 2.30 V (5) 2.0 V

IOH = –2 mA DC, VCCIO = 2.30 V (5) 1.7 V

VOL 3.3–V low–level TTL output voltage IOL = 8 mA DC, VCCIO = 3.00 V (6) 0.4 V

3.3–V low–level CMOS output

voltage

IOL = 0.1 mA DC, VCCIO = 3.00 V (6) 0.2 V

2.5–V low–level output voltage IOL = 100 µA DC, VCCIO = 2.30 V (6) 0.2 V

IOL = 1 mA DC, VCCIO = 2.30 V (6) 0.4 V

IOL = 2 mA DC, VCCIO = 2.30 V (6) 0.7 V

IIInput leakage current VI = –0.5 to 5.5 V (7) –10 10 μA

IOZ Tri–state output off–state current VI = –0.5 to 5.5 V (7) –10 10 μA

RISP Value of I/O pin pull–up resistor

when programming in–system or

during power–up

VCCIO = 2.3 to 3.6 V (8) 20 74 kΩ

24 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Notes to tables:

(1) See the Operating Requirements for Altera Devices Data Sheet.

(2) 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.

(3) All pins, including dedicated inputs, I/O pins, and JTAG pins, may be driven before VCCINT and VCCIO are

powered.

(4) These values are specified under the recommended operating conditions, as shown in Table 13 on page 23.

(5) The parameter is measured with 50% of the outputs each sourcing the specified current. The IOH parameter refers

to high–level TTL or CMOS output current.

(6) The parameter is measured with 50% of the outputs each sinking the specified current. The IOL parameter refers to

low–level TTL, PCI, or CMOS output current.

(7) This value is specified during normal device operation. During power-up, the maximum leakage current is

±300 μA.

(8) This pull–up exists while devices are programmed in–system and in unprogrammed devices during power–up.

(9) Capacitance is measured at 25° C and is sample–tested only. The OE1 pin (high–voltage pin during programming)

has a maximum capacitance of 20 pF.

(10) The POR time for all MAX 3000A devices does not exceed 100 μs. The sufficient VCCINT voltage level for POR is

3.0 V. The device is fully initialized within the POR time after VCCINT reaches the sufficient POR voltage level.

(11) These devices support in-system programming for –40° to 100° C. For in-system programming support between –40°

and 0° C, contact Altera Applications.

Figure 9 shows the typical output drive characteristics of MAX 3000A

devices.

Table 15. MAX 3000A Device Capacitance Note (9)

Symbol Parameter Conditions Min Max Unit

CIN Input pin capacitance VIN = 0 V, f = 1.0 MHz 8 pF

CI/O I/O pin capacitance VOUT = 0 V, f = 1.0 MHz 8 pF

Altera Corporation 25

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 9. Output Drive Characteristics of MAX 3000A Devices

Power

Sequencing &

Hot–Socketing

Because MAX 3000A 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 MAX 3000A devices before and during

power-up without damaging the device. In addition, MAX 3000A devices

do not drive out during power-up. Once operating conditions are

reached, MAX 3000A devices operate as specified by the user.

VO Output Voltage (V)

1234

IOL

IOH

VCCINT = 3.3

= 25 C

VCCIO = 3.3 V

Temperature

100

150

Typical I

Output

Current (mA)

VO Output Voltage (V)

1234

VCCINT = 3.3 V

VCCIO = 2.5 V

IOH

2.5 V

3.3 V

Typical I

Output

Current (mA)

IOL

100

150

= 25 C

Temperature O

26 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Timing Model MAX 3000A device timing can be analyzed with the Altera software, with

a variety of popular industry–standard EDA simulators and timing

analyzers, or with the timing model shown in Figure 10. MAX 3000A

devices have predictable internal delays that enable the designer to

determine the worst–case timing of any design. The software provides

timing simulation, point–to–point delay prediction, and detailed timing

analysis for device–wide performance evaluation.

Figure 10. MAX 3000A Timing Model

The timing characteristics of any signal path can be derived from the

timing model and parameters of a particular device. External timing

parameters, which represent pin–to–pin timing delays, can be calculated

as the sum of internal parameters. Figure 11 shows the timing relationship

between internal and external delay parameters.

Logic Array

Delay

LAD

Output

Delay

OD3

OD2

OD1

ZX2

ZX3

Input

Delay

PRE

CLR

COMB

PIA

Delay

PIA

Shared

Expander Delay

SEXP

Control Delay

LAC

I/O

Delay

Global Control

Delay

GLOB

Internal Output

Enable Delay

IOE

Parallel

Expander Delay

PEXP

Altera Corporation 27

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 11. MAX 3000A Switching Waveforms

Combinatorial Mode

Input Pin

I/O Pin

PIA Delay

Shared Expander

Delay

Logic Array

Input

Parallel Expander

Delay

Logic Array

Output

Output Pin

LAC

, t

LAD

PIA

PEXP

SEXP

COMB

Global Clock Mode

Global

Clock Pin

Global Clock

at Register

Data or Enable

(Logic Array Output)

GLOB

Array Clock Mode

Input or I/O Pin

Clock into PIA

Clock into

Logic Array

Clock at

Data from

Logic Array

to Logic Array

to Pin

ACH

ACL

PIA

CLR

, t

PRE

PIA

tR & tF < 2 ns. Inputs are

driven at 3 V for a logic

high and 0 V for a logic

low. All timing

characteristics are

measured at 1.5 V.

28 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Tables 16 through 23 show EPM3032A, EPM3064A, EPM3128A,

EPM3256A, and EPM3512A timing information.

Table 16. EPM3032A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

–4 –7 –10

Min Max Min Max Min Max

tPD1 Input to non–

registered output

C1 = 35 pF

(2)

4.5 7.5 10 ns

tPD2 I/O input to non–

registered output

C1 = 35 pF

(2)

4.5 7.5 10 ns

tSU Global clock setup

time

(2) 2.9 4.7 6.3 ns

tHGlobal clock hold time (2) 0.0 0.0 0.0 ns

tCO1 Global clock to output

delay

C1 = 35 pF 1.0 3.0 1.0 5.0 1.0 6.7 ns

tCH Global clock high time 2.0 3.0 4.0 ns

tCL Global clock low time 2.0 3.0 4.0 ns

tASU Array clock setup time (2) 1.6 2.5 3.6 ns

tAH Array clock hold time (2) 0.3 0.5 0.5 ns

tACO1 Array clock to output

delay

C1 = 35 pF

(2)

1.0 4.3 1.0 7.2 1.0 9.4 ns

tACH Array clock high time 2.0 3.0 4.0 ns

tACL Array clock low time 2.0 3.0 4.0 ns

tCPPW Minimum pulse width

for clear and preset

(3) 2.0 3.0 4.0 ns

tCNT Minimum global clock

period

(2) 4.4 7.2 9.7 ns

fCNT Maximum internal

global clock frequency

(2), (4) 227.3 138.9 103.1 MHz

tACNT Minimum array clock

period

(2) 4.4 7.2 9.7 ns

fACNT Maximum internal

array clock frequency

(2), (4) 227.3 138.9 103.1 MHz

Altera Corporation 29

MAX 3000A Programmable Logic Device Family Data Sheet

Table 17. EPM3032A Internal Timing Parameters (Part 1 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–4 –7 –10

Min Max Min Max Min Max

tIN Input pad and buffer delay 0.7 1.2 1.5 ns

tIO I/O input pad and buffer

delay

0.7 1.2 1.5 ns

tSEXP Shared expander delay 1.9 3.1 4.0 ns

tPEXP Parallel expander delay 0.5 0.8 1.0 ns

tLAD Logic array delay 1.5 2.5 3.3 ns

tLAC Logic control array delay 0.6 1.0 1.2 ns

tIOE Internal output enable delay 0.0 0.0 0.0 ns

tOD1 Output buffer and pad

delay, slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 0.8 1.3 1.8 ns

tOD2 Output buffer and pad

delay, slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 1.3 1.8 2.3 ns

tOD3 Output buffer and pad

delay, slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 5.8 6.3 6.8 ns

tZX1 Output buffer enable delay,

slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 4.0 4.0 5.0 ns

tZX2 Output buffer enable delay,

slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 4.5 4.5 5.5 ns

tZX3 Output buffer enable delay,

slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 9.0 9.0 10.0 ns

tXZ Output buffer disable delay C1 = 5 pF 4.0 4.0 5.0 ns

tSU Register setup time 1.3 2.0 2.8 ns

tHRegister hold time 0.6 1.0 1.3 ns

tRD Register delay 0.7 1.2 1.5 ns

tCOMB Combinatorial delay 0.6 1.0 1.3 ns

tIC Array clock delay 1.2 2.0 2.5 ns

tEN Register enable time 0.6 1.0 1.2 ns

tGLOB Global control delay 0.8 1.3 1.9 ns

tPRE Register preset time 1.2 1.9 2.6 ns

tCLR Register clear time 1.2 1.9 2.6 ns

30 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

tPIA PIA delay (2) 0.9 1.5 2.1 ns

tLPA Low–power adder (5) 2.5 4.0 5.0 ns

Table 18. EPM3064A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

–4 –7 –10

Min Max Min Max Min Max

tPD1 Input to non–registered

output

C1 = 35 pF (2) 4.5 7.5 10.0 ns

tPD2 I/O input to non–registered

output

C1 = 35 pF (2) 4.5 7.5 10.0 ns

tSU Global clock setup time (2) 2.8 4.7 6.2 ns

tHGlobal clock hold time (2) 0.0 0.0 0.0 ns

tCO1 Global clock to output delay C1 = 35 pF 1.0 3.1 1.0 5.1 1.0 7.0 ns

tCH Global clock high time 2.0 3.0 4.0 ns

tCL Global clock low time 2.0 3.0 4.0 ns

tASU Array clock setup time (2) 1.6 2.6 3.6 ns

tAH Array clock hold time (2) 0.3 0.4 0.6 ns

tACO1 Array clock to output delay C1 = 35 pF (2) 1.04.31.07.21.09.6 ns

tACH Array clock high time 2.0 3.0 4.0 ns

tACL Array clock low time 2.0 3.0 4.0 ns

tCPPW Minimum pulse width for

clear and preset

(3) 2.0 3.0 4.0 ns

tCNT Minimum global clock

period

(2) 4.5 7.4 10.0 ns

fCNT Maximum internal global

clock frequency

(2), (4) 222.2 135.1 100.0 MHz

tACNT Minimum array clock period (2) 4.5 7.4 10.0 ns

fACNT Maximum internal array

clock frequency

(2), (4) 222.2 135.1 100.0 MHz

Table 17. EPM3032A Internal Timing Parameters (Part 2 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–4 –7 –10

Min Max Min Max Min Max

Altera Corporation 31

MAX 3000A Programmable Logic Device Family Data Sheet

Table 19. EPM3064A Internal Timing Parameters (Part 1 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–4 –7 –10

Min Max Min Max Min Max

tIN Input pad and buffer delay 0.6 1.1 1.4 ns

tIO I/O input pad and buffer

delay

0.6 1.1 1.4 ns

tSEXP Shared expander delay 1.8 3.0 3.9 ns

tPEXP Parallel expander delay 0.4 0.7 0.9 ns

tLAD Logic array delay 1.5 2.5 3.2 ns

tLAC Logic control array delay 0.6 1.0 1.2 ns

tIOE Internal output enable delay 0.0 0.0 0.0 ns

tOD1 Output buffer and pad

delay, slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 0.8 1.3 1.8 ns

tOD2 Output buffer and pad

delay, slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 1.3 1.8 2.3 ns

tOD3 Output buffer and pad

delay, slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 5.8 6.3 6.8 ns

tZX1 Output buffer enable delay,

slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 4.0 4.0 5.0 ns

tZX2 Output buffer enable delay,

slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 4.5 4.5 5.5 ns

tZX3 Output buffer enable delay,

slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 9.0 9.0 10.0 ns

tXZ Output buffer disable delay C1 = 5 pF 4.0 4.0 5.0 ns

tSU Register setup time 1.3 2.0 2.9 ns

tHRegister hold time 0.6 1.0 1.3 ns

tRD Register delay 0.7 1.2 1.6 ns

tCOMB Combinatorial delay 0.6 0.9 1.3 ns

tIC Array clock delay 1.2 1.9 2.5 ns

tEN Register enable time 0.6 1.0 1.2 ns

tGLOB Global control delay 1.0 1.5 2.2 ns

tPRE Register preset time 1.3 2.1 2.9 ns

32 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

tCLR Register clear time 1.3 2.1 2.9 ns

tPIA PIA delay (2) 1.0 1.7 2.3 ns

tLPA Low–power adder (5) 3.5 4.0 5.0 ns

Table 20. EPM3128A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

–5 –7 –10

Min Max Min Max Min Max

tPD1 Input to non–

registered output

C1 = 35 pF

(2)

5.0 7.5 10 ns

tPD2 I/O input to non–

registered output

C1 = 35 pF

(2)

5.0 7.5 10 ns

tSU Global clock setup

time

(2) 3.3 4.9 6.6 ns

tHGlobal clock hold time (2) 0.0 0.0 0.0 ns

tCO1 Global clock to output

delay

C1 = 35 pF 1.0 3.4 1.0 5.0 1.0 6.6 ns

tCH Global clock high time 2.0 3.0 4.0 ns

tCL Global clock low time 2.0 3.0 4.0 ns

tASU Array clock setup time (2) 1.8 2.8 3.8 ns

tAH Array clock hold time (2) 0.2 0.3 0.4 ns

tACO1 Array clock to output

delay

C1 = 35 pF

(2)

1.0 4.9 1.0 7.1 1.0 9.4 ns

tACH Array clock high time 2.0 3.0 4.0 ns

tACL Array clock low time 2.0 3.0 4.0 ns

tCPPW Minimum pulse width

for clear and preset

(3) 2.0 3.0 4.0 ns

tCNT Minimum global clock

period

(2) 5.2 7.7 10.2 ns

fCNT Maximum internal

global clock frequency

(2), (4) 192.3 129.9 98.0 MHz

tACNT Minimum array clock

period

(2) 5.2 7.7 10.2 ns

Table 19. EPM3064A Internal Timing Parameters (Part 2 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–4 –7 –10

Min Max Min Max Min Max

Altera Corporation 33

MAX 3000A Programmable Logic Device Family Data Sheet

fACNT Maximum internal

array clock frequency

(2), (4) 192.3 129.9 98.0 MHz

Table 21. EPM3128A Internal Timing Parameters (Part 1 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–5 –7 –10

Min Max Min Max Min Max

tIN Input pad and buffer delay 0.7 1.0 1.4 ns

tIO I/O input pad and buffer

delay

0.7 1.0 1.4 ns

tSEXP Shared expander delay 2.0 2.9 3.8 ns

tPEXP Parallel expander delay 0.4 0.7 0.9 ns

tLAD Logic array delay 1.6 2.4 3.1 ns

tLAC Logic control array delay 0.7 1.0 1.3 ns

tIOE Internal output enable delay 0.0 0.0 0.0 ns

tOD1 Output buffer and pad

delay, slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 0.8 1.2 1.6 ns

tOD2 Output buffer and pad

delay, slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 1.3 1.7 2.1 ns

tOD3 Output buffer and pad

delay, slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 5.8 6.2 6.6 ns

tZX1 Output buffer enable delay,

slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 4.0 4.0 5.0 ns

tZX2 Output buffer enable delay,

slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 4.5 4.5 5.5 ns

tZX3 Output buffer enable delay,

slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 9.0 9.0 10.0 ns

tXZ Output buffer disable delay C1 = 5 pF 4.0 4.0 5.0 ns

Table 20. EPM3128A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

–5 –7 –10

Min Max Min Max Min Max

34 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

tSU Register setup time 1.4 2.1 2.9 ns

tHRegister hold time 0.6 1.0 1.3 ns

tRD Register delay 0.8 1.2 1.6 ns

tCOMB Combinatorial delay 0.5 0.9 1.3 ns

tIC Array clock delay 1.2 1.7 2.2 ns

tEN Register enable time 0.7 1.0 1.3 ns

tGLOB Global control delay 1.1 1.6 2.0 ns

tPRE Register preset time 1.4 2.0 2.7 ns

tCLR Register clear time 1.4 2.0 2.7 ns

tPIA PIA delay (2) 1.4 2.0 2.6 ns

tLPA Low–power adder (5) 4.0 4.0 5.0 ns

Table 22. EPM3256A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

–7 –10

Min Max Min Max

tPD1 Input to non–registered

output

C1 = 35 pF (2) 7.5 10 ns

tPD2 I/O input to non–registered

output

C1 = 35 pF (2) 7.5 10 ns

tSU Global clock setup time (2) 5.2 6.9 ns

tHGlobal clock hold time (2) 0.0 0.0 ns

tCO1 Global clock to output

delay

C1 = 35 pF 1.0 4.8 1.0 6.4 ns

tCH Global clock high time 3.0 4.0 ns

tCL Global clock low time 3.0 4.0 ns

tASU Array clock setup time (2) 2.7 3.6 ns

tAH Array clock hold time (2) 0.3 0.5 ns

tACO1 Array clock to output delay C1 = 35 pF (2) 1.0 7.3 1.0 9.7 ns

tACH Array clock high time 3.0 4.0 ns

tACL Array clock low time 3.0 4.0 ns

tCPPW Minimum pulse width for

clear and preset

(3) 3.0 4.0 ns

Table 21. EPM3128A Internal Timing Parameters (Part 2 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–5 –7 –10

Min Max Min Max Min Max

Altera Corporation 35

MAX 3000A Programmable Logic Device Family Data Sheet

tCNT Minimum global clock

period

(2) 7.9 10.5 ns

fCNT Maximum internal global

clock frequency

(2), (4) 126.6 95.2 MHz

tACNT Minimum array clock

period

(2) 7.9 10.5 ns

fACNT Maximum internal array

clock frequency

(2), (4) 126.6 95.2 MHz

Table 23. EPM3256A Internal Timing Parameters (Part 1 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–7 –10

Min Max Min Max

tIN Input pad and buffer delay 0.9 1.2 ns

tIO I/O input pad and buffer delay 0.9 1.2 ns

tSEXP Shared expander delay 2.8 3.7 ns

tPEXP Parallel expander delay 0.5 0.6 ns

tLAD Logic array delay 2.2 2.8 ns

tLAC Logic control array delay 1.0 1.3 ns

tIOE Internal output enable delay 0.0 0.0 ns

tOD1 Output buffer and pad delay,

slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 1.2 1.6 ns

tOD2 Output buffer and pad delay,

slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 1.7 2.1 ns

tOD3 Output buffer and pad delay,

slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 6.2 6.6 ns

tZX1 Output buffer enable delay, slow

slew rate = off VCCIO = 3.3 V

C1 = 35 pF 4.0 5.0 ns

tZX2 Output buffer enable delay, slow

slew rate = off VCCIO = 2.5 V

C1 = 35 pF 4.5 5.5 ns

Table 22. EPM3256A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

–7 –10

Min Max Min Max

36 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

tZX3 Output buffer enable delay, slow

slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 9.0 10.0 ns

tXZ Output buffer disable delay C1 = 5 pF 4.0 5.0 ns

tSU Register setup time 2.1 2.9 ns

tHRegister hold time 0.9 1.2 ns

tRD Register delay 1.2 1.6 ns

tCOMB Combinatorial delay 0.8 1.2 ns

tIC Array clock delay 1.6 2.1 ns

tEN Register enable time 1.0 1.3 ns

tGLOB Global control delay 1.5 2.0 ns

tPRE Register preset time 2.3 3.0 ns

tCLR Register clear time 2.3 3.0 ns

tPIA PIA delay (2) 2.4 3.2 ns

tLPA Low–power adder (5) 4.0 5.0 ns

Table 24. EPM3512A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

-7 -10

Min Max Min Max

tPD1 Input to non-registered output C1 = 35 pF (2) 7.5 10.0 ns

tPD2 I/O input to non-registered

output

C1 = 35 pF (2) 7.5 10.0 ns

tSU Global clock setup time (2) 5.6 7.6 ns

tHGlobal clock hold time (2) 0.0 0.0 ns

tFSU Global clock setup time of fast

input

3.0 3.0 ns

tFH Global clock hold time of fast

input

0.0 0.0 ns

tCO1 Global clock to output delay C1 = 35 pF 1.0 4.7 1.0 6.3 ns

tCH Global clock high time 3.0 4.0 ns

tCL Global clock low time 3.0 4.0 ns

tASU Array clock setup time (2) 2.5 3.5 ns

Table 23. EPM3256A Internal Timing Parameters (Part 2 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

–7 –10

Min Max Min Max

Altera Corporation 37

MAX 3000A Programmable Logic Device Family Data Sheet

tAH Array clock hold time (2) 0.2 0.3 ns

tACO1 Array clock to output delay C1 = 35 pF (2) 1.0 7.8 1.0 10.4 ns

tACH Array clock high time 3.0 4.0 ns

tACL Array clock low time 3.0 4.0 ns

tCPPW Minimum pulse width for clear

and preset

(3) 3.0 4.0 ns

tCNT Minimum global clock period (2) 8.6 11.5 ns

fCNT Maximum internal global clock

frequency

(2), (4) 116.3 87.0 MHz

tACNT Minimum array clock period (2) 8.6 11.5 ns

fACNT Maximum internal array clock

frequency

(2), (4) 116.3 87.0 MHz

Table 25. EPM3512A Internal Timing Parameters (Part 1 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

-7 -10

Min Max Min Max

tIN Input pad and buffer delay 0.7 0.9 ns

tIO I/O input pad and buffer delay 0.7 0.9 ns

tFIN Fast input delay 3.1 3.6 ns

tSEXP Shared expander delay 2.7 3.5 ns

tPEXP Parallel expander delay 0.4 0.5 ns

tLAD Logic array delay 2.2 2.8 ns

tLAC Logic control array delay 1.0 1.3 ns

tIOE Internal output enable delay 0.0 0.0 ns

tOD1 Output buffer and pad delay,

slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 1.0 1.5 ns

tOD2 Output buffer and pad delay,

slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 1.5 2.0 ns

Table 24. EPM3512A External Timing Parameters Note (1)

Symbol Parameter Conditions Speed Grade Unit

-7 -10

Min Max Min Max

38 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Notes to tables:

(1) These values are specified under the recommended operating conditions, as shown in Table 13 on page 23. See

Figure 11 on page 27 for more information on switching waveforms.

(2) These values are specified for a PIA fan–out of one LAB (16 macrocells). For each additional LAB fan–out in these

devices, add an additional 0.1 ns to the PIA timing value.

(3) This minimum pulse width for preset and clear applies for both global clear and array controls. The tLPA parameter

must be added to this minimum width if the clear or reset signal incorporates the tLAD parameter into the signal

path.

(4) These parameters are measured with a 16–bit loadable, enabled, up/down counter programmed into each LAB.

(5) The tLPA parameter must be added to the tLAD, tLAC, tIC, tEN, tSEXP, tACL, and tCPPW parameters for macrocells

running in low–power mode.

tOD3 Output buffer and pad delay,

slow slew rate = on

VCCIO = 2.5 V or 3.3 V

C1 = 35 pF 6.0 6.5 ns

tZX1 Output buffer enable delay,

slow slew rate = off

VCCIO = 3.3 V

C1 = 35 pF 4.0 5.0 ns

tZX2 Output buffer enable delay,

slow slew rate = off

VCCIO = 2.5 V

C1 = 35 pF 4.5 5.5 ns

tZX3 Output buffer enable delay,

slow slew rate = on

VCCIO = 3.3 V

C1 = 35 pF 9.0 10.0 ns

tXZ Output buffer disable delay C1 = 5 pF 4.0 5.0 ns

tSU Register setup time 2.1 3.0 ns

tHRegister hold time 0.6 0.8 ns

tFSU Register setup time of fast input 1.6 1.6 ns

tFH Register hold time of fast input 1.4 1.4 ns

tRD Register delay 1.3 1.7 ns

tCOMB Combinatorial delay 0.6 0.8 ns

tIC Array clock delay 1.8 2.3 ns

tEN Register enable time 1.0 1.3 ns

tGLOB Global control delay 1.7 2.2 ns

tPRE Register preset time 1.0 1.4 ns

tCLR Register clear time 1.0 1.4 ns

tPIA PIA delay (2) 3.0 4.0 ns

tLPA Low-power adder (5) 4.5 5.0 ns

Table 25. EPM3512A Internal Timing Parameters (Part 2 of 2) Note (1)

Symbol Parameter Conditions Speed Grade Unit

-7 -10

Min Max Min Max

Altera Corporation 39

MAX 3000A Programmable Logic Device Family Data Sheet

Power

Consumption

Supply power (P) versus frequency (fMAX, in MHz) for MAX 3000A

devices is calculated with the following equation:

P = PINT + PIO = ICCINT × VCC + PIO

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 ICCINT value depends on the switching frequency and the application

logic. The ICCINT value is calculated with the following equation:

ICCINT =

(A × MCTON) + [B × (MCDEV – MCTON)] + (C × MCUSED × fMAX × togLC)

The parameters in the ICCINT equation are:

MCTON = Number of macrocells with the Turbo BitTM option turned

on, as reported in the Quartus II or MAX+PLUS II Report

File (.rpt)

MCDEV = Number of macrocells in the device

MCUSED = Total number of macrocells in the design, as reported in

the RPT File

fMAX = Highest clock frequency to the device

togLC = Average percentage of logic cells toggling at each clock

(typically 12.5%)

A, B, C = Constants (shown in Table 26)

The ICCINT calculation provides an ICC estimate based on typical

conditions using a pattern of a 16–bit, loadable, enabled, up/down

counter in each LAB with no output load. Actual ICC should be verified

during operation because this measurement is sensitive to the actual

pattern in the device and the environmental operating conditions.

Figures 12 and 13 show the typical supply current versus frequency for

MAX 3000A devices.

Table 26. MAX 3000A ICC Equation Constants

Device ABC

EPM3032A 0.71 0.30 0.014

EPM3064A 0.71 0.30 0.014

EPM3128A 0.71 0.30 0.014

EPM3256A 0.71 0.30 0.014

EPM3512A 0.71 0.30 0.014

40 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 12. ICC vs. Frequency for MAX 3000A Devices

= 3.3 V

Room Temperature

Frequency (MHz)

High Speed

Low Power

50 100

200

192.3 MHz

108.7 MHz

250

EPM3128A

EPM3032A

= 3.3 V

Room Temperature

Frequency (MHz)

= 3.3 V

Room Temperature

Frequency (MHz)

High Speed

Low Power

50 100

200

222.2 MHz

125.0 MHz

250

50 100

200 250

EPM3064A

High Speed

Low Power

227.3 MHz

144.9 MHz

Typical I

Active (mA)

CC Typical I

Active (mA)

Typical I

Active (mA)

120

140

160

100

Altera Corporation 41

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 13. ICC vs. Frequency for MAX 3000A Devices

EPM3256A

VCC = 3.3 V

Room Temperature

Frequency (MHz)

Low Power

172.4 MHz

102.0 MHz

100

150

200

250

300

High Speed

050 100 150200

Typical I

Active (mA)

EPM3512A

VCC = 3.3 V

Room Temperature

Frequency (MHz)

Low Power

116.3 MHz

76.3 MHz

100

200

300

400

500

600

020 40 80 100

Typical I

Active (mA)

CC High Speed

60 120 140

42 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Device

Pin–Outs

See the Altera web site (http://www.altera.com) or the Altera Digital

Library for pin–out information.

Figures 14 through 18 show the package pin–out diagrams for

MAX 3000A devices.

Figure 14. 44–Pin PLCC/TQFP Package Pin–Out Diagram

Package outlines not drawn to scale.

44-Pin PLCC

I/O

VCC

INPUT/OE2/GCLK2

INPUT/GCLRn

INPUT/OE1

INPUT/GCLK1

GND

I/O

I/O/TDO

I/O

GND

VCC

I/O

I/O/TCK

I/O

GND

I/O

GND

VCC

I/O

6 5 4 3 2 1 44 43 42 41 40

18 19 20 21 22 23 24 25 26 27 28

EPM3032A

EPM3064A

I/O/TDI

I/O

GND

I/O

I/O/TMS

I/O

VCC

I/O

GND

44-Pin TQFP

Pin 12 Pin 23

Pin 34

Pin 1

I/O

VCC

INPUT/OE2/GCLK2

INPUT/GCLRn

INPUT/OE1

INPUT/GCLK1

GND

I/O

I/O/TDO

I/O

GND

VCC

I/O

I/O/TCK

I/O

GND

I/O

GND

VCC

I/O

I/O/TDI

I/O

GND

I/O

I/O/TMS

I/O

VCC

I/O

GND

EPM3032A

EPM3064A

Altera Corporation 43

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 15. 100–Pin TQFP Package Pin–Out Diagram

Package outline not drawn to scale.

Figure 16. 144–Pin TQFP Package Pin–Out Diagram

Package outline not drawn to scale.

Pin 1

Pin 26

Pin 76

Pin 51

EPM3064A

EPM3128A

Indicates location

of Pin 1

Pin 1 Pin 109

Pin 73

Pin 37

EPM3128A

EPM3256A

44 Altera Corporation

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 17. 208–Pin PQFP Package Pin–Out Diagram

Package outline not drawn to scale.

Pin 1 Pin 157

Pin 105Pin 53

EPM3256A

EPM3512A

Altera Corporation 45

MAX 3000A Programmable Logic Device Family Data Sheet

Figure 18. 256-Pin FineLine BGA Package Pin-Out Diagram

Package outline not drawn to scale.

Revision

History

The information contained in the MAX 3000A Programmable Logic Device

Data Sheet version 3.5 supersedes information published in previous

versions. The following changes were made in the MAX 3000A

Programmable Logic Device Data Sheet version 3.5:

Version 3.5

The following changes were made in the MAX 3000A Programmable Logic

Device Data Sheet version 3.5:

■New paragraph added before “Expander Product Terms”.

Version 3.4

The following changes were made in the MAX 3000A Programmable Logic

Device Data Sheet version 3.4:

■Updated Table 1.

Indicates

Location of

Ball A1

A1 Ball

Pad Corner

16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

EPM3512A

stylized Altera logo, specific device designations, and all other words and logos that are identified as

trademarks and/or service marks are, unless noted otherwise, the trademarks and service marks of Altera

Corporation in the U.S. and other countries. All other product or service names are the property of their

respective holders. Altera products are protected under numerous U.S. and foreign patents and pending

applications, maskwork rights, and copyrights. Altera warrants performance of its semiconductor products to

current specifications in accordance with Altera's standard warranty, but reserves the right

to make changes to any products and services at any time without notice. Altera assumes no

responsibility or liability arising out of the application or use of any information, product, or

service described herein except as expressly agreed to in writing by Altera Corporation.

Altera customers are advised to obtain the latest version of device specifications before

relying on any published information and before placing orders for products or services

101 Innovation Drive

San Jose, CA 95134

(408) 544-7000

http://www.altera.com

Applications Hotline:

(800) 800-EPLD

Customer Marketing:

(408) 544-7104

Literature Services:

lit_req@altera.com

MAX 3000A Programmable Logic Device Family Data Sheet

46 Altera Corporation

Version 3.3

The following changes were made in the MAX 3000A Programmable Logic

Device Data Sheet version 3.3:

■Updated Tables 3, 13, and 26.

■Added Tables 4 through 6.

■Updated Figures 12 and 13.

■Added “Programming Sequence” on page 14 and “Programming

Times” on page 14

Version 3.2

The following change were made in the MAX 3000A Programmable Logic

Device Data Sheet version 3.2:

■Updated the EPM3512 ICC versus frequency graph in Figure 13.

Version 3.1

The following changes were made in the MAX 3000A Programmable Logic

Device Data Sheet version 3.1:

■Updated timing information in Table 1 for the EPM3256A device.

■Updated Note (10) of Table 15.

Version 3.0

The following changes were made in the MAX 3000A Programmable Logic

Device Data Sheet version 3.0:

■Added EPM3512A device.

■Updated Tables 2 and 3.