5M80ZE64I5N - INTEL - Datasheet.Company

May 2011 Altera Corporation MAX V Device Handbook

Section I. MAX V Device Core

This section provides a complete overview of all features relating to the MAX®V

device family.

This section includes the following chapters:

■Chapter 1, MAX V Device Family Overview

■Chapter 2, MAX V Architecture

■Chapter 3, DC and Switching Characteristics for MAX V Devices

I–2 Section I: MAX V Device Core

MAX V Device Handbook May 2011 Altera Corporation

MAX V Device Handbook

May 2011

MV51001-1.2

and/or trademarks of Altera Corporation in the U.S. and other countries. All other trademarks and service marks are the property of their respective holders as described at

www.altera.com/common/legal.html. 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. 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.

1. MAX V Device Family Overview

The MAX®V family of low cost and low power CPLDs offer more density and I/Os

per footprint versus other CPLDs. Ranging in density from 40 to 2,210 logic elements

(LEs) (32 to 1,700 equivalent macrocells) and up to 271 I/Os, MAX V devices provide

programmable solutions for applications such as I/O expansion, bus and protocol

bridging, power monitoring and control, FPGA configuration, and analog IC

interface.

MAX V devices feature on-chip flash storage, internal oscillator, and memory

functionality. With up to 50% lower total power versus other CPLDs and requiring as

few as one power supply, MAX V CPLDs can help you meet your low power design

requirement.

This chapter contains the following sections:

■“Feature Summary” on page 1–1

■“Integrated Software Platform” on page 1–3

■“Device Pin-Outs” on page 1–3

■“Ordering Information” on page 1–4

Feature Summary

The following list summarizes the MAX V device family features:

■Low-cost, low-power, and non-volatile CPLD architecture

■Instant-on (0.5 ms or less) configuration time

■Standby current as low as 25 µA and fast power-down/reset operation

■Fast propagation delay and clock-to-output times

■Internal oscillator

■Emulated RSDS output support with a data rate of up to 200 Mbps

■Emulated LVDS output support with a data rate of up to 304 Mbps

■Four global clocks with two clocks available per logic array block (LAB)

■User flash memory block up to 8 Kbits for non-volatile storage with up to 1000

read/write cycles

■Single 1.8-V external supply for device core

■MultiVolt I/O interface supporting 3.3-V, 2.5-V, 1.8-V, 1.5-V, and 1.2-V logic levels

■Bus-friendly architecture including programmable slew rate, drive strength,

bus-hold, and programmable pull-up resistors

■Schmitt triggers enabling noise tolerant inputs (programmable per pin)

1–2 Chapter 1: MAX V Device Family Overview

Feature Summary

MAX V Device Handbook May 2011 Altera Corporation

■I/Os are fully compliant with the PCI-SIG® PCI Local Bus Specification, revision

2.2 for 3.3-V operation

■Hot-socket compliant

■Built-in JTAG BST circuitry compliant with IEEE Std. 1149.1-1990

Table 1–1 lists the MAX V family features.

MAX V devices accept 1.8 V on their

VCCINT

pins. The 1.8-V VCCINT external supply

powers the device core directly. MAX V devices operate internally at 1.8 V. The

supported MultiVolt I/O interface voltage levels (VCCIO) are 1.2 V, 1.5 V, 1.8 V, 2.5 V,

and 3.3 V.

MAX V devices are available in two speed grades: –4 and –5, with –4 being the fastest.

For commercial applications, speed grades –C4 and –C5 are available. For industrial

and automotive applications, speed grade –I5 and –A5 are available, respectively.

These speed grades represent the overall relative performance, not any specific timing

parameter.

fFor propagation delay timing numbers within each speed grade and density, refer to

the DC and Switching Characteristics for MAX V Devices chapter.

MAX V devices are available in space-saving FineLine BGA (FBGA), Micro FineLine

BGA (MBGA), plastic enhanced quad flat pack (EQFP), and thin quad flat pack

(TQFP) packages (refer to Table 1–2 and Table 1–3 ). MAX V devices support vertical

migration within the same package (for example, you can migrate between the

5M570Z, 5M1270Z, and 5M2210Z devices in the 256-pin FineLine BGA package).

Vertical migration means that you can migrate to devices whose dedicated pins and

JTAG pins are the same and power pins are subsets or supersets for a given package

across device densities. The largest density in any package has the highest number of

power pins; you must lay out for the largest planned density in a package to provide

Table 1–1. MAX V Family Features

Feature 5M40Z 5M80Z 5M160Z 5M240Z 5M570Z 5M1270Z 5M2210Z

LEs 40 80 160 240 570 1,270 2,210

Typical Equivalent Macrocells 32 64 128 192 440 980 1,700

User Flash Memory Size (bits) 8,192 8,192 8,192 8,192 8,192 8,192 8,192

Global Clocks 4444444

Internal Oscillator 1 1 1 1 1 1 1

Maximum User I/O pins 54 79 79 114 159 271 271

tPD1 (ns) (1) 7.5 7.5 7.5 7.5 9.0 6.2 7.0

fCNT (MHz) (2) 152 152 152 152 152 304 304

tSU (ns) 2.3 2.3 2.3 2.3 2.2 1.2 1.2

tCO (ns) 6.5 6.5 6.5 6.5 6.7 4.6 4.6

Notes to Table 1–1:

(1) tPD1 represents a pin-to-pin delay for the worst case I/O placement with a full diagonal path across the device and combinational logic

implemented in a single LUT and LAB that is adjacent to the output pin.

(2) The maximum global clock frequency, fCNT, is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay will run faster

than this number.

Chapter 1: MAX V Device Family Overview 1–3

Integrated Software Platform

May 2011 Altera Corporation MAX V Device Handbook

the necessary power pins for migration. For I/O pin migration across densities, cross

reference the available I/O pins using the device pin-outs for all planned densities of

a given package type to identify which I/O pins can be migrated. The Quartus® II

software can automatically cross-reference and place all pins for you when given a

device migration list.

Integrated Software Platform

The Quartus II software provides an integrated environment for HDL and schematic

design entry, compilation and logic synthesis, full simulation and advanced timing

analysis, and programming of MAX V devices.

fFor more information about the Quartus II software features, refer to the Quartus II

Handbook.

You can debug your MAX V designs using In-System Sources and Probes Editor in

the Quartus II software. This feature allows you to easily control any internal signal

and provides you with a completely dynamic debugging environment.

fFor more information about the In-System Sources and Probes Editor, refer to the

Design Debugging Using In-System Sources and Probes chapter of the Quartus II

Handbook.

Device Pin-Outs

fFor more information, refer to the MAX V Device Pin-Out Files page.

Table 1–2. MAX V Packages and User I/O Pins (Note 1)

Device 64-Pin

MBGA

64-Pin

EQFP

68-Pin

MBGA

100-Pin

TQFP

100-Pin

MBGA

144-Pin

TQFP

256-Pin

FBGA

324-Pin

FBGA

5M40Z 30 54 — — — — — —

5M80Z 30 54 52 79 — — — —

5M160Z — 54 52 79 79 — — —

5M240Z — — 52 79 79 114 — —

5M570Z — — — 74 74 114 159 —

5M1270Z — — — — — 114 211 271

5M2210Z — — — — — — 203 271

Note to Table 1–2:

(1) Device packages under the same arrow sign have vertical migration capability.

Table 1–3. MAX V Package Sizes

Package 64-Pin

MBGA

64-Pin

EQFP

68-Pin

MBGA

100-Pin

TQFP

100-Pin

MBGA

144-Pin

TQFP

256-Pin

FBGA

324-Pin

FBGA

Pitch (mm) 0.5 0.4 0.5 0.5 0.5 0.5 1 1

Area (mm2) 20.25 81 25 256 36 484 289 361

Length × width

(mm × mm) 4.5 × 4.5 9 × 9 5 × 5 16 × 16 6 × 6 22 × 22 17 × 17 19 × 19

1–4 Chapter 1: MAX V Device Family Overview

Ordering Information

MAX V Device Handbook May 2011 Altera Corporation

Ordering Information

Figure 1–1 shows the ordering codes for MAX V devices.

Document Revision History

Table 1 –4 lists the revision history for this chapter.

Figure 1–1. MAX V Device Packaging Ordering Information

Package Type

T: Thin quad flat pack (TQFP)

F: FineLine BGA (FBGA)

M: Micro FineLine BGA (MBGA)

E: Plastic Enhanced Quad Flat Pack (EQFP)

Speed Grade

Family Signature

5M: MAX V

Operating Temperature

Pin Count

Device Type

40Z: 40 Logic Elements

80Z: 80 Logic Elements

160Z: 160 Logic Elements

240Z: 240 Logic Elements

570Z: 570 Logic Elements

1270Z: 1,270 Logic Elements

2210Z: 2,210 Logic Elements

Optional Suffix

4 or 5, with 4 being the fastest

Number of pins for a particular package

C: Commercial temperature (T

= 0° C to 85° C)

I: Industrial temperature (T

= -40° C to 100° C)

A: Automotive temperature (T

= -40° C to 125° C)

5M 40Z E 64 C 4 N

Indicates specific device

options or shipment method

N: Lead-free packaging

Table 1–4. Document Revision History

Date Version Changes

May 2011 1.2

■Updated Figure 1–1.

■Updated Table 1–3.

January 2011 1.1 Updated “Feature Summary” section.

December 2010 1.0 Initial release.

MAX V Device Handbook

December 2010

MV51002-1.0

and/or trademarks of Altera Corporation in the U.S. and other countries. All other trademarks and service marks are the property of their respective holders as described at

www.altera.com/common/legal.html. 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 app lication or u se of any

information, product, or service described herein except as expressly agreed to in writing by Altera. 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.

2. MAX V Architecture

This chapter describes the architecture of the MAX® V device and contains the

following sections:

■“Functional Description” on page 2–1

■“Logic Array Blocks” on page 2–4

■“Logic Elements” on page 2–8

■“MultiTrack Interconnect” on page 2–14

■“Global Signals” on page 2–19

■“User Flash Memory Block” on page 2–21

■“Internal Oscillator” on page 2–22

■“Core Voltage” on page 2–25

■“I/O Structure” on page 2–26

Functional Description

MAX V devices contain a two-dimensional row- and column-based architecture to

implement custom logic. Row and column interconnects provide signal interconnects

between the logic array blocks (LABs).

Each LAB in the logic array contains 10 logic elements (LEs). An LE is a small unit of

logic that provides efficient implementation of user logic functions. LABs are grouped

into rows and columns across the device. The MultiTrack interconnect provides fast

granular timing delays between LABs. The fast routing between LEs provides

minimum timing delay for added levels of logic versus globally routed interconnect

structures.

The I/O elements (IOEs) located after the LAB rows and columns around the

periphery of the MAX V device feeds the I/O pins. Each IOE contains a bidirectional

I/O buffer with several advanced features. I/O pins support Schmitt trigger inputs

and various single-ended standards, such as 33-MHz, 32-bit PCI™, and LVTTL.

MAX V devices provide a global clock network. The global clock network consists of

four global clock lines that drive throughout the entire device, providing clocks for all

resources within the device. You can also use the global clock lines for control signals

such as clear, preset, or output enable.

2–2 Chapter 2: MAX V Architecture

Functional Description

MAX V Device Handbook December 2010 Altera Corporation

Figure 2–1 shows a functional block diagram of the MAX V device.

Each MAX V device contains a flash memory block within its floorplan. This block is

located on the left side of the 5M40Z, 5M80Z, 5M160Z, and 5M240Z devices. On the

5M240Z (T144 package), 5M570Z, 5M1270Z, and 5M2210Z devices, the flash memory

block is located on the bottom-left area of the device. The majority of this flash

memory storage is partitioned as the dedicated configuration flash memory (CFM)

block. The CFM block provides the non-volatile storage for all of the SRAM

configuration information. The CFM automatically downloads and configures the

logic and I/O at power-up, providing instant-on operation.

fFor more information about configuration upon power-up, refer to the Hot Socketing

and Power-On Reset for MAX V Devices chapter.

A portion of the flash memory within the MAX V device is partitioned into a small

block for user data. This user flash memory (UFM) block provides 8,192 bits of

general-purpose user storage. The UFM provides programmable port connections to

the logic array for reading and writing. There are three LAB rows adjacent to this

block, with column numbers varying by device.

Figure 2–1. Device Block Diagram

Logic Array

BLock (LAB)

MultiTrack

Interconnect

MultiTrack

Interconnect

Logic

Element

Logic

Element

IOE

IOE IOE

Logic

Element

Logic

Element

IOE

Logic

Element

Logic

Element

IOE IOE

Logic

Element

Logic

Element

Logic

Element

Logic

Element

IOE IOE

Logic

Element

Logic

Element

Chapter 2: MAX V Architecture 2–3

Functional Description

December 2010 Altera Corporation MAX V Device Handbook

Table 2–1 lists the number of LAB rows and columns in each device, as well as the

number of LAB rows and columns adjacent to the flash memory area. The long LAB

rows are full LAB rows that extend from one side of row I/O blocks to the other. The

short LAB rows are adjacent to the UFM block; their length is shown as width in LAB

columns.

Table 2–1. Device Resources for MAX V Devices

Device UFM Blocks LAB Columns

LAB Rows

Tot al LABs

Long LAB Rows Short LAB Rows (Width) (1)

5M40Z 1 6 4 — 24

5M80Z 1 6 4 — 24

5M160Z 1 6 4 — 24

5M240Z (2) 164 — 24

5M240Z (3) 1124 3 (3) 57

5M570Z 1 12 4 3 (3) 57

5M1270Z (4) 1167 3 (5) 127

5M1270Z (5) 12010 3 (7) 221

5M2210Z 1 20 10 3 (7) 221

Notes to Table 2–1 :

(1) The width is the number of LAB columns in length.

(2) Not applicable to T144 package of the 5M240Z device.

(3) Only applicable to T144 package of the 5M240Z device.

(4) Not applicable to F324 package of the 5M1270Z device.

(5) Only applicable to F324 package of the 5M1270Z device.

2–4 Chapter 2: MAX V Architecture

Logic Array Blocks

MAX V Device Handbook December 2010 Altera Corporation

Figure 2–2 shows a floorplan of a MAX V device.

Logic Array Blocks

Each LAB consists of 10 LEs, LE carry chains, LAB control signals, a local interconnect,

a look-up table (LUT) chain, and register chain connection lines. There are 26 possible

unique inputs into an LAB, with an additional 10 local feedback input lines fed by LE

outputs in the same LAB. The local interconnect transfers signals between LEs in the

same LAB. LUT chain connections transfer the LUT output from one LE to the

Figure 2–2. Device Floorplan for MAX V Devices (Note 1)

Note to Figure 2–2:

(1) The device shown is a 5M570Z device. 5M1270Z and 5M2210Z devices have a similar floorplan with more LABs. For 5M40Z, 5M80Z, 5M160Z,

and 5M240Z devices, the CFM and UFM blocks are located on the left side of the device.

UFM Block

CFM Block

I/O Blocks

Logic Array

Blocks

I/O Blocks

Logic Arra

Blocks

2 GCLK

Inputs

2 GCLK

Inputs

I/O Blocks

Chapter 2: MAX V Architecture 2–5

Logic Array Blocks

December 2010 Altera Corporation MAX V Device Handbook

adjacent LE for fast sequential LUT connections within the same LAB. Register chain

connections transfer the output of one LE’s register to the adjacent LE’s register

within an LAB. The Quartus® II software places associated logic within an LAB or

adjacent LABs, allowing the use of local, LUT chain, and register chain connections

for performance and area efficiency. Figure 2–3 shows the MAX V LAB.

Figure 2–3. LAB Structure for MAX V Devices

Note to Figure 2–3:

(1) Only from LABs adjacent to IOEs.

DirectLink

interconnect from

adjacent LAB

or IOE

DirectLink

interconnect to

adjacent LAB

or IOE

Row Interconnect

Column Interconnect

Local InterconnectLAB

DirectLink

interconnect from

adjacent LAB

or IOE

DirectLink

interconnect to

adjacent LAB

or IOE

Fast I/O connection

to IOE (1)

Fast I/O connection

to IOE (1)

LE0

LE1

LE2

LE3

LE4

LE6

LE7

LE8

LE9

LE5

Logic Element

2–6 Chapter 2: MAX V Architecture

Logic Array Blocks

MAX V Device Handbook December 2010 Altera Corporation

LAB Interconnects

Column and row interconnects and LE outputs within the same LAB drive the LAB

local interconnect. Adjacent LABs, from the left and right, can also drive an LAB’s

local interconnect through the DirectLink connection. The DirectLink connection

feature minimizes the use of row and column interconnects, providing higher

performance and flexibility. Each LE can drive 30 other LEs through fast local and

DirectLink interconnects. Figure 2–4 shows the DirectLink connection.

LAB Control Signals

Each LAB contains dedicated logic for driving control signals to its LEs. The control

signals include two clocks, two clock enables, two asynchronous clears, a

synchronous clear, an asynchronous preset/load, a synchronous load, and

add/subtract control signals, providing a maximum of 10 control signals at a time.

Synchronous load and clear signals are generally used when implementing counters

but they can also be used with other functions.

Each LAB can use two clocks and two clock enable signals. Each LAB’s clock and

clock enable signals are linked. For example, any LE in a particular LAB using the

labclk1

signal also uses

labclkena1

. If the LAB uses both the rising and falling edges

of a clock, it also uses both LAB-wide clock signals. Deasserting the clock enable

signal turns off the LAB-wide clock.

Each LAB can use two asynchronous clear signals and an asynchronous load/preset

signal. By default, the Quartus II software uses a

NOT

gate push-back technique to

achieve preset. If you disable the

NOT

gate push-back option or assign a given register

to power-up high using the Quartus II software, the preset is then achieved using the

asynchronous load signal with asynchronous load data input tied high.

Figure 2–4. DirectLink Connection

LAB

DirectLink

interconnect

to right

DirectLink interconnect from

right LAB or IOE output

DirectLink interconnect from

left LAB or IOE output

Local

Interconnect

DirectLink

interconnect

to left

LE0

LE1

LE2

LE3

LE4

LE6

LE7

LE8

LE9

LE5

Logic Element

Chapter 2: MAX V Architecture 2–7

Logic Array Blocks

December 2010 Altera Corporation MAX V Device Handbook

With the LAB-wide

addnsub

control signal, a single LE can implement a one-bit adder

and subtractor. This signal saves LE resources and improves performance for logic

functions such as correlators and signed multipliers that alternate between addition

and subtraction depending on data.

The LAB column clocks

[3..0]

, driven by the global clock network, and LAB local

interconnect generate the LAB-wide control signals. The MultiTrack interconnect

structure drives the LAB local interconnect for non-global control signal generation.

The MultiTrack interconnect’s inherent low skew allows clock and control signal

distribution in addition to data signals. Figure 2–5 shows the LAB control signal

generation circuit.

Figure 2–5. LAB-Wide Control Signals

labclkena1

labclk2labclk1

labclkena2

asyncload

or labpre

syncload

Dedicated

LAB Column

Clocks

Local

Interconnect

Local

Interconnect

Local

Interconnect

Local

Interconnect

Local

Interconnect

Local

Interconnect labclr1

labclr2

synclr

addnsub

2–8 Chapter 2: MAX V Architecture

Logic Elements

MAX V Device Handbook December 2010 Altera Corporation

Logic Elements

The smallest unit of logic in the MAX V architecture, the LE, is compact and provides

advanced features with efficient logic utilization. Each LE contains a four-input LUT,

which is a function generator that can implement any function of four variables. In

addition, each LE contains a programmable register and carry chain with carry-select

capability. A single LE also supports dynamic single-bit addition or subtraction mode

that is selected by an LAB-wide control signal. Each LE drives all types of

interconnects: local, row, column, LUT chain, register chain, and DirectLink

interconnects as shown in Figure 2–6.

You can configure each LE’s programmable register for D, T, JK, or SR operation. Each

asynchronous load/preset inputs. Global signals, general purpose I/O (GPIO) pins,

or any LE can drive the register’s clock and clear control signals. Either GPIO pins or

LEs can drive the clock enable, preset, asynchronous load, and asynchronous data.

The asynchronous load data input comes from the

data3

input of the LE. For

combinational functions, the LUT output bypasses the register and drives directly to

the LE outputs.

Each LE has three outputs that drive the local, row, and column routing resources. The

LUT or register output can drive these three outputs independently. Two LE outputs

drive either a column or row and DirectLink routing connections while one output

drives the local interconnect resources. This configuration allows the LUT to drive one

output while the register drives another output. This register packing feature

Figure 2–6. LE for MAX V Devices

labclk1

labclk2

labclr2

labpre/aload

Carry-In1

Carry-In0

LAB Carry-In

Clock and

Clock Enable

Select

LAB Carry-Out

Carry-Out1

Carry-Out0

Look-Up

Ta ble

(LUT)

Carry

Chain

Row, column,

and DirectLink

routing

Row, column,

and DirectLink

routing

Programmable

PRN/ALD

CLRN

ENA

Packed

Chip-Wide

Reset (DEV_CLRn)

labclkena1

labclkena2

Synchronous

Load and

Clear Logic

LAB-wide

Synchronous

Load LAB-wide

Synchronous

Clear

Asynchronous

Clear/Preset/

Load Logic

data1

data2

data3

data4

LUT chain

routing to next LE

labclr1

Local routing

output

ADATA

addnsub

Feedback

routing from

previous LE

Chapter 2: MAX V Architecture 2–9

Logic Elements

December 2010 Altera Corporation MAX V Device Handbook

improves device utilization because the device can use the register and the LUT for

unrelated functions. Another special packing mode allows the register output to feed

back into the LUT of the same LE so that the register is packed with its own fan-out

LUT. This mode provides another mechanism for improved fitting. The LE can also

drive out registered and unregistered versions of the LUT output.

LUT Chain and Register Chain

In addition to the three general routing outputs, the LEs within a LAB have LUT chain

and register chain outputs. LUT chain connections allow LUTs within the same LAB

to cascade together for wide input functions. Register chain outputs allow registers

within the same LAB to cascade together. The register chain output allows a LAB to

use LUTs for a single combinational function and the registers for an unrelated shift

saving local interconnect resources. For more information about LUT chain and

addnsub Signal

The LE’s dynamic adder/subtractor feature saves logic resources by using one set of

LEs to implement both an adder and a subtractor. This feature is controlled by the

LAB-wide control signal

addnsub

. The

addnsub

signal sets the LAB to perform either

A + B or A – B. The LUT computes addition; subtraction is computed by adding the

two’s complement of the intended subtractor. The LAB-wide signal converts to two’s

complement by inverting the B bits within the LAB and setting carry-in to 1, which

adds one to the LSB. The LSB of an adder/subtractor must be placed in the first LE of

the LAB, where the LAB-wide

addnsub

signal automatically sets the carry-in to 1. The

Quartus II Compiler automatically places and uses the adder/subtractor feature

when using adder/subtractor parameterized functions.

LE Operating Modes

The MAX V LE can operate in one of the following modes:

■“Normal Mode”

■“Dynamic Arithmetic Mode”

Each mode uses LE resources differently. In each mode, eight available inputs to the

LE, the four data inputs from the LAB local interconnect,

carry-in0

and

carry-in1

from the previous LE, the LAB carry-in from the previous carry-chain LAB, and the

desired logic function. LAB-wide signals provide clock, asynchronous clear,

asynchronous preset/load, synchronous clear, synchronous load, and clock enable

control for the register. These LAB-wide signals are available in all LE modes. The

addnsub

control signal is allowed in arithmetic mode.

The Quartus II software, along with parameterized functions such as the library of

parameterized modules (LPM) functions, automatically chooses the appropriate

mode for common functions such as counters, adders, subtractors, and arithmetic

functions.

2–10 Chapter 2: MAX V Architecture

Logic Elements

MAX V Device Handbook December 2010 Altera Corporation

Normal Mode

The normal mode is suitable for general logic applications and combinational

functions. In normal mode, four data inputs from the LAB local interconnect are

inputs to a four-input LUT as shown in Figure 2–7. The Quartus II Compiler

automatically selects the carry-in or the

data3

signal as one of the inputs to the LUT.

Each LE can use LUT chain connections to drive its combinational output directly to

the next LE in the LAB. Asynchronous load data for the register comes from the

data3

input of the LE. LEs in normal mode support packed registers.

Dynamic Arithmetic Mode

The dynamic arithmetic mode is ideal for implementing adders, counters,

accumulators, wide parity functions, and comparators. A LE in dynamic arithmetic

mode uses four 2-input LUTs configurable as a dynamic adder/subtractor. The first

two 2-input LUTs compute two summations based on a possible carry-in of 1 or 0; the

other two LUTs generate carry outputs for the two chains of the carry-select circuitry.

As shown in Figure 2–8, the LAB carry-in signal selects either the

carry-in0

carry-in1

chain. The selected chain’s logic level in turn determines which parallel

sum is generated as a combinational or registered output. For example, when

implementing an adder, the sum output is the selection of two possible calculated

sums:

data1 + data2 + carry-in0

data1 + data2 + carry-in1

Figure 2–7. LE in Normal Mode

Note to Figure 2–7:

(1) This signal is only allowed in normal mode if the LE is after an adder/subtractor chain.

data1

4-Input

LUT

data2

data3

cin (from cout

of previous LE)

data4

addnsub (LAB Wide)

clock (LAB Wide)

ena (LAB Wide)

aclr (LAB Wide)

aload

(LAB Wide)

ALD/PRE

CLRN

ENA

ADATA

sclear

(LAB Wide)

sload

(LAB Wide)

connection

LUT chain

connection

chain output

Row, column, and

DirectLink routing

Row, column, and

DirectLink routing

Local routing

(1)

Chapter 2: MAX V Architecture 2–11

Logic Elements

December 2010 Altera Corporation MAX V Device Handbook

The other two LUTs use the

data1

and

data2

signals to generate two possible

carry-out signals: one for a carry of 1 and the other for a carry of 0. The

carry-in0

signal acts as the carry-select for the

carry-out0

output and

carry-in1

acts as the

carry-select for the

carry-out1

output. LEs in arithmetic mode can drive out

registered and unregistered versions of the LUT output.

The dynamic arithmetic mode also offers clock enable, counter enable, synchronous

up/down control, synchronous clear, synchronous load, and dynamic

adder/subtractor options. The LAB local interconnect data inputs generate the

counter enable and synchronous up/down control signals. The synchronous clear

and synchronous load options are LAB-wide signals that affect all registers in the

LAB. The Quartus II software automatically places any registers that are not used by

the counter into other LABs. The

addnsub

LAB-wide signal controls whether the LE

acts as an adder or subtractor.

Carry-Select Chain

The carry-select chain provides a very fast carry-select function between LEs in

dynamic arithmetic mode. The carry-select chain uses the redundant carry calculation

to increase the speed of carry functions. The LE is configured to calculate outputs for a

possible carry-in of 0 and carry-in of 1 in parallel. The

carry-in0

and

carry-in1

signals from a lower-order bit feed forward into the higher-order bit via the parallel

carry chain and feed into both the LUT and the next portion of the carry chain.

Carry-select chains can begin in any LE within an LAB.

Figure 2–8. LE in Dynamic Arithmetic Mode

Note to Figure 2–8:

(1) The addnsub signal is tied to the carry input for the first LE of a carry chain only.

data1 LUT

data2

data3

addnsub

(LAB Wide)

clock (LAB Wide)

ena (LAB Wide)

aclr (LAB Wide)

ALD/PRE

CLRN

ENA

ADATA

connection

LUT

Carry-Out1Carry-Out0

LAB Carry-In

Carry-In0

Carry-In1

(1)

sclear

(LAB Wide)

sload

(LAB Wide)

LUT chain

connection

chain output

Row, column, an

direct link routing

Row, column, an

direct link routing

Local routing

aload

(LAB Wide)

2–12 Chapter 2: MAX V Architecture

Logic Elements

MAX V Device Handbook December 2010 Altera Corporation

The speed advantage of the carry-select chain is in the parallel pre-computation of

carry chains. Because the LAB carry-in selects the precomputed carry chain, not every

LE is in the critical path. Only the propagation delays between LAB carry-in

generation (

LE5

and

LE10

) are now part of the critical path. This feature allows the

MAX V architecture to implement high-speed counters, adders, multipliers, parity

functions, and comparators of arbitrary width.

Figure 2–9 shows the carry-select circuitry in an LAB for a 10-bit full adder. One

portion of the LUT generates the sum of two bits using the input signals and the

appropriate carry-in bit; the sum is routed to the output of the LE. The register can be

bypassed for simple adders or used for accumulator functions. Another portion of the

LUT generates carry-out bits. An LAB-wide carry-in bit selects which chain is used for

the addition of given inputs. The carry-in signal for each chain,

carry-in0

carry-in1

, selects the carry-out to carry forward to the carry-in signal of the

next-higher-order bit. The final carry-out signal is routed to an LE, where it is fed to

local, row, or column interconnects.

Figure 2–9. Carry-Select Chain

LE3

LE2

LE1

LE0

Sum1

Sum2

Sum3

Sum4

LE9

LE8

LE7

LE6

A10

B10

Sum7

LE5

Sum6

LE4

Sum5

Sum8

Sum9

Sum10

LAB Carry-In

LAB Carry-Out

LUT

data1

LAB Carry-In

data2

Carry-In0

Carry-In1

Carry-Out0 Carry-Out1

Sum

To top of adjacent LAB

Chapter 2: MAX V Architecture 2–13

Logic Elements

December 2010 Altera Corporation MAX V Device Handbook

The Quartus II software automatically creates carry chain logic during design

processing, or you can create it manually during design entry. Parameterized

functions such as LPM functions automatically take advantage of carry chains for the

appropriate functions. The Quartus II software creates carry chains longer than 10 LEs

by linking adjacent LABs within the same row together automatically. A carry chain

can extend horizontally up to one full LAB row, but does not extend between LAB

rows.

Clear and Preset Logic Control

LAB-wide signals control the logic for the register’s clear and preset signals. The LE

directly supports an asynchronous clear and preset function. The register preset is

achieved through the asynchronous load of a logic high. MAX V devices support

simultaneous preset/asynchronous load and clear signals. An asynchronous clear

signal takes precedence if both signals are asserted simultaneously. Each LAB

supports up to two clears and one preset signal.

In addition to the clear and preset ports, MAX V devices provide a chip-wide reset pin

(

DEV_CLRn

) that resets all registers in the device. An option set before compilation in

the Quartus II software controls this pin. This chip-wide reset overrides all other

control signals and uses its own dedicated routing resources without using any of the

four global resources. Driving this signal low before or during power-up prevents

user mode from releasing clears within the design. This allows you to control when

clear is released on a device that has just been powered-up. If not set for its chip-wide

reset function, the

DEV_CLRn

pin is a regular I/O pin.

By default, all registers in MAX V devices are set to power-up low. However, this

power-up state can be set to high on individual registers during design entry using

the Quartus II software.

LE RAM

The Quartus II memory compiler can configure the unused LEs as LE RAM.

MAX V devices support the following memory types:

■FIFO synchronous R/W

■FIFO asynchronous R/W

■1 port SRAM

■2 port SRAM

■3 port SRAM

■shift registers

fFor more information about memory, refer to the Internal Memory (RAM and ROM)

User Guide.

2–14 Chapter 2: MAX V Architecture

MultiTrack Interconnect

MAX V Device Handbook December 2010 Altera Corporation

MultiTrack Interconnect

In the MAX V architecture, connections between LEs, the UFM, and device I/O pins

are provided by the MultiTrack interconnect structure. The MultiTrack interconnect

consists of continuous, performance-optimized routing lines used for inter- and

intra-design block connectivity. The Quartus II Compiler automatically places critical

design paths on faster interconnects to improve design performance.

The MultiTrack interconnect consists of row and column interconnects that span fixed

distances. A routing structure with fixed length resources for all devices allows

predictable and short delays between logic levels instead of large delays associated

with global or long routing lines. Dedicated row interconnects route signals to and

from LABs within the same row. These row resources include:

■DirectLink interconnects between LABs

■R4 interconnects traversing four LABs to the right or left

The DirectLink interconnect allows an LAB to drive into the local interconnect of its

left and right neighbors. The DirectLink interconnect provides fast communication

between adjacent LABs and blocks without using row interconnect resources.

The R4 interconnects span four LABs and are used for fast row connections in a

four-LAB region. Every LAB has its own set of R4 interconnects to drive either left or

right. Figure 2–10 shows R4 interconnect connections from an LAB. R4 interconnects

can drive and be driven by row IOEs. For LAB interfacing, a primary LAB or

horizontal LAB neighbor can drive a given R4 interconnect. For R4 interconnects that

drive to the right, the primary LAB and right neighbor can drive on to the

interconnect. For R4 interconnects that drive to the left, the primary LAB and its left

neighbor can drive on to the interconnect. R4 interconnects can drive other R4

interconnects to extend the range of LABs they can drive. R4 interconnects can also

drive C4 interconnects for connections from one row to another.

Chapter 2: MAX V Architecture 2–15

MultiTrack Interconnect

December 2010 Altera Corporation MAX V Device Handbook

The column interconnect operates similarly to the row interconnect. Each column of

LABs is served by a dedicated column interconnect, which vertically routes signals to

and from LABs and row and column IOEs. These column resources include:

■LUT chain interconnects within an LAB

■Register chain interconnects within an LAB

■C4 interconnects traversing a distance of four LABs in an up and down direction

MAX V devices include an enhanced interconnect structure within LABs for routing

LE output to LE input connections faster using LUT chain connections and register

chain connections. The LUT chain connection allows the combinational output of an

LE to directly drive the fast input of the LE right below it, bypassing the local

interconnect. These resources can be used as a high-speed connection for wide fan-in

functions from

LE 1

LE 10

in the same LAB. The register chain connection allows

the register output of one LE to connect directly to the register input of the next LE in

the LAB for fast shift registers. The Quartus II Compiler automatically takes

advantage of these resources to improve utilization and performance. Figure 2–11

shows the LUT chain and register chain interconnects.

Figure 2–10. R4 Interconnect Connections

Notes to Figure 2–10:

(1) C4 interconnects can drive R4 interconnects.

(2) This pattern is repeated for every LAB in the LAB row.

Primary

LAB (2)

R4 Interconnect

Driving Left

Adjacent LAB can

drive onto another

LAB’s R4 Interconnect

C4 Column Interconnects (1)

R4 Interconnect

Driving Right

LAB

Neighbor

LAB

Neighbor

2–16 Chapter 2: MAX V Architecture

MultiTrack Interconnect

MAX V Device Handbook December 2010 Altera Corporation

The C4 interconnects span four LABs up or down from a source LAB. Every LAB has

its own set of C4 interconnects to drive either up or down. Figure 2–12 shows the C4

interconnect connections from an LAB in a column. The C4 interconnects can drive

and be driven by column and row IOEs. For LAB interconnection, a primary LAB or

its vertical LAB neighbor can drive a given C4 interconnect. C4 interconnects can

drive each other to extend their range as well as drive row interconnects for

column-to-column connections.

Figure 2–11. LUT Chain and Register Chain Interconnects

LE0

LE1

LE2

LE3

LE4

LE5

LE6

LE7

LE8

LE9

LUT Chain

Routing to

Adjacent LE

Local

Interconnect

Routing to Adjacent

LE's Register Input

Local Interconnect

Routing Among LEs

in the LAB

Chapter 2: MAX V Architecture 2–17

MultiTrack Interconnect

December 2010 Altera Corporation MAX V Device Handbook

Figure 2–12. C4 Interconnect Connections (Note 1)

Note to Figure 2–12:

(1) Each C4 interconnect can drive either up or down four rows.

C4 Interconnect

Drives Local and R4

Interconnects

Up to Four Rows

Adjacent LAB can

drive onto neighboring

LAB's C4 interconnect

C4 Interconnect

Driving Up

C4 Interconnect

Driving Down

LAB

Row

Interconnect

Local

Interconnect

2–18 Chapter 2: MAX V Architecture

MultiTrack Interconnect

MAX V Device Handbook December 2010 Altera Corporation

The UFM block communicates with the logic array similar to LAB-to-LAB interfaces.

The UFM block connects to row and column interconnects and has local interconnect

regions driven by row and column interconnects. This block also has DirectLink

interconnects for fast connections to and from a neighboring LAB. For more

information about the UFM interface to the logic array, refer too “User Flash Memory

Block” on page 2–21.

Table 2–2 lists the MAX V device routing scheme.

Table 2–2. Routing Scheme for MAX V Devices

Source

Destination

LUT

Chain

Local

(1)

DirectLink

(1) R4 (1) C4 (1) LE UFM

Block

Column

IOE

Row

IOE

Fast I/O

(1)

LUT Chain — — — — — — v————

Local

Interconnect ——— — ——vv vv—

DirectLink

Interconnect ——v— — ——— ———

R4 Interconnect — — v—vv—— ———

C4 Interconnect — — v—vv—— ———

LE vvv v vv—— vvv

UFM Block — — vv vv—— ———

Column IOE — — — — — v—— ———

Row IOE — — — vvv—— ———

Note to Tab le 2 –2 :

(1) These categories are interconnects.

Chapter 2: MAX V Architecture 2–19

Global Signals

December 2010 Altera Corporation MAX V Device Handbook

Global Signals

Each MAX V device has four dual-purpose dedicated clock pins (

GCLK[3..0]

, two

pins on the left side and two pins on the right side) that drive the global clock network

for clocking, as shown in Figure 2–13. These four pins can also be used as GPIOs if

they are not used to drive the global clock network.

The four global clock lines in the global clock network drive throughout the entire

device. The global clock network can provide clocks for all resources within the

device including LEs, LAB local interconnect, IOEs, and the UFM block. The global

clock lines can also be used for global control signals, such as clock enables,

synchronous or asynchronous clears, presets, output enables, or protocol control

signals such as

TRDY

and

IRDY

for the PCI I/O standard. Internal logic can drive the

global clock network for internally-generated global clocks and control signals.

Figure 2–13 shows the various sources that drive the global clock network.

The global clock network drives to individual LAB column signals, LAB column

clocks

[3..0]

, that span an entire LAB column from the top to the bottom of the

device. Unused global clocks or control signals in an LAB column are turned off at the

LAB column clock buffers shown in Figure 2–14. The LAB column clocks

[3..0]

are

multiplexed down to two LAB clock signals and one LAB clear signal. Other control

signal types route from the global clock network into the LAB local interconnect. For

more information, refer to “LAB Control Signals” on page 2–6.

Figure 2–13. Global Clock Generation

Note to Figure 2–13:

(1) Any I/O pin can use a MultiTrack interconnect to route as a logic array-generated global clock signal.

GCLK0

Global Clock

Network

GCLK1

GCLK2

GCLK3

Logic Array(1)

2–20 Chapter 2: MAX V Architecture

Global Signals

MAX V Device Handbook December 2010 Altera Corporation

Figure 2–14. Global Clock Network (Note 1)

Notes to Figure 2–14:

(1) LAB column clocks in I/O block regions provide high fan-out output enable signals.

(2) LAB column clocks drive to the UFM block.

UFM Block (2)

CFM Block

I/O Block Region

LAB Column

clock[3..0]

LAB Column

clock[3..0]

4 4 4 4 4 4 4 4

Chapter 2: MAX V Architecture 2–21

User Flash Memory Block

December 2010 Altera Corporation MAX V Device Handbook

User Flash Memory Block

MAX V devices feature a single UFM block, which can be used like a serial EEPROM

for storing non-volatile information up to 8,192 bits. The UFM block connects to the

logic array through the MultiTrack interconnect, allowing any LE to interface to the

UFM block. Figure 2–15 shows the UFM block and interface signals. The logic array is

used to create customer interface or protocol logic to interface the UFM block data

outside of the device. The UFM block offers the following features:

■Non-volatile storage up to 16-bit wide and 8,192 total bits

■Two sectors for partitioned sector erase

■Built-in internal oscillator that optionally drives logic array

■Program, erase, and busy signals

■Auto-increment addressing

■Serial interface to logic array with programmable interface

Figure 2–15. UFM Block and Interface Signals

OSC 4

Program

Erase

Control

UFM Sector 1

UFM Sector 0

Address

PROGRAM

ERASE

OSC_ENA

RTP_BUSY

BUSY

OSC

Data Register

UFM Block

DRDin DRDout

ARCLK

ARSHFT

ARDin

DRCLK

DRSHFT

16 16

2–22 Chapter 2: MAX V Architecture

User Flash Memory Block

MAX V Device Handbook December 2010 Altera Corporation

UFM Storage

Each device stores up to 8,192 bits of data in the UFM block. Table 2–3 lists the data

size, sector, and address sizes for the UFM block.

There are 512 locations with 9-bit addressing ranging from

000h

1FFh

. The sector 0

address space is

000h

0FFh

and the sector 1 address space is from

100h

1FFh

. The

data width is up to 16 bits of data. The Quartus II software automatically creates logic

to accommodate smaller read or program data widths. Erasure of the UFM involves

individual sector erasing (that is, one erase of sector 0 and one erase of sector 1 is

required to erase the entire UFM block). Because sector erase is required before a

program or write operation, having two sectors enables a sector size of data to be left

untouched while the other sector is erased and programmed with new data.

Internal Oscillator

As shown in Figure 2–15, the dedicated circuitry within the UFM block contains an

oscillator. The dedicated circuitry uses this oscillator internally for its read and

program operations. This oscillator's divide by 4 output can drive out of the UFM

block as a logic interface clock source or for general-purpose logic clocking. The

typical

OSC

output signal frequency ranges from 3.9 to 5.3 MHz, and its exact

frequency of operation is not programmable.

The UFM internal oscillator can be instantiated using the MegaWizard™ Plug-In

Manager. You can also use the MAX II/MAX V Oscillator megafunction to instantiate

the UFM oscillator without using the UFM memory block.

Table 2–3. UFM Array Size

Device Total Bits Sectors Address Bits Data Width

5M40Z 8,192 2 (4,096 bits per sector) 9 16

5M80Z 8,192 2 (4,096 bits per sector) 9 16

5M160Z 8,192 2 (4,096 bits per sector) 9 16

5M240Z 8,192 2 (4,096 bits per sector) 9 16

5M570Z 8,192 2 (4,096 bits per sector) 9 16

5M1270Z 8,192 2 (4,096 bits per sector) 9 16

5M2210Z 8,192 2 (4,096 bits per sector) 9 16

Chapter 2: MAX V Architecture 2–23

User Flash Memory Block

December 2010 Altera Corporation MAX V Device Handbook

Program, Erase, and Busy Signals

The UFM block’s dedicated circuitry automatically generates the necessary internal

program and erase algorithm after the

PROGRAM

ERASE

input signals have been

asserted. The

PROGRAM

ERASE

signal must be asserted until the busy signal deasserts,

indicating the UFM internal program or erase operation has completed. The UFM

block also supports JTAG as the interface for programming and reading.

fFor more information about programming and erasing the UFM block, refer to the

User Flash Memory in MAX V Devices chapter.

Auto-Increment Addressing

The UFM block supports standard read or stream read operations. The stream read is

supported with an auto-increment address feature. Deasserting the

ARSHIFT

signal

while clocking the

ARCLK

signal increments the address register value to read

consecutive locations from the UFM array.

Serial Interface

The UFM block supports a serial interface with serial address and data signals. The

internal shift registers within the UFM block for address and data are 9 bits and 16 bits

wide, respectively. The Quartus II software automatically generates interface logic in

LEs for a parallel address and data interface to the UFM block. Other standard

protocol interfaces such as SPI are also automatically generated in LE logic by the

Quartus II software.

fFor more information about the UFM interface signals and the Quartus II LE-based

alternate interfaces, refer to the User Flash Memory in MAX V Devices chapter.

2–24 Chapter 2: MAX V Architecture

User Flash Memory Block

MAX V Device Handbook December 2010 Altera Corporation

UFM Block to Logic Array Interface

The UFM block is a small partition of the flash memory that contains the CFM block,

as shown in Figure 2–1 and Figure 2–2. The UFM block for the 5M40Z, 5M80Z,

5M160Z, and 5M240Z devices is located on the left side of the device adjacent to the

left most LAB column. The UFM blocks for the 5M570Z, 5M1270Z, and 5M2210Z

devices are located at the bottom left of the device. The UFM input and output signals

interface to all types of interconnects (R4 interconnect, C4 interconnect, and

DirectLink interconnect to/from adjacent LAB rows). The UFM signals can also be

driven from global clocks,

GCLK[3..0]

. The interface regions for the 5M40Z, 5M80Z,

5M160Z, and 5M240Z devices are shown in Figure 2–16. The interface regions for

5M570Z, 5M1270Z, and 5M2210Z devices are shown in Figure 2–17.

Figure 2–16. 5M40Z, 5M80Z, 5M160Z, and 5M240Z UFM Block LAB Row Interface (Note 1),(2)

Notes to Figure 2–16:

(1) The UFM block inputs and outputs can drive to and from all types of interconnects, not only DirectLink interconnects

from adjacent row LABs.

(2) Not applicable to the T144 package of the 5M240Z device.

UFM Block

CFM Block

PROGRAM

ERASE

OSC_ENA

DRDin

DRCLK

DRSHFT

ARin

ARCLK

ARSHFT

DRDout

OSC

BUSY

RTP_BUSY

LAB

Chapter 2: MAX V Architecture 2–25

Core Voltage

December 2010 Altera Corporation MAX V Device Handbook

Core Voltage

The MAX V architecture supports a 1.8-V core voltage on the VCCINT supply. You must

use a 1.8-V VCC external supply to power the

VCCINT

pins.

Figure 2–17. 5M240Z, 5M570Z, 5M1270Z, and 5M2210Z UFM Block LAB Row Interface (Note 1)

Note to Figure 2–17:

(1) Only applicable to the T144 package of the 5M240Z device.

RTP_BUSY

BUSY

OSC

DRDout

DRDin

PROGRAM

ERASE

OSC_ENA

ARCLK

ARSHFT

DRDCLK

DRDSHFT

ARDin

UFM Block

CFM Block

LAB

Figure 2–18. Core Voltage Feature in MAX V Devices

MAX V Device

1.8-V on

VCCINT Pins

1.8-V Core

Voltage

2–26 Chapter 2: MAX V Architecture

I/O Structure

MAX V Device Handbook December 2010 Altera Corporation

I/O Structure

IOEs support many features, including:

■LVTTL, LVCMOS, LVDS, and RSDS I/O standards

■3.3-V, 32-bit, 33-MHz PCI compliance

■JTAG boundary-scan test (BST) support

■Programmable drive strength control

■Weak pull-up resistors during power-up and in system programming

■Slew-rate control

■Tri-state buffers with individual output enable control

■Bus-hold circuitry

■Programmable pull-up resistors in user mode

■Unique output enable per pin

■Open-drain outputs

■Schmitt trigger inputs

■Fast I/O connection

■Programmable input delay

MAX V device IOEs contain a bidirectional I/O buffer. Figure 2–19 shows the MAX V

IOE structure. Registers from adjacent LABs can drive to or be driven from the IOE’s

bidirectional I/O buffers. The Quartus II software automatically attempts to place

registers in the adjacent LAB with fast I/O connection to achieve the fastest possible

clock-to-output and registered output enable timing. When the fast input registers

option is enabled, the Quartus II software automatically routes the register to

guarantee zero hold time. You can set timing assignments in the Quartus II software

to achieve desired I/O timing.

Chapter 2: MAX V Architecture 2–27

I/O Structure

December 2010 Altera Corporation MAX V Device Handbook

Fast I/O Connection

A dedicated fast I/O connection from the adjacent LAB to the IOEs within an I/O

block provides faster output delays for clock-to-output and tPD propagation delays.

This connection exists for data output signals, not output enable signals or input

signals. Figure 2–20, Figure 2–21, and Figure 2–22 illustrate the fast I/O connection.

Figure 2–19. IOE Structure for MAX V Devices

Notes to Figure 2–19:

(1) Available only in I/O bank 3 of 5M1270Z and 5M2210Z devices.

(2) The programmable pull-up resistor is active during power-up, in-system programming (ISP), and if the device is unprogrammed.

Data_in

Optional Schmitt

Trigger Input

Drive Strength Control

Open-Drain Output

Slew Control

Fast_out

Data_out OE

Optional

PCI Clamp (1)

Programmable

Pull-Up (2)

VCCIO VCCIO

I/O Pin

Optional Bus-Hold

Circuit

DEV_OE

Programmable

Input Delay

2–28 Chapter 2: MAX V Architecture

I/O Structure

MAX V Device Handbook December 2010 Altera Corporation

I/O Blocks

The IOEs are located in I/O blocks around the periphery of the MAX V device. There

are up to seven IOEs per row I/O block and up to four IOEs per column I/O block.

Each column or row I/O block interfaces with its adjacent LAB and MultiTrack

interconnect to distribute signals throughout the device. The row I/O blocks drive

row, column, or DirectLink interconnects. The column I/O blocks drive column

interconnects.

15M40Z, 5M80Z, 5M160Z, and 5M240Z devices have a maximum of five IOEs per row

I/O block.

Figure 2–20 shows how a row I/O block connects to the logic array.

Figure 2–20. Row I/O Block Connection to the Interconnect (Note 1)

Note to Figure 2–20:

(1) Each of the seven IOEs in the row I/O block can have one data_out or fast_out output, one OE output, and

one data_in input.

R4 Interconnects C4 Interconnects

I/O Block Local

Interconnect

data_in[6..0]

data_out

[6..0]

fast_out

[6..0]

Row I/O Block

Contains up to

Seven IOEs

Direct Link

Interconnect

to Adjacent LAB

Direct Link

Interconnect

from Adjacent LAB

LAB Column

clock [3..0]

LAB Local

Interconnect

LAB Row

I/O Block

Chapter 2: MAX V Architecture 2–29

I/O Structure

December 2010 Altera Corporation MAX V Device Handbook

Figure 2–21 shows how a column I/O block connects to the logic array.

I/O Standards and Banks

Table 2–4 lists the I/O standards supported by MAX V devices.

Figure 2–21. Column I/O Block Connection to the Interconnect (Note 1)

Note to Figure 2–21:

(1) Each of the four IOEs in the column I/O block can have one data_out or fast_out output, one OE output, and

one data_in input.

Column I/O

Block Contains

Up To 4 IOEs

I/O Block

Local Interconnect

R4 Interconnects

LAB Local

Interconnect

C4 Interconnects

LAB Local

Interconnect

C4 Interconnects

LAB LAB LAB

data_out

[3..0]

fast_out

[3..0]

Fast I/O

Interconnect

Path

data_in

[3..0]

Column I/O Block

LAB Local

Interconnect

LAB Column

Clock [3..0]

Table 2–4. MAX V I/O Standards (Part 1 of 2)

I/O Standard Type Output Supply Voltage (VCCIO)

(V)

3.3-V LVTTL/LVCMOS Single-ended 3.3

2.5-V LVTTL/LVCMOS Single-ended 2.5

1.8-V LVTTL/LVCMOS Single-ended 1.8

1.5-V LVCMOS Single-ended 1.5

1.2-V LVCMOS Single-ended 1.2

2–30 Chapter 2: MAX V Architecture

I/O Structure

MAX V Device Handbook December 2010 Altera Corporation

The 5M40Z, 5M80Z, 5M160Z, 5M240Z, and 5M570Z devices support two I/O banks,

as shown in Figure 2–22. Each of these banks support all the LVTTL, LVCMOS, LVDS,

and RSDS standards shown in Table 2–4. PCI compliant I/O is not supported in these

devices and banks.

3.3-V PCI (1) Single-ended 3.3

LVDS (2) Differential 2.5

RSDS (3) Differential 2.5

Notes to Table 2–4 :

(1) The 3.3-V PCI compliant I/O is supported in Bank 3 of the 5M1270Z and 5M2210Z devices.

(2) MAX V devices only support emulated LVDS output using a three resistor network (LVDS_E_3R).

(3) MAX V devices only support emulated RSDS output using a three resistor network (RSDS_E_3R).

Figure 2–22. I/O Banks for 5M40Z, 5M80Z, 5M160Z, 5M240Z, and 5M570Z Devices (Note 1), (2)

Notes to Figure 2–22:

(1) Figure 2–22 is a top view of the silicon die.

(2) Figure 2–22 is a graphical representation only. Refer to the pin list and the Quartus II software for exact pin locations.

(3) This I/O standard is not supported in Bank 1.

(4) Emulated LVDS output using a three resistor network (LVDS_E_3R).

(5) Emulated RSDS output using a three resistor network (RSDS_E_3R).

Table 2–4. MAX V I/O Standards (Part 2 of 2)

I/O Standard Type Output Supply Voltage (VCCIO)

(V)

All I/O Banks Support

3.3-V LVTTL/LVCMOS,

2.5-V LVTTL/LVCMOS,

1.8-V LVTTL/LVCMOS,

1.5-V LVCMOS,

1.2-V

LVDS (4)

RSDS (5)

LVCMOS (3),

I/O Bank 2

I/O Bank 1

Chapter 2: MAX V Architecture 2–31

I/O Structure

December 2010 Altera Corporation MAX V Device Handbook

The 5M1270Z and 5M2210Z devices support four I/O banks, as shown in Figure 2–23.

Each of these banks support all of the LVTTL, LVCMOS, LVDS, and RSDS standards

shown in Table 2–4. PCI compliant I/O is supported in Bank 3. Bank 3 supports the

PCI clamping diode on inputs and PCI drive compliance on outputs. You must use

Bank 3 for designs requiring PCI compliant I/O pins. The Quartus II software

automatically places I/O pins in this bank if assigned with the PCI I/O standard.

Each I/O bank has dedicated VCCIO pins that determine the voltage standard support

in that bank. A single device can support 1.2-V, 1.5-V, 1.8-V, 2.5-V, and 3.3-V interfaces;

each individual bank can support a different standard. Each I/O bank can support

multiple standards with the same VCCIO

for input and output pins. For example, when

VCCIO is 3.3 V, Bank 3 can support LVTTL, LVCMOS, and 3.3-V PCI. VCCIO powers

both the input and output buffers in MAX V devices.

The JTAG pins for MAX V devices are dedicated pins that cannot be used as regular

I/O pins. The pins

TMS

TDI

TDO

, and

TCK

support all the I/O standards shown in

Table 2–4 on page 2–29 except for PCI and 1.2-V LVCMOS. These pins reside in Bank 1

for all MAX V devices and their I/O standard support is controlled by the VCCIO

setting for Bank 1.

Figure 2–23. I/O Banks for 5M1270Z and 5M2210Z Devices (Note 1), (2)

Notes to Figure 2–23:

(1) Figure 2–23 is a top view of the silicon die.

(2) Figure 2–23 is a graphical representation only. Refer to the pin list and the Quartus II software for exact pin locations.

(3) This I/O standard is not supported in Bank 1.

(4) Emulated LVDS output using a three resistor network (LVDS_E_3R).

(5) Emulated RSDS output using a three resistor network (RSDS_E_3R).

I/O Bank 2

I/O Bank 3

I/O Bank 4

I/O Bank 1

Also Supports

the 3.3-V PCI

I/O Standard

All I/O Banks Support

3.3-V LVTTL/LVCMOS,

2.5-V LVTTL/LVCMOS,

1.8-V LVTTL/LVCMOS,

1.5-V LVCMOS,

1.2-V LVCMOS (3),

LVDS (4),

RSDS(5)

2–32 Chapter 2: MAX V Architecture

I/O Structure

MAX V Device Handbook December 2010 Altera Corporation

PCI Compliance

The MAX V 5M1270Z and 5M2210Z devices are compliant with PCI applications as

well as all 3.3-V electrical specifications in the PCI Local Bus Specification Revision 2.2.

These devices are also large enough to support PCI intellectual property (IP) cores.

Table 2–5 shows the MAX V device speed grades that meet the PCI timing

specifications.

LVDS and RSDS Channels

The MAX V device supports emulated LVDS and RSDS outputs on both row and

column I/O banks. You can configure the rows and columns as emulated LVDS or

RSDS output buffers that use two single-ended output buffers with three external

resistor networks.

Schmitt Trigger

The input buffer for each MAX V device I/O pin has an optional Schmitt trigger

setting for the 3.3-V and 2.5-V standards. The Schmitt trigger allows input buffers to

respond to slow input edge rates with a fast output edge rate. Most importantly,

Schmitt triggers provide hysteresis on the input buffer, preventing slow-rising noisy

input signals from ringing or oscillating on the input signal driven into the logic array.

This provides system noise tolerance on MAX V inputs, but adds a small, nominal

input delay.

The JTAG input pins (

TMS

TCK

, and

TDI

) have Schmitt trigger buffers that are always

enabled.

1The

TCK

input is susceptible to high pulse glitches when the input signal fall time is

greater than 200 ns for all I/O standards.

Table 2–5. 3.3-V PCI Electrical Specifications and PCI Timing Support for MAX V Devices

Device 33-MHz PCI

5M1270Z All Speed Grades

5M2210Z All Speed Grades

Table 2–6. LVDS and RSDS Channels supported in MAX V Devices (Note 1)

Device 64 MBGA 64 EQFP 68 MBGA 100 TQFP 100 MBGA 144 TQFP 256 FBGA 324 FBGA

5M40Z 10 eTx 20 eTx — — — — — —

5M80Z 10 eTx 20 eTx 20 eTx 33 eTx — — — —

5M160Z — 20 eTx 20 eTx 33 eTx 33 eTx — — —

5M240Z — — 20 eTx 33 eTx 33 eTx 49 eTx — —

5M570Z — — — 28 eTx 28 eTx 49 eTx 75 eTx —

5M1270Z — — — — — 42 eTx 90 eTx 115 eTx

5M2210Z — — — — — — 83 eTx 115 eTx

Note to Tab le 2 –6 :

(1) eTx = emulated LVDS output buffers (LVDS_E_3R) or emulated RSDS output buffers (RSDS_E_3R).

Chapter 2: MAX V Architecture 2–33

I/O Structure

December 2010 Altera Corporation MAX V Device Handbook

Output Enable Signals

Each MAX V IOE output buffer supports output enable signals for tri-state control.

The output enable signal can originate from the

GCLK[3..0]

global signals or from the

MultiTrack interconnect. The MultiTrack interconnect routes output enable signals

and allows for a unique output enable for each output or bidirectional pin.

MAX V devices also provide a chip-wide output enable pin (

DEV_OE

) to control the

output enable for every output pin in the design. An option set before compilation in

the Quartus II software controls this pin. This chip-wide output enable uses its own

routing resources and does not use any of the four global resources. If this option is

turned on, all outputs on the chip operate normally when

DEV_OE

is asserted. When

the pin is deasserted, all outputs are tri-stated. If this option is turned off, the

DEV_OE

pin is disabled when the device operates in user mode and is available as a user I/O

pin.

Programmable Drive Strength

The output buffer for each MAX V device I/O pin has two levels of programmable

drive strength control for each of the LVTTL and LVCMOS I/O standards.

Programmable drive strength provides system noise reduction control for high

performance I/O designs. Although a separate slew-rate control feature exists, using

the lower drive strength setting provides signal slew-rate control to reduce system

noise and signal overshoot without the large delay adder associated with the

slew-rate control feature. Table 2–7 lists the possible settings for the I/O standards

with drive strength control. The Quartus II software uses the maximum current

strength as the default setting. The PCI I/O standard is always set at 20 mA with no

alternate setting.

1The programmable drive strength feature can be used simultaneously with the

slew-rate control feature.

Table 2–7. Programmable Drive Strength (Note 1)

I/O Standard IOH/IOL Current Strength Setting (mA)

3.3-V LVTTL 16

3.3-V LVCMOS 8

2.5-V LVTTL/LVCMOS 14

1.8-V LVTTL/LVCMOS 6

1.5-V LVCMOS 4

1.2-V LVCMOS 3

Note to Tab le 2 –7 :

(1) The IOH current strength numbers shown are for a condition of a VOUT = VOH minimum, where the VOH

minimum is specified by the I/O standard. The IOL current strength numbers shown are for a condition of a

VOUT = VOL maximum, where the VOL maximum is specified by the I/O standard. For 2.5-V LVTTL/LVCMOS,

the IOH condition is VOUT = 1.7 V and the IOL condition is VOUT = 0.7 V.

2–34 Chapter 2: MAX V Architecture

I/O Structure

MAX V Device Handbook December 2010 Altera Corporation

Slew-Rate Control

The output buffer for each MAX V device I/O pin has a programmable output

slew-rate control 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 output delay to rising and falling

edges. The lower the voltage standard (for example, 1.8-V LVTTL) the larger the

output delay when slow slew is enabled. Each I/O pin has an individual slew-rate

control, allowing you to specify the slew rate on a pin-by-pin basis. The slew-rate

control affects both the rising and falling edges. If no slew-rate control is specified, the

Quartus II software defaults to a fast slew rate.

1The slew-rate control feature can be used simultaneously with the programmable

drive strength feature.

Open-Drain Output

MAX V 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 (for example, interrupt and write enable signals) that can be asserted

by any of several devices. This output can also provide an additional wired-OR plane.

Programmable Ground Pins

Each unused I/O pin on MAX V devices can be used as an additional ground pin.

This programmable ground feature does not require the use of the associated LEs in

the device. In the Quartus II software, unused pins can be set as programmable GND

on a global default basis or they can be individually assigned. Unused pins also have

the option of being set as tri-stated input pins.

Bus-Hold

Each MAX V device I/O pin provides an optional bus-hold feature. The bus-hold

circuitry can hold the signal on an I/O pin at its last-driven state. Because the bus-

hold feature holds the last-driven state of the pin until the next input signal is present,

an external pull-up or pull-down resistor is not necessary to hold a signal level when

the bus is tri-stated.

The bus-hold circuitry also pulls un-driven pins away from the input threshold

voltage where noise can cause unintended high-frequency switching. You can select

this feature individually for each I/O pin. The bus-hold output will drive no higher

than VCCIO to prevent overdriving signals. If the bus-hold feature is enabled, the

device cannot use the programmable pull-up option.

The bus-hold circuitry is only active after the device has fully initialized. The bus-hold

circuit captures the value on the pin present at the moment user mode is entered.

Chapter 2: MAX V Architecture 2–35

I/O Structure

December 2010 Altera Corporation MAX V Device Handbook

Programmable Pull-Up Resistor

Each MAX V device I/O pin provides an optional programmable pull-up resistor

during user mode. If you enable this feature for an I/O pin, the pull-up resistor holds

the output to the VCCIO level of the output pin’s bank.

1The programmable pull-up resistor feature should not be used at the same time as the

bus-hold feature on a given I/O pin.

1The programmable pull-up resistor is active during power-up, ISP, and if the device is

unprogrammed.

Programmable Input Delay

The MAX V IOE includes a programmable input delay that is activated to ensure zero

hold times. A path where a pin directly drives a register, with minimal routing

between the two, may require the delay to ensure zero hold time. However, a path

where a pin drives a register through long routing or through combinational logic

may not require the delay to achieve a zero hold time. The Quartus II software uses

this delay to ensure zero hold times when needed.

MultiVolt I/O Interface

The MAX V architecture supports the MultiVolt I/O interface feature, which allows

MAX V devices in all packages to interface with systems of different supply voltages.

The devices have one set of

VCC

pins for internal operation (VCCINT), and up to four

sets for input buffers and I/O output driver buffers (VCCIO), depending on the

number of I/O banks available in the devices where each set of

VCCIO

pins powers one

I/O bank. The 5M40Z, 5M80Z, 5M160Z, 5M240Z, and 5M570Z devices each have two

I/O banks while the 5M1270Z and 5M2210Z devices each have four I/O banks.

Connect

VCCIO

pins to either a 1.2-, 1.5-, 1.8-, 2.5-, or 3.3-V power supply, depending

on the output requirements. The output levels are compatible with systems of the

same voltage as the power supply (that is, when

VCCIO

pins are connected to a 1.5-V

power supply, the output levels are compatible with 1.5-V systems). When

VCCIO

pins

are connected to a 3.3-V power supply, the output high is 3.3 V and is compatible with

3.3-V or 5.0-V systems. Table 2–8 summarizes MAX V MultiVolt I/O support.

Table 2–8. MultiVolt I/O Support in MAX V Devices (Part 1 of 2) (Note 1)

VCCIO (V)

Input Signal Output Signal

1.2 V 1.5 V 1.8 V 2.5 V 3.3 V 5.0 V 1.2 V 1.5 V 1.8 V 2.5 V 3.3 V 5.0 V

1.2 v—————v—————

1.5 —vvvv—vv————

1.8 —vvvv—v (2) v (2) v———

2.5 ———vv—v (3) v (3) v (3) v——

2–36 Chapter 2: MAX V Architecture

Document Revision History

MAX V Device Handbook December 2010 Altera Corporation

Document Revision History

Table 2–9 lists the revision history for this chapter.

3.3 ———v (4) vv (5) v (6) v (6) v (6) v (6) vv (7)

Notes to Ta ble 2– 8 :

(1) To drive inputs higher than VCCIO but less than 4.0 V including the overshoot, disable the I/O clamp diode. However, to drive 5.0-V signals to

the device, enable the I/O clamp diode to prevent VI from rising above 4.0 V. Use an external diode if the I/O pin does not support the clamp

diode.

(2) When VCCIO = 1.8 V, a MAX V device can drive a 1.2-V or 1.5-V device with 1.8-V tolerant inputs.

(3) When VCCIO = 2.5 V, a MAX V device can drive a 1.2-V, 1.5-V, or 1.8-V device with 2.5-V tolerant inputs.

(4) When VCCIO = 3.3 V and a 2.5-V input signal feeds an input pin, the VCCIO supply current will be slightly larger than expected.

(5) MAX V devices can be 5.0-V tolerant with the use of an external resistor and the internal I/O clamp diode on the 5M1270Z and 5M2210Z devices.

Use an external clamp diode if the internal clamp diode is not available.

(6) When VCCIO = 3.3 V, a MAX V device can drive a 1.2-V, 1.5-V, 1.8-V, or 2.5-V device with 3.3-V tolerant inputs.

(7) When VCCIO = 3.3 V, a MAX V device can drive a device with 5.0-V TTL inputs but not 5.0-V CMOS inputs. For 5.0-V CMOS, open-drain setting

with internal I/O clamp diode (available only on 5M1270Z and 5M2210Z devices) and external resistor is required. Use an external clamp diode

if the internal clamp diode is not available.

Table 2–8. MultiVolt I/O Support in MAX V Devices (Part 2 of 2) (Note 1)

VCCIO (V)

Input Signal Output Signal

1.2 V 1.5 V 1.8 V 2.5 V 3.3 V 5.0 V 1.2 V 1.5 V 1.8 V 2.5 V 3.3 V 5.0 V

Table 2–9. Document Revision History

Date Version Changes

December 2010 1.0 Initial release.

MAX V Device Handbook

May 2011

MV51003-1.2

and/or trademarks of Altera Corporation in the U.S. and other countries. All other trademarks and service marks are the property of their respective holders as described at

www.altera.com/common/legal.html. 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. 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.

3. DC and Switching Characteristics for

MAX V Devices

This chapter covers the electrical and switching characteristics for MAX®V devices.

Electrical characteristics include operating conditions and power consumptions. This

chapter also describes the timing model and specifications.

You must consider the recommended DC and switching conditions described in this

chapter to maintain the highest possible performance and reliability of the MAX V

devices.

This chapter contains the following sections:

■“Operating Conditions” on page 3–1

■“Power Consumption” on page 3–10

■“Timing Model and Specifications” on page 3–10

Operating Conditions

Table 3 –1 through Table 3–15 on page 3–9 list information about absolute maximum

ratings, recommended operating conditions, DC electrical characteristics, and other

specifications for MAX V devices.

Absolute Maximum Ratings

Table 3 –1 lists the absolute maximum ratings for the MAX V device family.

Table 3–1. Absolute Maximum Ratings for MAX V Devices (Note 1), (2)

Symbol Parameter Conditions Minimum Maximum Unit

VCCINT Internal supply voltage With respect to ground –0.5 2.4 V

VCCIO I/O supply voltage — –0.5 4.6 V

VIDC input voltage — –0.5 4.6 V

IOUT DC output current, per pin — –25 25 mA

TSTG Storage temperature No bias –65 150 °C

TAMB Ambient temperature Under bias (3) –65 135 °C

TJJunction temperature TQFP and BGA packages

under bias — 135 °C

Notes to Table 3–1:

(1) For more information, refer to the Operating Requirements for Altera Devices Data Sheet.

(2) Conditions beyond those listed in Table 3–1 may cause permanent damage to a device. Additionally, device operation at the absolute maximum

ratings for extended periods of time may have adverse affects on the device.

(3) For more information about “under bias” conditions, refer to Table 3–2.

May 2011

MV51003-1.2

3–2 Chapter 3: DC and Switching Characteristics for MAX V Devices

Operating Conditions

MAX V Device Handbook May 2011 Altera Corporation

Recommended Operating Conditions

Table 3 –2 lists recommended operating conditions for the MAX V device family.

Table 3–2. Recommended Operating Conditions for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCINT (1) 1.8-V supply voltage for internal logic and

in-system programming (ISP) MAX V devices 1.71 1.89 V

VCCIO (1)

Supply voltage for I/O buffers, 3.3-V

operation — 3.00 3.60 V

Supply voltage for I/O buffers, 2.5-V

operation — 2.375 2.625 V

Supply voltage for I/O buffers, 1.8-V

operation — 1.71 1.89 V

Supply voltage for I/O buffers, 1.5-V

operation — 1.425 1.575 V

Supply voltage for I/O buffers, 1.2-V

operation — 1.14 1.26 V

VIInput voltage (2), (3), (4) –0.5 4.0 V

VOOutput voltage — 0 VCCIO V

TJOperating junction temperature

Commercial range 0 85 °C

Industrial range –40 100 °C

Extended range (5) –40 125 °C

Notes to Table 3–2:

(1) MAX V device ISP and/or user flash memory (UFM) programming using JTAG or logic array is not guaranteed outside the recommended

operating conditions (for example, if brown-out occurs in the system during a potential write/program sequence to the UFM, Altera recommends

that you read back the UFM contents and verify it against the intended write data).

(2) The minimum DC input is –0.5 V. During transitions, the inputs may undershoot to –2.0 V for input currents less than 100 mA and periods

shorter than 20 ns.

(3) During transitions, the inputs may overshoot to the voltages shown below based on the input duty cycle. The DC case is equivalent to 100%

duty cycle. For more information about 5.0-V tolerance, refer to the Using MAX V Devices in Multi-Voltage Systems chapter.

VIN Max. Duty Cycle

4.0 V 100% (DC)

4.1 V 90%

4.2 V 50%

4.3 V 30%

4.4 V 17%

4.5 V 10%

(4) All pins, including the clock, I/O, and JTAG pins, may be driven before VCCINT and VCCIO are powered.

(5) For the extended temperature range of 100 to 125°C, MAX V UFM programming (erase/write) is only supported using the JTAG interface. UFM

programming using the logic array interface is not guaranteed in this range.

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–3

Operating Conditions

May 2011 Altera Corporation MAX V Device Handbook

Programming/Erasure Specifications

Table 3 –3 lists the programming/erasure specifications for the MAX V device family.

DC Electrical Characteristics

Table 3 –4 lists DC electrical characteristics for the MAX V device family.

Table 3–3. Programming/Erasure Specifications for MAX V Devices

Parameter Block Minimum Typical Maximum Unit

Erase and reprogram cycles UFM — — 1000 (1) Cycles

Configuration flash memory (CFM) — — 100 Cycles

Note to Table 3–3:

(1) This value applies to the commercial grade devices. For the industrial grade devices, the value is 100 cycles.

Table 3–4. DC Electrical Characteristics for MAX V Devices (Note 1) (Part 1 of 2)

Symbol Parameter Conditions Minimum Typical Maximum Unit

IIInput pin leakage current VI = VCCIO max to 0 V (2) –10 — 10 µA

IOZ

Tri-stated I/O pin leakage

current VO = VCCIO max to 0 V (2) –10 — 10 µA

ICCSTANDBY

VCCINT supply current

(standby) (3)

5M40Z, 5M80Z, 5M160Z, and

5M240Z (Commercial grade)

(4), (5)

—2590µA

5M240Z (Commercial grade)

(6) —2796µA

5M40Z, 5M80Z, 5M160Z, and

5M240Z (Industrial grade)

(5), (7)

— 25 139 µA

5M240Z (Industrial grade) (6) — 27 152 µA

5M570Z (Commercial grade)

(4) —2796µA

5M570Z (Industrial grade) (7) — 27 152 µA

5M1270Z and 5M2210Z — 2 — mA

VSCHMITT (8) Hysteresis for Schmitt

trigger input (9)

VCCIO = 3.3 V — 400 — mV

VCCIO = 2.5 V — 190 — mV

ICCPOWERUP

VCCINT supply current

during power-up (10) MAX V devices — — 40 mA

RPULLUP

Value of I/O pin pull-up

resistor during user

mode and ISP

VCCIO = 3.3 V (11) 5—25k

VCCIO = 2.5 V (11) 10 — 40 k

VCCIO = 1.8 V (11) 25 — 60 k

VCCIO = 1.5 V (11) 45 — 95 k

VCCIO = 1.2 V (11) 80 — 130 k

3–4 Chapter 3: DC and Switching Characteristics for MAX V Devices

Operating Conditions

MAX V Device Handbook May 2011 Altera Corporation

IPULLUP

I/O pin pull-up resistor

current when I/O is

unprogrammed

— — — 300 µA

CIO

Input capacitance for

user I/O pin ———8pF

CGCLK

Input capacitance for

dual-purpose GCLK/user

I/O pin

———8pF

Notes to Table 3–4:

(1) Typical values are for TA = 25°C, VCCINT = 1.8 V and VCCIO = 1.2, 1.5, 1.8, 2.5, or 3.3 V.

(2) This value is specified for normal device operation. The value may vary during power-up. This applies to all VCCIO settings (3.3, 2.5, 1.8, 1.5,

and 1.2 V).

(3) VI = ground, no load, and no toggling inputs.

(4) Commercial temperature ranges from 0°C to 85°C with the maximum current at 85°C.

(5) Not applicable to the T144 package of the 5M240Z device.

(6) Only applicable to the T144 package of the 5M240Z device.

(7) Industrial temperature ranges from –40°C to 100°C with the maximum current at 100°C.

(8) This value applies to commercial and industrial range devices. For extended temperature range devices, the VSCHMITT typical value is 300 mV

for VCCIO = 3.3 V and 120 mV for VCCIO = 2.5 V.

(9) The

TCK

input is susceptible to high pulse glitches when the input signal fall time is greater than 200 ns for all I/O standards.

(10) This is a peak current value with a maximum duration of tCONFIG time.

(11) Pin pull-up resistance values will lower if an external source drives the pin higher than VCCIO.

Table 3–4. DC Electrical Characteristics for MAX V Devices (Note 1) (Part 2 of 2)

Symbol Parameter Conditions Minimum Typical Maximum Unit

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–5

Operating Conditions

May 2011 Altera Corporation MAX V Device Handbook

Output Drive Characteristics

Figure 3–1 shows the typical drive strength characteristics of MAX V devices.

I/O Standard Specifications

Table 3 –5 through Table 3–13 on page 3–8 list the I/O standard specifications for the

MAX V device family.

Figure 3–1. Output Drive Characteristics of MAX V Devices (Note 1)

Notes to Figure 3–1:

(1) The DC output current per pin is subject to the absolute maximum rating of Table 3–1 on page 3–1.

(2) 1.2-V VCCIO is only applicable to the maximum drive strength.

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

Voltage (V)

Typical I

Output Current (mA)

3.3-V VCCIO

2.5-V VCCIO

1.8-V VCCIO

1.5-V VCCIO

(Minimum Drive Strength)

MAX V Output Drive I

Characteristics

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

Voltage (V)

Typical I

Output Current (mA)

3.3-V VCCIO

2.5-V VCCIO

1.8-V VCCIO

1.5-V VCCIO

(Minimum Drive Strength)

MAX V Output Drive I

Characteristics

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

Voltage (V)

Typical I

Output Current (mA)

3.3-V VCCIO

2.5-V VCCIO

1.8-V VCCIO

1.5-V VCCIO

(Maximum Drive Strength)

MAX V Output Drive I

Characteristics

1.2-V VCCIO (2)

MAX V Output Drive I

Characteristics

(Maximum Drive Strength)

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5

Voltage (V)

Typical I

Output Current (mA)

3.3-V VCCIO

2.5-V VCCIO

1.8-V VCCIO

1.5-V VCCIO

1.2-V VCCIO (2)

Table 3–5. 3.3-V LVTTL Specifications for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCIO I/O supply voltage — 3.0 3.6 V

VIH High-level input voltage — 1.7 4.0 V

VIL Low-level input voltage — –0.5 0.8 V

VOH High-level output voltage IOH = –4 mA (1) 2.4 — V

VOL Low-level output voltage IOL = 4 mA (1) —0.45V

Note to Table 3–5:

(1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the

MAX V Device Architecture chapter.

3–6 Chapter 3: DC and Switching Characteristics for MAX V Devices

Operating Conditions

MAX V Device Handbook May 2011 Altera Corporation

Table 3–6. 3.3-V LVCMOS Specifications for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCIO I/O supply voltage — 3.0 3.6 V

VIH High-level input voltage — 1.7 4.0 V

VIL Low-level input voltage — –0.5 0.8 V

VOH High-level output voltage VCCIO = 3.0,

IOH = –0.1 mA (1) VCCIO – 0.2 — V

VOL Low-level output voltage VCCIO = 3.0,

IOL = 0.1 mA (1) —0.2V

Note to Table 3–6:

(1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the

MAX V Device Architecture chapter.

Table 3–7. 2.5-V I/O Specifications for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCIO I/O supply voltage — 2.375 2.625 V

VIH High-level input voltage — 1.7 4.0 V

VIL Low-level input voltage — –0.5 0.7 V

VOH High-level output voltage

IOH = –0.1 mA (1) 2.1 — V

IOH = –1 mA (1) 2.0 — V

IOH = –2 mA (1) 1.7 — V

VOL Low-level output voltage

IOL = 0.1 mA (1) —0.2V

IOL = 1 mA (1) —0.4V

IOL = 2 mA (1) —0.7V

Note to Table 3–7:

(1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the

MAX V Device Architecture chapter.

Table 3–8. 1.8-V I/O Specifications for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCIO I/O supply voltage — 1.71 1.89 V

VIH High-level input voltage — 0.65 × VCCIO 2.25 (2) V

VIL Low-level input voltage — –0.3 0.35 × VCCIO V

VOH High-level output voltage IOH = –2 mA (1) VCCIO – 0.45 — V

VOL Low-level output voltage IOL = 2 mA (1) —0.45V

Notes to Table 3–8:

(1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the

MAX V Device Architecture chapter.

(2) This maximum VIH reflects the JEDEC specification. The MAX V input buffer can tolerate a VIH maximum of 4.0, as specified by the VI parameter

in Table 3–2 on page 3–2.

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–7

Operating Conditions

May 2011 Altera Corporation MAX V Device Handbook

Table 3–9. 1.5-V I/O Specifications for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCIO I/O supply voltage — 1.425 1.575 V

VIH High-level input voltage — 0.65 × VCCIO VCCIO + 0.3 (2) V

VIL Low-level input voltage — –0.3 0.35 × VCCIO V

VOH High-level output voltage IOH = –2 mA (1) 0.75 × VCCIO —V

VOL Low-level output voltage IOL = 2 mA (1) —0.25 × V

CCIO V

Notes to Table 3–9:

(1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the

MAX V Device Architecture chapter.

(2) This maximum VIH reflects the JEDEC specification. The MAX V input buffer can tolerate a VIH maximum of 4.0, as specified by the VI parameter

in Table 3–2 on page 3–2.

Table 3–10. 1.2-V I/O Specifications for MAX V Devices

Symbol Parameter Conditions Minimum Maximum Unit

VCCIO I/O supply voltage — 1.14 1.26 V

VIH High-level input voltage — 0.8 × VCCIO VCCIO +0.3 V

VIL Low-level input voltage — –0.3 0.25 × VCCIO V

VOH High-level output voltage IOH = –2 mA (1) 0.75 × VCCIO —V

VOL Low-level output voltage IOL = 2 mA (1) —0.25×V

CCIO V

Note to Table 3–10:

(1) This specification is supported across all the programmable drive strength settings available for this I/O standard, as shown in the

MAX V Device Architecture chapter.

Table 3–11. 3.3-V PCI Specifications for MAX V Devices (Note 1)

Symbol Parameter Conditions Minimum Typical Maximum Unit

VCCIO I/O supply voltage — 3.0 3.3 3.6 V

VIH High-level input voltage — 0.5 × VCCIO —V

CCIO + 0.5 V

VIL Low-level input voltage — –0.5 — 0.3 × VCCIO V

VOH High-level output voltage IOH = –500 µA 0.9 × VCCIO ——V

VOL Low-level output voltage IOL = 1.5 mA — — 0.1 × VCCIO V

Note to Table 3–11:

(1) 3.3-V PCI I/O standard is only supported in Bank 3 of the 5M1270Z and 5M2210Z devices.

Table 3–12. LVDS Specifications for MAX V Devices (Note 1)

Symbol Parameter Conditions Minimum Typical Maximum Unit

VCCIO I/O supply voltage — 2.375 2.5 2.625 V

VOD Differential output voltage swing — 247 — 600 mV

VOS Output offset voltage — 1.125 1.25 1.375 V

Note to Table 3–12:

(1) Supports emulated LVDS output using a three-resistor network (LVDS_E_3R).

3–8 Chapter 3: DC and Switching Characteristics for MAX V Devices

Operating Conditions

MAX V Device Handbook May 2011 Altera Corporation

Bus Hold Specifications

Table 3 –14 lists the bus hold specifications for the MAX V device family.

Table 3–13. RSDS Specifications for MAX V Devices (Note 1)

Symbol Parameter Conditions Minimum Typical Maximum Unit

VCCIO I/O supply voltage — 2.375 2.5 2.625 V

VOD Differential output voltage swing — 247 — 600 mV

VOS Output offset voltage — 1.125 1.25 1.375 V

Note to Table 3–13:

(1) Supports emulated RSDS output using a three-resistor network (RSDS_E_3R).

Table 3–14. Bus Hold Specifications for MAX V Devices

Parameter Conditions

VCCIO Level

Unit1.2 V 1.5 V 1.8 V 2.5 V 3.3 V

Min Max Min Max Min Max Min Max Min Max

Low sustaining

current VIN > VIL (maximum) 10 — 20 — 30 — 50 — 70 — µA

High sustaining

current VIN < VIH (minimum) –10 — –20 — –30 — –50 — –70 — µA

Low overdrive

current 0 V < VIN < VCCIO —130—160—200—300—500µA

High overdrive

current 0 V < VIN < VCCIO — –130 — –160 — –200 — –300 — –500 µA

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–9

Operating Conditions

May 2011 Altera Corporation MAX V Device Handbook

Power-Up Timing

Table 3 –15 lists the power-up timing characteristics for the MAX V device family.

Table 3–15. Power-Up Timing for MAX V Devices

Symbol Parameter Device Temperature Range Min Typ Max Unit

tCONFIG

The amount of time from

when minimum VCCINT is

reached until the device

enters user mode (1)

5M40Z Commercial and industrial — — 200 µs

Extended — — 300 µs

5M80Z Commercial and industrial — — 200 µs

Extended — — 300 µs

5M160Z Commercial and industrial — — 200 µs

Extended — — 300 µs

5M240Z (2) Commercial and industrial — — 200 µs

Extended — — 300 µs

5M240Z (3) Commercial and industrial — — 300 µs

Extended — — 400 µs

5M570Z Commercial and industrial — — 300 µs

Extended — — 400 µs

5M1270Z (4) Commercial and industrial — — 300 µs

Extended — — 400 µs

5M1270Z (5) Commercial and industrial — — 450 µs

Extended — — 500 µs

5M2210Z Commercial and industrial — — 450 µs

Extended — — 500 µs

Notes to Table 3–15:

(1) For more information about power-on reset (POR) trigger voltage, refer to the Hot Socketing and Power-On Reset in MAX V Devices chapter.

(2) Not applicable to the T144 package of the 5M240Z device.

(3) Only applicable to the T144 package of the 5M240Z device.

(4) Not applicable to the F324 package of the 5M1270Z device.

(5) Only applicable to the F324 package of the 5M1270Z device.

3–10 Chapter 3: DC and Switching Characteristics for MAX V Devices

Power Consumption

MAX V Device Handbook May 2011 Altera Corporation

Power Consumption

You can use the Altera® PowerPlay Early Power Estimator and PowerPlay Power

Analyzer to estimate the device power.

fFor more information about these power analysis tools, refer to the PowerPlay Early

Power Estimator for Altera CPLDs User Guide and the PowerPlay Power Analysis chapter

in volume 3 of the Quartus II Handbook.

Timing Model and Specifications

MAX V devices timing can be analyzed with the Altera Quartus®II software, a variety

of industry-standard EDA simulators and timing analyzers, or with the timing model

shown in Figure 3–2.

MAX V devices have predictable internal delays that allow you 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.

You can derive the timing characteristics of any signal path from the timing model

and parameters of a particular device. You can calculate external timing parameters,

which represent pin-to-pin timing delays, as the sum of the internal parameters.

fFor more information, refer to AN629: Understanding Timing in Altera CPLDs.

Figure 3–2. Timing Model for MAX V Devices

I/O Pin

I/O Input Delay

tIN

INPUT

Global Input Delay

tC4

tR4

Output

Delay

tOD

tXZ

tZX

tLOCAL

tGLOB

Logic Element

I/O Pin

tFASTIO

Output Routing

Delay

User

Flash

Memory

From Adjacent LE

To Adjacent LE

Input Routing

Delay

tDL

tLUT

LUT Delay

Delay

tCO

tSU

tPRE

tCLR

Data-In/LUT Chain

Data-Out

tIODR

Output and Output Enable

Data Delay

tIOE

tCOMB

Combinational Path Delay

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–11

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

Preliminary and Final Timing

This section describes the performance, internal, external, and UFM timing

specifications. All specifications are representative of the worst-case supply voltage

and junction temperature conditions.

Timing models can have either preliminary or final status. The Quartus II software

issues an informational message during the design compilation if the timing models

are preliminary. Table 3–16 lists the status of the MAX V device timing models.

Preliminary status means the timing model is subject to change. Initially, timing

numbers are created using simulation results, process data, and other known

parameters. These tests are used to make the preliminary numbers as close to the

actual timing parameters as possible.

Final timing numbers are based on actual device operation and testing. These

numbers reflect the actual performance of the device under the worst-case voltage

and junction temperature conditions.

Performance

Table 3 –17 lists the MAX V device performance for some common designs. All

performance values were obtained with the Quartus II software compilation of

megafunctions.

Table 3–16. Timing Model Status for MAX V Devices

Device Final

5M40Z v

5M80Z v

5M160Z v

5M240Z v

5M570Z v

5M1270Z v

5M2210Z v

Table 3–17. Device Performance for MAX V Devices (Part 1 of 2)

Resource

Used

Design Size and

Function

Resources Used

Performance

Unit

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Mode LEs UFM

Blocks C4 C5, I5 C4 C5, I5

16-bit counter (1) — 16 0 184.1 118.3 247.5 201.1 MHz

64-bit counter (1) — 64 0 83.2 80.5 154.8 125.8 MHz

16-to-1 multiplexer — 11 0 17.4 20.4 8.0 9.3 ns

32-to-1 multiplexer — 24 0 12.5 25.3 9.0 11.4 ns

16-bit

XOR

function — 5 0 9.0 16.1 6.6 8.2 ns

16-bit decoder with

single address line — 5 0 9.2 16.1 6.6 8.2 ns

3–12 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Internal Timing Parameters

Internal timing parameters are specified on a speed grade basis independent of device

density. Table 3–18 through Table 3–25 on page 3–19 list the MAX V device internal

timing microparameters for LEs, input/output elements (IOEs), UFM blocks, and

MultiTrack interconnects.

fFor more information about each internal timing microparameters symbol, refer to

AN629: Understanding Timing in Altera CPLDs.

UFM

512 × 16 None 3 1 10.0 10.0 10.0 10.0 MHz

512 × 16 SPI (2) 37 1 9.7 9.7 8.0 8.0 MHz

512 × 8 Parallel

(3) 73 1 (4) (4) (4) (4) MHz

512 × 16 I2C (3) 142 1 100 (5) 100 (5) 100 (5) 100 (5) kHz

Notes to Table 3–17:

(1) This design is a binary loadable up counter.

(2) This design is configured for read-only operation in Extended mode. Read and write ability increases the number of logic elements (LEs) used.

(3) This design is configured for read-only operation. Read and write ability increases the number of LEs used.

(4) This design is asynchronous.

(5) The I2C megafunction is verified in hardware up to 100-kHz serial clock line rate.

Table 3–17. Device Performance for MAX V Devices (Part 2 of 2)

Resource

Used

Design Size and

Function

Resources Used

Performance

Unit

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Mode LEs UFM

Blocks C4 C5, I5 C4 C5, I5

Table 3–18. LE Internal Timing Microparameters for MAX V Devices (Part 1 of 2)

Symbol Parameter

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

tLUT

LE combinational look-up

table (LUT) delay — 1,215 — 2,247 — 742 — 914 ps

tCOMB Combinational path delay — 243 — 309 — 192 — 236 ps

tCLR LE register clear delay 401 — 545 — 309 — 381 — ps

tPRE LE register preset delay 401 — 545 — 309 — 381 — ps

tSU

LE register setup time

before clock 260 — 321 — 271 — 333 — ps

LE register hold time

after clock 0 —0 —0 —0 —ps

tCO

LE register

clock-to-output delay — 380 — 494 — 305 — 376 ps

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–13

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

tCLKHL

Minimum clock high or

low time 253 — 339 — 216 — 266 — ps

tCRegister control delay — 1,356 — 1,741 — 1,114 — 1,372 ps

Table 3–18. LE Internal Timing Microparameters for MAX V Devices (Part 2 of 2)

Symbol Parameter

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

Table 3–19. IOE Internal Timing Microparameters for MAX V Devices

Symbol Parameter

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

tFASTIO

Data output delay from

adjacent LE to I/O block — 170 — 428 — 207 — 254 ps

tIN

I/O input pad and buffer

delay — 907 — 986 — 920 — 1,132 ps

tGLOB (1)

I/O input pad and buffer

delay used as global

signal pin

— 2,261 — 3,322 — 1,974 — 2,430 ps

tIOE

Internally generated

output enable delay — 530 — 1,410 — 374 — 460 ps

tDL Input routing delay — 318 — 509 — 291 — 358 ps

tOD (2) Output delay buffer and

pad delay — 1,319 — 1,543 — 1,383 — 1,702 ps

tXZ (3) Output buffer disable

delay — 1,045 — 1,276 — 982 — 1,209 ps

tZX (4) Output buffer enable

delay — 1,160 — 1,353 — 1,303 — 1,604 ps

Notes to Table 3–19:

(1) Delay numbers for tGLOB differ for each device density and speed grade. The delay numbers for tGLOB, shown in Table 3–19, are based on a 5M240Z

device target.

(2) For more information about delay adders associated with different I/O standards, drive strengths, and slew rates, refer to Table 3–34 on page 3–24

and Table 3–35 on page 3–25.

(3) For more information about tXZ delay adders associated with different I/O standards, drive strengths, and slew rates, refer to Table 3–22 on

page 3–15 and Table 3–23 on page 3–15.

(4) For more information about tZX delay adders associated with different I/O standards, drive strengths, and slew rates, refer to Table 3–20 on

page 3–14 and Table 3–21 on page 3–14.

3–14 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Table 3 –20 through Table 3–23 list the adder delays for tZX and tXZ microparameters

when using an I/O standard other than 3.3-V LVTTL with 16 mA drive strength.

Table 3–20. tZX IOE Microparameter Adders for Fast Slew Rate for MAX V Devices

Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL 16 mA —0 —0 —0 —0 ps

8 mA — 72 — 74 — 101 — 125 ps

3.3-V LVCMOS 8 mA —0 —0 —0 —0 ps

4 mA — 72 — 74 — 101 — 125 ps

2.5-V LVTTL /

LVCMOS

14 mA — 126 — 127 — 155 — 191 ps

7 mA — 196 — 197 — 545 — 671 ps

1.8-V LVTTL /

LVCMOS

6 mA — 608 — 610 — 721 — 888 ps

3 mA — 681 — 685 — 2012 — 2477 ps

1.5-V LVCMOS 4 mA — 1162 — 1157 — 1590 — 1957 ps

2 mA — 1245 — 1244 — 3269 — 4024 ps

1.2-V LVCMOS 3 mA — 1889 — 1856 — 2860 — 3520 ps

3.3-V PCI 20 mA — 72 — 74 — –18 — –22 ps

LVDS — — 126 — 127 — 155 — 191 ps

RSDS — — 126 — 127 — 155 — 191 ps

Table 3–21. tZX IOE Microparameter Adders for Slow Slew Rate for MAX V Devices

Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL 16 mA — 5,951 — 6,063 — 6,012 — 5,743 ps

8 mA — 6,534 — 6,662 — 8,785 — 8,516 ps

3.3-V LVCMOS 8 mA — 5,951 — 6,063 — 6,012 — 5,743 ps

4 mA — 6,534 — 6,662 — 8,785 — 8,516 ps

2.5-V LVTTL /

LVCMOS

14 mA — 9,110 — 9,237 — 10,072 — 9,803 ps

7 mA — 9,830 — 9,977 — 12,945 — 12,676 ps

1.8-V LVTTL /

LVCMOS

6 mA — 21,800 — 21,787 — 21,185 — 20,916 ps

3 mA — 23,020 — 23,037 — 24,597 — 24,328 ps

1.5-V LVCMOS 4 mA — 39,120 — 39,067 — 34,517 — 34,248 ps

2 mA — 40,670 — 40,617 — 39,717 — 39,448 ps

1.2-V LVCMOS 3 mA — 69,505 — 70,461 — 55,800 — 55,531 ps

3.3-V PCI 20 mA — 6,534 — 6,662 — 35 — 44 ps

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–15

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

Table 3–22. tXZ IOE Microparameter Adders for Fast Slew Rate for MAX V Devices

Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL 16 mA—0—0—0—0 ps

8 mA — –69 — –69 — –74 — –91 ps

3.3-V LVCMOS 8 mA—0—0—0—0 ps

4 mA — –69 — –69 — –74 — –91 ps

2.5-V LVTTL /

LVCMOS

14 mA — –7 — –10 — –46 — –56 ps

7 mA — –66 — –69 — –82 — –101 ps

1.8-V LVTTL /

LVCMOS

6 mA — 45 — 37 — –7 — –8 ps

3 mA — 34 — 25 — 119 — 147 ps

1.5-V LVCMOS 4 mA — 166 — 155 — 339 — 418 ps

2 mA — 190 — 179 — 464 — 571 ps

1.2-V LVCMOS 3 mA — 300 — 283 — 817 — 1,006 ps

3.3-V PCI 20 mA — –69 — –69 — 80 — 99 ps

LVDS — — –7 — –10 — –46 — –56 ps

RSDS — — –7 — –10 — –46 — –56 ps

Table 3–23. tXZ IOE Microparameter Adders for Slow Slew Rate for MAX V Devices

Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL 16 mA — 171 — 174 — 73 — –132 ps

8 mA — 112 — 116 — 758 — 553 ps

3.3-V LVCMOS 8 mA — 171 — 174 — 73 — –132 ps

4 mA — 112 — 116 — 758 — 553 ps

2.5-V LVTTL /

LVCMOS

14 mA — 213 — 213 — 32 — –173 ps

7 mA — 166 — 166 — 714 — 509 ps

1.8-V LVTTL /

LVCMOS

6 mA — 441 — 438 — 96 — –109 ps

3 mA — 496 — 494 — 963 — 758 ps

1.5-V LVCMOS 4 mA — 765 — 755 — 238 — 33 ps

2 mA — 903 — 897 — 1,319 — 1,114 ps

1.2-V LVCMOS 3 mA — 1,159 — 1,130 — 400 — 195 ps

3.3-V PCI 20 mA — 112 — 116 — 303 — 373 ps

3–16 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

1The default slew rate setting for MAX V devices in the Quartus II design software is

“fast”.

Table 3–24. UFM Block Internal Timing Microparameters for MAX V Devices (Part 1 of 2)

Symbol Parameter

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

tACLK

Address register clock

period 100 — 100 — 100 — 100 — ns

tASU

Address register shift

signal setup to address

20—20—20—20—ns

tAH

Address register shift

signal hold to address

20—20—20—20—ns

tADS

Address register data in

setup to address register

clock

20—20—20—20—ns

tADH

Address register data in

hold from address

20—20—20—20—ns

tDCLK Data register clock period 100 — 100 — 100 — 100 — ns

tDSS

Data register shift signal

setup to data register

clock

60—60—60—60—ns

tDSH

Data register shift signal

hold from data register

clock

20—20—20—20—ns

tDDS

Data register data in

setup to data register

clock

20—20—20—20—ns

tDDH

Data register data in hold

from data register clock 20—20—20—20—ns

tDP

Program signal to data

clock hold time 0—0—0—0—ns

tPB

Maximum delay between

program rising edge to

UFM

busy

signal rising

edge

— 960 — 960 — 960 — 960 ns

tBP

Minimum delay allowed

from UFM

busy

signal

going low to program

signal going low

20—20—20—20—ns

tPPMX

Maximum length of

busy

pulse during a program — 100 — 100 — 100 — 100 µs

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–17

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

tAE

Minimum

erase

signal

to address clock hold

time

0—0—0—0 —ns

tEB

Maximum delay between

the

erase

rising edge to

the UFM

busy

signal

rising edge

— 960 — 960 — 960 — 960 ns

tBE

Minimum delay allowed

from the UFM

busy

signal going low to

erase

signal going low

20—20—20—20—ns

tEPMX

Maximum length of

busy

pulse during an erase — 500 — 500 — 500 — 500 ms

tDCO

Delay from data register

clock to data register

output

—5—5—5—5ns

tOE

Delay from

OSC_ENA

signal reaching UFM to

rising clock of

OSC

leaving the UFM

180 — 180 — 180 — 180 — ns

tRA

Maximum read access

time —65—65—65—65ns

tOSCS

Maximum delay between

the

OSC_ENA

rising edge

to the

erase/program

signal rising edge

250 — 250 — 250 — 250 — ns

tOSCH

Minimum delay allowed

from the

erase/program

signal

going low to

OSC_ENA

signal going low

250 — 250 — 250 — 250 — ns

Table 3–24. UFM Block Internal Timing Microparameters for MAX V Devices (Part 2 of 2)

Symbol Parameter

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3–18 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Figure 3–3 through Figure 3–5 show the read, program, and erase waveforms for

UFM block timing parameters listed in Table 3–24.

Figure 3–3. UFM Read Waveform

DCO

DCLK

DSS

DSH

ADH

ADS

ASU

ACLK

ARShft

ARClk

ARDin

DRShft

DRClk

DRDin

DRDout

Program

Erase

Busy

16 Data Bits

9 Address Bits

OSC_ENA

Figure 3–4. UFM Program Waveform

ADS

ASU

ACLK

ADH

DDS

DCLK

DSS

DSH

DDH

PPMX

OSCS

OSCH

ARShft

ARClk

ARDin

DRShft

DRClk

DRDin

DRDout

Program

Erase

Busy

16 Data Bits

9 Address Bits

OSC_ENA

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–19

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

External Timing Parameters

External timing parameters are specified by device density and speed grade. All

external I/O timing parameters shown are for the 3.3-V LVTTL I/O standard with the

maximum drive strength and fast slew rate. For external I/O timing using standards

other than LVTTL or for different drive strengths, use the I/O standard input and

output delay adders in Table 3–32 on page 3–23 through Table 3–36 on page 3–25.

fFor more information about each external timing parameters symbol, refer to

AN629: Understanding Timing in Altera CPLDs.

Figure 3–5. UFM Erase Waveform

ARShft

ARClk

ARDin

DRShft

DRClk

DRDin

DRDout

Program

Erase

Busy

9 Address Bits

tASU tACLK tAH

tADH

tADS

tEB

tEPMX

tOSCS tOSCH

OSC_ENA

tBE

Table 3–25. Routing Delay Internal Timing Microparameters for MAX V Devices

Routing

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

tC4 — 860 — 1,973 — 561 — 690 ps

tR4 — 655 — 1,479 — 445 — 548 ps

tLOCAL — 1,143 — 2,947 — 731 — 899 ps

3–20 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Table 3 –26 lists the external I/O timing parameters for the 5M40Z, 5M80Z, 5M160Z,

and 5M240Z devices.

Table 3 –27 lists the external I/O timing parameters for the T144 package of the

5M240Z device.

Table 3–26. Global Clock External I/O Timing Parameters for the 5M40Z, 5M80Z, 5M160Z, and 5M240Z Devices

(Note 1), (2)

Symbol Parameter Condition

C4 C5, I5

Unit

Min Max Min Max

tPD1 Worst case pin-to-pin delay through one LUT 10 pF — 7.9 — 14.0 ns

tPD2 Best case pin-to-pin delay through one LUT 10 pF — 5.8 — 8.5 ns

tSU Global clock setup time — 2.4 — 4.6 — ns

tHGlobal clock hold time — 0 — 0 — ns

tCO Global clock to output delay 10 pF 2.0 6.6 2.0 8.6 ns

tCH Global clock high time — 253 — 339 — ps

tCL Global clock low time — 253 — 339 — ps

tCNT

Minimum global clock period for

16-bit counter — 5.4 — 8.4 — ns

fCNT

Maximum global clock frequency for 16-bit

counter — — 184.1 — 118.3 MHz

Notes to Table 3–26:

(1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global

clock input pin maximum frequency.

(2) Not applicable to the T144 package of the 5M240Z device.

Table 3–27. Global Clock External I/O Timing Parameters for the 5M240Z Device (Note 1), (2)

Symbol Parameter Condition

C4 C5, I5

Unit

Min Max Min Max

tPD1 Worst case pin-to-pin delay through one LUT 10 pF — 9.5 — 17.7 ns

tPD2 Best case pin-to-pin delay through one LUT 10 pF — 5.7 — 8.5 ns

tSU Global clock setup time — 2.2 — 4.4 — ns

tHGlobal clock hold time — 0 — 0 — ns

tCO Global clock to output delay 10 pF 2.0 6.7 2.0 8.7 ns

tCH Global clock high time — 253 — 339 — ps

tCL Global clock low time — 253 — 339 — ps

tCNT

Minimum global clock period for 16-bit

counter — 5.4 — 8.4 — ns

fCNT

Maximum global clock frequency for 16-bit

counter — — 184.1 — 118.3 MHz

Notes to Table 3–27:

(1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global

clock input pin maximum frequency.

(2) Only applicable to the T144 package of the 5M240Z device.

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–21

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

Table 3 –28 lists the external I/O timing parameters for the 5M570Z device.

Table 3 –29 lists the external I/O timing parameters for the 5M1270Z device.

Table 3–28. Global Clock External I/O Timing Parameters for the 5M570Z Device (Note 1)

Symbol Parameter Condition

C4 C5, I5

Unit

Min Max Min Max

tPD1 Worst case pin-to-pin delay through one LUT 10 pF — 9.5 — 17.7 ns

tPD2 Best case pin-to-pin delay through one LUT 10 pF — 5.7 — 8.5 ns

tSU Global clock setup time — 2.2 — 4.4 — ns

tHGlobal clock hold time — 0 — 0 — ns

tCO Global clock to output delay 10 pF 2.0 6.7 2.0 8.7 ns

tCH Global clock high time — 253 — 339 — ps

tCL Global clock low time — 253 — 339 — ps

tCNT

Minimum global clock period for 16-bit

counter — 5.4 — 8.4 — ns

fCNT

Maximum global clock frequency for 16-bit

counter — — 184.1 — 118.3 MHz

Note to Table 3–28:

(1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global

clock input pin maximum frequency.

Table 3–29. Global Clock External I/O Timing Parameters for the 5M1270Z Device (Note 1), (2)

Symbol Parameter Condition

C4 C5, I5

Unit

Min Max Min Max

tPD1 Worst case pin-to-pin delay through one LUT 10 pF — 8.1 — 10.0 ns

tPD2 Best case pin-to-pin delay through one LUT 10 pF — 4.8 — 5.9 ns

tSU Global clock setup time — 1.5 — 1.9 — ns

tHGlobal clock hold time — 0 — 0 — ns

tCO Global clock to output delay 10 pF 2.0 5.9 2.0 7.3 ns

tCH Global clock high time — 216 — 266 — ps

tCL Global clock low time — 216 — 266 — ps

tCNT

Minimum global clock period for 16-bit

counter — 4.0 — 5.0 — ns

fCNT

Maximum global clock frequency for 16-bit

counter — — 247.5 — 201.1 MHz

Notes to Table 3–29:

(1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global

clock input pin maximum frequency.

(2) Not applicable to the F324 package of the 5M1270Z device.

3–22 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Table 3 –30 lists the external I/O timing parameters for the F324 package of the

5M1270Z device.

Table 3 –31 lists the external I/O timing parameters for the 5M2210Z device.

Table 3–30. Global Clock External I/O Timing Parameters for the 5M1270Z Device (Note 1), (2)

Symbol Parameter Condition

C4 C5, I5

Unit

Min Max Min Max

tPD1 Worst case pin-to-pin delay through one LUT 10 pF — 9.1 — 11.2 ns

tPD2 Best case pin-to-pin delay through one LUT 10 pF — 4.8 — 5.9 ns

tSU Global clock setup time — 1.5 — 1.9 — ns

tHGlobal clock hold time — 0 — 0 — ns

tCO Global clock to output delay 10 pF 2.0 6.0 2.0 7.4 ns

tCH Global clock high time — 216 — 266 — ps

tCL Global clock low time — 216 — 266 — ps

tCNT

Minimum global clock period for 16-bit

counter — 4.0 — 5.0 — ns

fCNT

Maximum global clock frequency for 16-bit

counter — — 247.5 — 201.1 MHz

Notes to Table 3–30:

(1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global

clock input pin maximum frequency.

(2) Only applicable to the F324 package of the 5M1270Z device.

Table 3–31. Global Clock External I/O Timing Parameters for the 5M2210Z Device (Note 1)

Symbol Parameter Condition

C4 C5, I5

Unit

Min Max Min Max

tPD1 Worst case pin-to-pin delay through one LUT 10 pF — 9.1 — 11.2 ns

tPD2 Best case pin-to-pin delay through one LUT 10 pF — 4.8 — 5.9 ns

tSU Global clock setup time — 1.5 — 1.9 — ns

tHGlobal clock hold time — 0 — 0 — ns

tCO Global clock to output delay 10 pF 2.0 6.0 2.0 7.4 ns

tCH Global clock high time — 216 — 266 — ps

tCL Global clock low time — 216 — 266 — ps

tCNT

Minimum global clock period for 16-bit

counter — 4.0 — 5.0 — ns

fCNT

Maximum global clock frequency for 16-bit

counter — — 247.5 — 201.1 MHz

Note to Table 3–31:

(1) The maximum frequency is limited by the I/O standard on the clock input pin. The 16-bit counter critical delay performs faster than this global

clock input pin maximum frequency.

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–23

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

External Timing I/O Delay Adders

The I/O delay timing parameters for the I/O standard input and output adders and

the input delays are specified by speed grade, independent of device density.

Table 3 –32 through Table 3–36 on page 3–25 list the adder delays associated with I/O

pins for all packages. If you select an I/O standard other than 3.3-V LVTTL, add the

input delay adder to the external tSU timing parameters listed in Table 3–26 on

page 3–20 through Table 3–31. If you select an I/O standard other than 3.3-V LVTTL

with 16 mA drive strength and fast slew rate, add the output delay adder to the

external tCO and tPD listed in Table 3–26 on page 3–20 through Ta b le 3–3 1 .

Table 3–32. External Timing Input Delay Adders for MAX V Devices

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL

Without Schmitt

Trigger —0—0—0—0ps

With Schmitt

Trigger — 387 — 442 — 480 — 591 ps

3.3-V LVCMOS

Without Schmitt

Trigger —0—0—0—0ps

With Schmitt

Trigger — 387 — 442 — 480 — 591 ps

2.5-V LVTTL /

LVCMOS

Without Schmitt

Trigger — 42 — 42 — 246 — 303 ps

With Schmitt

Trigger — 429 — 483 — 787 — 968 ps

1.8-V LVTTL /

LVCMOS

Without Schmitt

Trigger — 378 — 368 — 695 — 855 ps

1.5-V LVCMOS Without Schmitt

Trigger — 681 — 658 — 1,334 — 1,642 ps

1.2-V LVCMOS Without Schmitt

Trigger — 1,055 — 1,010 — 2,324 — 2,860 ps

3.3-V PCI Without Schmitt

Trigger —0—0—0—0ps

Table 3–33. External Timing Input Delay tGLOB Adders for GCLK Pins for MAX V Devices (Part 1 of 2)

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL

Without Schmitt

Trigger —0—0—0—0ps

With Schmitt

Trigger — 387 — 442 — 400 — 493 ps

3–24 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

3.3-V LVCMOS

Without Schmitt

Trigger —0—0—0—0ps

With Schmitt

Trigger — 387 — 442 — 400 — 493 ps

2.5-V LVTTL /

LVCMOS

Without Schmitt

Trigger — 242 — 242 — 287 — 353 ps

With Schmitt

Trigger — 429 — 483 — 550 — 677 ps

1.8-V LVTTL /

LVCMOS

Without Schmitt

Trigger — 378 — 368 — 459 — 565 ps

1.5-V LVCMOS Without Schmitt

Trigger — 681 — 658 — 1,111 — 1,368 ps

1.2-V LVCMOS Without Schmitt

Trigger — 1,055 — 1,010 — 2,067 — 2,544 ps

3.3-V PCI Without Schmitt

Trigger —0—0—7—9ps

Table 3–33. External Timing Input Delay tGLOB Adders for GCLK Pins for MAX V Devices (Part 2 of 2)

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

Table 3–34. External Timing Output Delay and tOD Adders for Fast Slew Rate for MAX V Devices

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL 16 mA—0—0—0—0ps

8 mA — 39 — 58 — 84 — 104 ps

3.3-V LVCMOS 8 mA—0—0—0—0ps

4 mA — 39 — 58 — 84 — 104 ps

2.5-V LVTTL / LVCMOS 14 mA — 122 — 129 — 158 — 195 ps

7 mA — 196 — 188 — 251 — 309 ps

1.8-V LVTTL / LVCMOS 6 mA — 624 — 624 — 738 — 909 ps

3 mA — 686 — 694 — 850 — 1,046 ps

1.5-V LVCMOS 4 mA — 1,188 — 1,184 — 1,376 — 1,694 ps

2 mA — 1,279 — 1,280 — 1,517 — 1,867 ps

1.2-V LVCMOS 3 mA — 1,911 — 1,883 — 2,206 — 2,715 ps

3.3-V PCI 20 mA — 39 — 58 — 4 — 5 ps

LVDS — — 122 — 129 — 158 — 195 ps

RSDS — — 122 — 129 — 158 — 195 ps

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–25

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

Table 3–35. External Timing Output Delay and tOD Adders for Slow Slew Rate for MAX V Devices

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

3.3-V LVTTL 16 mA — 5,913 — 6,043 — 6,612 — 6,293 ps

8 mA — 6,488 — 6,645 — 7,313 — 6,994 ps

3.3-V LVCMOS 8 mA — 5,913 — 6,043 — 6,612 — 6,293 ps

4 mA — 6,488 — 6,645 — 7,313 — 6,994 ps

2.5-V LVTTL / LVCMOS 14 mA — 9,088 — 9,222 — 10,021 — 9,702 ps

7 mA — 9,808 — 9,962 — 10,881 — 10,562 ps

1.8-V LVTTL / LVCMOS 6 mA — 21,758 — 21,782 — 21,134 — 20,815 ps

3 mA — 23,028 — 23,032 — 22,399 — 22,080 ps

1.5-V LVCMOS 4 mA — 39,068 — 39,032 — 34,499 — 34,180 ps

2 mA — 40,578 — 40,542 — 36,281 — 35,962 ps

1.2-V LVCMOS 3 mA — 69,332 — 70,257 — 55,796 — 55,477 ps

3.3-V PCI 20 mA — 6,488 — 6,645 — 339 — 418 ps

Table 3–36. IOE Programmable Delays for MAX V Devices

Parameter

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z 5M1270Z/ 5M2210Z

Unit

C4 C5, I5 C4 C5, I5

Min Max Min Max Min Max Min Max

Input Delay from Pin to Internal

Cells = 1 — 1,858 — 2,214 — 1,592 — 1,960 ps

Input Delay from Pin to Internal

Cells = 0 — 569 — 616 — 115 — 142 ps

3–26 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Maximum Input and Output Clock Rates

Table 3 –37 and Table 3–38 list the maximum input and output clock rates for standard

I/O pins in MAX V devices.

Table 3–37. Maximum Input Clock Rate for I/Os for MAX V Devices

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z/5M1270Z/

5M2210Z Unit

C4, C5, I5

3.3-V LVTTL Without Schmitt Trigger 304 MHz

With Schmitt Trigger 304 MHz

3.3-V LVCMOS Without Schmitt Trigger 304 MHz

With Schmitt Trigger 304 MHz

2.5-V LVTTL Without Schmitt Trigger 304 MHz

With Schmitt Trigger 304 MHz

2.5-V LVCMOS Without Schmitt Trigger 304 MHz

With Schmitt Trigger 304 MHz

1.8-V LVTTL Without Schmitt Trigger 200 MHz

1.8-V LVCMOS Without Schmitt Trigger 200 MHz

1.5-V LVCMOS Without Schmitt Trigger 150 MHz

1.2-V LVCMOS Without Schmitt Trigger 120 MHz

3.3-V PCI Without Schmitt Trigger 304 MHz

Table 3–38. Maximum Output Clock Rate for I/Os for MAX V Devices

I/O Standard

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z/5M1270Z/

5M2210Z Unit

C4, C5, I5

3.3-V LVTTL 304 MHz

3.3-V LVCMOS 304 MHz

2.5-V LVTTL 304 MHz

2.5-V LVCMOS 304 MHz

1.8-V LVTTL 200 MHz

1.8-V LVCMOS 200 MHz

1.5-V LVCMOS 150 MHz

1.2-V LVCMOS 120 MHz

3.3-V PCI 304 MHz

LVDS 304 MHz

RSDS 200 MHz

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–27

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

LVDS and RSDS Output Timing Specifications

Table 3 –39 lists the emulated LVDS output timing specifications for MAX V devices.

Table 3–39. Emulated LVDS Output Timing Specifications for MAX V Devices

Parameter Mode

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z/5M1270Z/

5M2210Z Unit

C4, C5, I5

Min Max

Data rate (1), (2)

10 — 304 Mbps

9 — 304 Mbps

8 — 304 Mbps

7 — 304 Mbps

6 — 304 Mbps

5 — 304 Mbps

4 — 304 Mbps

3 — 304 Mbps

2 — 304 Mbps

1 — 304 Mbps

tDUTY —4555%

Total jitter (3) ——0.2UI

tRISE ——450ps

tFALL ——450ps

Notes to Table 3–39:

(1) The performance of the LVDS_E_3R transmitter system is limited by the lower of the two—the maximum data rate supported by LVDS_E_3R

I/O buffer or 2x (FMAX of the ALTLVDS_TX instance). The actual performance of your LVDS_E_3R transmitter system must be attained through

the Quartus II timing analysis of the complete design.

(2) For the input clock pin to achieve 304 Mbps, use I/O standard with VCCIO of 2.5 V and above.

(3) This specification is based on external clean clock source.

3–28 Chapter 3: DC and Switching Characteristics for MAX V Devices

Timing Model and Specifications

MAX V Device Handbook May 2011 Altera Corporation

Table 3 –40 lists the emulated RSDS output timing specifications for MAX V devices.

Table 3–40. Emulated RSDS Output Timing Specifications for MAX V Devices

Parameter Mode

5M40Z/ 5M80Z/ 5M160Z/

5M240Z/ 5M570Z/5M1270Z/

5M2210Z

Unit

C4, C5, I5

Min Max

Data rate (1)

10 — 200 Mbps

9 — 200 Mbps

8 — 200 Mbps

7 — 200 Mbps

6 — 200 Mbps

5 — 200 Mbps

4 — 200 Mbps

3 — 200 Mbps

2 — 200 Mbps

1 — 200 Mbps

tDUTY —4555%

Total jitter (2) ——0.2UI

tRISE ——450ps

tFALL ——450ps

Notes to Table 3–40:

(1) For the input clock pin to achieve 200 Mbps, use I/O standard with VCCIO of 1.8 V and above.

(2) This specification is based on external clean clock source.

Chapter 3: DC and Switching Characteristics for MAX V Devices 3–29

Timing Model and Specifications

May 2011 Altera Corporation MAX V Device Handbook

JTAG Timing Specifications

Figure 3–6 shows the timing waveform for the JTAG signals for the MAX V device

family.

Table 3 –41 lists the JTAG timing parameters and values for the MAX V device family.

Figure 3–6. JTAG Timing Waveform for MAX V Devices

TDI

TMS

TDO

TCK

Signal

to be

Captured

Signal

to be

Driven

tJCP

tJCH tJCL

tJPSU tJPH

tJPCO tJPXZ

tJPZX

tJSSU tJSH

tJSZX tJSCO tJSXZ

Table 3–41. JTAG Timing Parameters for MAX V Devices (Part 1 of 2)

Symbol Parameter Min Max Unit

tJCP (1)

TCK

clock period for VCCIO1 = 3.3 V 55.5 — ns

TCK

clock period for VCCIO1 = 2.5 V 62.5 — ns

TCK

clock period for VCCIO1 = 1.8 V 100 — ns

TCK

clock period for VCCIO1 = 1.5 V 143 — ns

tJCH

TCK

clock high time 20 — ns

tJCL

TCK

clock low time 20 — ns

tJPSU JTAG port setup time (2) 8—ns

tJPH JTAG port hold time 10 — ns

tJPCO JTAG port clock to output (2) —15ns

tJPZX JTAG port high impedance to valid output (2) —15ns

tJPXZ JTAG port valid output to high impedance (2) —15ns

tJSSU Capture register setup time 8 — ns

tJSH Capture register hold time 10 — ns

tJSCO Update register clock to output — 25 ns

tJSZX Update register high impedance to valid output — 25 ns

3–30 Chapter 3: DC and Switching Characteristics for MAX V Devices

Document Revision History

MAX V Device Handbook May 2011 Altera Corporation

Document Revision History

Table 3 –42 lists the revision history for this chapter.

tJSXZ Update register valid output to high impedance — 25 ns

Notes to Table 3–41:

(1) Minimum clock period specified for 10 pF load on the

TDO

pin. Larger loads on

TDO

degrades the maximum

TCK

frequency.

(2) This specification is shown for 3.3-V LVTTL/LVCMOS and 2.5-V LVTTL/LVCMOS operation of the JTAG pins. For 1.8-V LVTTL/LVCMOS and

1.5-V LVCMOS operation, the tJPSU minimum is 6 ns and tJPCO, tJPZX, and tJPXZ are maximum values at 35 ns.

Table 3–41. JTAG Timing Parameters for MAX V Devices (Part 2 of 2)

Symbol Parameter Min Max Unit

Table 3–42. Document Revision History

Date Version Changes

May 2011 1.2 Updated Table 3–2, Table 3–15, Table 3–16, and Table 3–33.

January 2011 1.1 Updated Table 3–37, Table 3–38, Table 3–39, and Table 3–40.

December 2010 1.0 Initial release.