Microsemi A3PN015Z1VQ100I Proasic3 nano flash fpgas Datasheet

Revision 11
ProASIC3 nano Flash FPGAs
Features and Benefits
Advanced I/Os
• 1.5 V, 1.8 V, 2.5 V, and 3.3 V Mixed-Voltage Operation
• Bank-Selectable I/O Voltages—up to 4 Banks per Chip
• Single-Ended I/O Standards: LVTTL, LVCMOS 3.3 V /
2.5 V / 1.8 V / 1.5 V
• Wide Range Power Supply Voltage Support per JESD8-B,
Allowing I/Os to Operate from 2.7 V to 3.6 V
• I/O Registers on Input, Output, and Enable Paths
• Selectable Schmitt Trigger Inputs
• Hot-Swappable and Cold-Sparing I/Os
• Programmable Output Slew Rate† and Drive Strength
• Weak Pull-Up/-Down
• IEEE 1149.1 (JTAG) Boundary Scan Test
• Pin-Compatible Packages across the ProASIC3 Family
Wide Range of Features
• 10 k to 250 k System Gates
• Up to 36 kbits of True Dual-Port SRAM
• Up to 71 User I/Os
Reprogrammable Flash Technology
• 130-nm, 7-Layer Metal (6 Copper), Flash-Based CMOS
Process
• Instant On Level 0 Support
• Single-Chip Solution
• Retains Programmed Design when Powered Off
High Performance
• 350 MHz System Performance
Clock Conditioning Circuit (CCC) and PLL†
In-System Programming (ISP) and Security
• ISP Using On-Chip 128-Bit Advanced Encryption Standard
(AES) Decryption via JTAG (IEEE 1532–compliant)†
• FlashLock® Designed to Secure FPGA Contents
Low Power
•
•
•
•
Low Power ProASIC®3 nano Products
1.5 V Core Voltage for Low Power
Support for 1.5 V-Only Systems
Low-Impedance Flash Switches
• Up to Six CCC Blocks, One with an Integrated PLL
• Configurable Phase Shift, Multiply/Divide, Delay
Capabilities and External Feedback
• Wide Input Frequency Range (1.5 MHz to 350 MHz)
Embedded Memory
• 1 kbit of FlashROM User Nonvolatile Memory
• SRAMs and FIFOs with Variable-Aspect-Ratio 4,608-Bit RAM
Blocks (×1, ×2, ×4, ×9, and ×18 organizations)†
• True Dual-Port SRAM (except ×18 organization)†
High-Performance Routing Hierarchy
Enhanced Commercial Temperature Range
• Segmented, Hierarchical Routing and Clock Structure
• –20°C to +70°C
Table 1 • ProASIC3 nano Devices
ProASIC3 nano Devices
ProASIC3 nano-Z
A3PN010
A3PN0151 A3PN020
Devices1
System Gates
A3PN060
A3PN125
A3PN250
A3PN030Z1,2
A3PN060Z1
A3PN125Z1
A3N250Z1
10,000
15,000
20,000
30,000
60,000
125,000
250,000
Typical Equivalent Macrocells
86
128
172
256
512
1,024
2,048
VersaTiles (D-flip-flops)
260
384
520
768
1,536
3,072
6,144
RAM Kbits (1,024 bits)2
–
–
–
–
18
36
36
4,608-Bit Blocks
–
–
–
–
4
8
8
FlashROM Kbits
1
1
1
1
1
1
1
–
–
–
–
Yes
Yes
Yes
2
Secure (AES) ISP
2
Integrated PLL in CCCs
2
–
–
–
–
1
1
1
VersaNet Globals
4
4
4
6
18
18
18
I/O Banks
2
3
3
2
2
2
4
Maximum User I/Os (packaged device)
34
49
49
77
71
71
68
Maximum User I/Os (Known Good Die)
34
–
52
83
71
71
68
QN48
QN68
QN68
QN48, QN68
VQ100
VQ100
VQ100
VQ100
Package Pins
QFN
VQFP
Notes:
1. Not recommended for new designs.
2. A3PN030Z and smaller devices do not support this feature.
3. For higher densities and support of additional features, refer to the ProASIC3 and ProASIC3E datasheets.
† A3PN030 and smaller devices do not support this feature.
January 2013
© 2013 Microsemi Corporation
I
I/Os Per Package
ProASIC3 nano Devices
A3PN010
A3PN0151
A3PN020
ProASIC3 nano-Z Devices1
A3PN060
A3PN125
A3PN250
A3PN030Z1
A3PN060Z1
A3PN125Z1
A3PN250Z1
Known Good Die
34
–
52
83
71
71
68
QN48
34
–
–
34
–
–
–
QN68
–
49
49
49
–
–
–
VQ100
–
–
–
77
71
71
68
Notes:
1. Not recommended for new designs.
2. When considering migrating your design to a lower- or higher-density device, refer to the ProASIC3 FPGA Fabric User’s Guide
to ensure compliance with design and board migration requirements.
3. "G" indicates RoHS-compliant packages. Refer to "ProASIC3 nano Ordering Information" on page III for the location of the "G"
in the part number. For nano devices, the VQ100 package is offered in both leaded and RoHS-compliant versions. All other
packages are RoHS-compliant only.
Table 2 • ProASIC3 nano FPGAs Package Sizes Dimensions
Packages
QN48
QN68
VQ100
Length × Width (mm\mm)
6x6
8x8
14 x 14
Nominal Area (mm2)
36
64
196
Pitch (mm)
0.4
0.4
0.5
Height (mm)
0.90
0.90
1.20
ProASIC3 nano Device Status
ProASIC3 nano Devices
Status
A3PN010
Production
A3PN015
Not recommended for new designs.
A3PN020
Production
ProASIC3 nano-Z Devices
Status
A3PN030Z
Not recommended for new designs.
A3PN060
Production
A3PN060Z
Not recommended for new designs.
A3PN125
Production
A3PN125Z
Not recommended for new designs.
A3PN250
Production
A3PN250Z
Not recommended for new designs.
II
R evis i o n 11
ProASIC3 nano Flash FPGAs
ProASIC3 nano Ordering Information
A3PN250
_
Z
1
VQ
G
100
Y
I
Application (Temperature Range)
Blank = Commercial (0°C to +70°C Ambient Temperature)
I = Industrial (–40°C to +85°C Ambient Temperature)
PP = Pre-Production
ES = Engineering Sample (Room Temperature Only)
Security Feature
Y = Device Includes License to Implement IP Based on the
Cryptography Research, Inc. (CRI) Patent Portfolio
Blank = Device Does Not Include License to Implement IP Based
on the Cryptography Research, Inc. (CRI) Patent Portfolio
Package Lead Count
Lead-Free Packaging
Blank = Standard Packaging
G= RoHS-Compliant Packaging
Package Type
QN = Quad Flat Pack No Leads (0.4 mm and 0.5 mm pitches)
VQ = Very Thin Quad Flat Pack (0.5 mm pitch)
DIELOT = Known Good Die
Speed Grade
Blank = Standard
1 = 15% Faster than Standard
2 = 25% Faster than Standard
Part Number
Feature Grade
Z = nano devices without enhanced features* (Not recommended for new designs)
Blank = Standard
ProASIC3 nano Devices
A3PN010 = 10,000 System Gates
A3PN015 = 15,000 System Gates (A3PN015 is not recommended for new designs)
A3PN020 = 20,000 System Gates
A3PN030 = 30,000 System Gates
A3PN060 = 60,000 System Gates
A3PN125 = 125,000 System Gates
A3PN250 = 250,000 System Gates
Note: *For the A3PN060, A3PN125, and A3PN250, the Z feature grade does not support the enhanced nano features of Schmitt
trigger input, cold-sparing, and hot-swap I/O capability. The A3PN030 Z feature grade does not support Schmitt trigger input.
For the VQ100, CS81, UC81, QN68, and QN48 packages, the Z feature grade and the N part number are not marked on the
device.
Devices Not Recommended For New Designs
A3PN015, A3PN030Z, A3PN060Z, A3PN125Z, and A3PN250Z are not recommended for new designs.
Device Marking
Microsemi normally topside marks the full ordering part number on each device. There are some exceptions to this, such as some of
the Z feature grade nano devices, the V2 designator for IGLOO devices, and packages where space is physically limited. Packages
that have limited characters available are UC36, UC81, CS81, QN48, QN68, and QFN132. On these specific packages, a subset of
the device marking will be used that includes the required legal information and as much of the part number as allowed by character
limitation of the device. In this case, devices will have a truncated device marking and may exclude the applications markings, such
as the I designator for Industrial Devices or the ES designator for Engineering Samples.
Figure 1 on page 1-IV shows an example of device marking based on the AGL030V5-UCG81.
R ev i si o n 1 1
III
The actual mark will vary by the device/package combination ordered.
Package
Wafer Lot #
Figure 1 •
Country of Origin
ACTELXXX
AGL030YWW
UCG81XXXX
XXXXXXXX
Device Name
(six characters)
Date Code
Customer Mark
(if applicable)
Example of Device Marking for Small Form Factor Packages
ProASIC3 nano Products Available in the Z Feature Grade
Devices
A3PN030*
A3PN060*
A3PN125*
A3PN250*
QN48
–
–
–
QN68
–
–
–
VQ100
VQ100
VQ100
VQ100
Packages
Note: *Not recommended for new designs.
Temperature Grade Offerings
ProASIC3 nano Devices
A3PN010
A3PN015*
A3PN020
ProASIC3 nano-Z Devices*
A3PN060
A3PN125
A3PN250
A3PN030Z*
A3PN060Z*
A3PN125Z*
A3PN250Z*
QN48
C, I
–
–
C, I
–
–
–
QN68
–
C, I
C, I
C, I
–
–
–
VQ100
–
–
–
C, I
C, I
C, I
C, I
Note: *Not recommended for new designs.
C = Commercial temperature range: 0°C to 70°C ambient temperature
I = Industrial temperature range: –40°C to 85°C ambient temperature
Speed Grade and Temperature Grade Matrix
Temperature Grade
C
I
Std.
1

2

Notes:
1. C = Commercial temperature range: 0°C to 70°C ambient temperature.
2. I = Industrial temperature range: –40°C to 85°C ambient temperature.
Contact your local Microsemi SoC Products Group representative for device availability:
http://www.microsemi.com/soc/contact/default.aspx.
IV
Revision 11
ProASIC3 nano Flash FPGAs
Table of Contents
ProASIC3 nano Device Overview
General Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1
ProASIC3 nano DC and Switching Characteristics
General Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1
Calculating Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-6
User I/O Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-12
VersaTile Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-49
Global Resource Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-53
Clock Conditioning Circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-57
Embedded SRAM and FIFO Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-59
Embedded FlashROM Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-70
JTAG 1532 Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-71
Pin Descriptions and Packaging
Supply Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
User Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
JTAG Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Special Function Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Related Documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3-1
3-2
3-3
3-4
3-4
3-4
Package Pin Assignments
48-Pin QFN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1
68-Pin QFN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-4
100-Pin VQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-8
Datasheet Information
List of Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1
Datasheet Categories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-6
Safety Critical, Life Support, and High-Reliability Applications Policy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-6
R ev i si o n 1 1
V
1 – ProASIC3 nano Device Overview
General Description
ProASIC3, the third-generation family of Microsemi flash FPGAs, offers performance, density, and
features beyond those of the ProASICPLUS® family. Nonvolatile flash technology gives ProASIC3 nano
devices the advantage of being a secure, low power, single-chip solution that is Instant On. ProASIC3
nano devices are reprogrammable and offer time-to-market benefits at an ASIC-level unit cost. These
features enable designers to create high-density systems using existing ASIC or FPGA design flows and
tools.
ProASIC3 nano devices offer 1 kbit of on-chip, reprogrammable, nonvolatile FlashROM storage as well
as clock conditioning circuitry based on an integrated phase-locked loop (PLL). A3PN030 and smaller
devices do not have PLL or RAM support. ProASIC3 nano devices have up to 250,000 system gates,
supported with up to 36 kbits of true dual-port SRAM and up to 71 user I/Os.
ProASIC3 nano devices increase the breadth of the ProASIC3 product line by adding new features and
packages for greater customer value in high volume consumer, portable, and battery-backed markets.
Added features include smaller footprint packages designed with two-layer PCBs in mind, low power,
hot-swap capability, and Schmitt trigger for greater flexibility in low-cost and power-sensitive applications.
Flash Advantages
Reduced Cost of Ownership
Advantages to the designer extend beyond low unit cost, performance, and ease of use. Unlike SRAMbased FPGAs, flash-based ProASIC3 nano devices allow all functionality to be Instant On; no external
boot PROM is required. On-board security mechanisms prevent access to all the programming
information and enable secure remote updates of the FPGA logic. Designers can perform secure remote
in-system reprogramming to support future design iterations and field upgrades with confidence that
valuable intellectual property (IP) cannot be compromised or copied. Secure ISP can be performed using
the industry-standard AES algorithm. The ProASIC3 nano device architecture mitigates the need for
ASIC migration at higher user volumes. This makes the ProASIC3 nano device a cost-effective ASIC
replacement solution, especially for applications in the consumer, networking/communications,
computing, and avionics markets.
With a variety of devices under $1, ProASIC3 nano FPGAs enable cost-effective implementation of
programmable logic and quick time to market.
Security
Nonvolatile, flash-based ProASIC3 nano devices do not require a boot PROM, so there is no vulnerable
external bitstream that can be easily copied. ProASIC3 nano devices incorporate FlashLock, which
provides a unique combination of reprogrammability and design security without external overhead,
advantages that only an FPGA with nonvolatile flash programming can offer.
ProASIC3 nano devices utilize a 128-bit flash-based lock and a separate AES key to provide the highest
level of protection in the FPGA industry for programmed intellectual property and configuration data. In
addition, all FlashROM data in ProASIC3 nano devices can be encrypted prior to loading, using the
industry-leading AES-128 (FIPS192) bit block cipher encryption standard. The AES standard was
adopted by the National Institute of Standards and Technology (NIST) in 2000 and replaces the 1977
DES standard. ProASIC3 nano devices have a built-in AES decryption engine and a flash-based AES
key that make them the most comprehensive programmable logic device security solution available
today. ProASIC3 nano devices with AES-based security provide a high level of protection for remote field
updates over public networks such as the Internet, and are designed to ensure that valuable IP remains
out of the hands of system overbuilders, system cloners, and IP thieves.
R ev i si o n 1 1
1 -1
ProASIC3 nano Device Overview
Security, built into the FPGA fabric, is an inherent component of ProASIC3 nano devices. The flash cells
are located beneath seven metal layers, and many device design and layout techniques have been used
to make invasive attacks extremely difficult. ProASIC3 nano devices, with FlashLock and AES security,
are unique in being highly resistant to both invasive and noninvasive attacks. Your valuable IP is
protected with industry-standard security, making remote ISP possible. A ProASIC3 nano device
provides the best available security for programmable logic designs.
Single Chip
Flash-based FPGAs store their configuration information in on-chip flash cells. Once programmed, the
configuration data is an inherent part of the FPGA structure, and no external configuration data needs to
be loaded at system power-up (unlike SRAM-based FPGAs). Therefore, flash-based ProASIC3 nano
FPGAs do not require system configuration components such as EEPROMs or microcontrollers to load
device configuration data. This reduces bill-of-materials costs and PCB area, and increases security and
system reliability.
Instant On
Microsemi flash-based ProASIC3 nano devices support Level 0 of the Instant On classification standard.
This feature helps in system component initialization, execution of critical tasks before the processor
wakes up, setup and configuration of memory blocks, clock generation, and bus activity management.
The Instant On feature of flash-based ProASIC3 nano devices greatly simplifies total system design and
reduces total system cost, often eliminating the need for CPLDs and clock generation PLLs that are used
for these purposes in a system. In addition, glitches and brownouts in system power will not corrupt the
ProASIC3 nano device's flash configuration, and unlike SRAM-based FPGAs, the device will not have to
be reloaded when system power is restored. This enables the reduction or complete removal of the
configuration PROM, expensive voltage monitor, brownout detection, and clock generator devices from
the PCB design. Flash-based ProASIC3 nano devices simplify total system design and reduce cost and
design risk while increasing system reliability and improving system initialization time.
Firm Errors
Firm errors occur most commonly when high-energy neutrons, generated in the upper atmosphere, strike
a configuration cell of an SRAM FPGA. The energy of the collision can change the state of the
configuration cell and thus change the logic, routing, or I/O behavior in an unpredictable way. These
errors are impossible to prevent in SRAM FPGAs. The consequence of this type of error can be a
complete system failure. Firm errors do not exist in the configuration memory of ProASIC3 nano flashbased FPGAs. Once it is programmed, the flash cell configuration element of ProASIC3 nano FPGAs
cannot be altered by high-energy neutrons and is therefore immune to them. Recoverable (or soft) errors
occur in the user data SRAM of all FPGA devices. These can easily be mitigated by using error detection
and correction (EDAC) circuitry built into the FPGA fabric.
Low Power
Flash-based ProASIC3 nano devices exhibit power characteristics similar to an ASIC, making them an
ideal choice for power-sensitive applications. ProASIC3 nano devices have only a very limited power-on
current surge and no high-current transition period, both of which occur on many FPGAs.
ProASIC3 nano devices also have low dynamic power consumption to further maximize power savings.
Advanced Flash Technology
ProASIC3 nano devices offer many benefits, including nonvolatility and reprogrammability through an
advanced flash-based, 130-nm LVCMOS process with seven layers of metal. Standard CMOS design
techniques are used to implement logic and control functions. The combination of fine granularity,
enhanced flexible routing resources, and abundant flash switches allows for very high logic utilization
without compromising device routability or performance. Logic functions within the device are
interconnected through a four-level routing hierarchy.
1- 2
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
Advanced Architecture
The proprietary ProASIC3 nano architecture provides granularity comparable to standard-cell ASICs.
The ProASIC3 nano device consists of five distinct and programmable architectural features (Figure 1-3
to Figure 1-4 on page 1-4):
•
FPGA VersaTiles
•
Dedicated FlashROM
•
Dedicated SRAM/FIFO memory
•
Extensive CCCs and PLLs
•
Advanced I/O structure
Bank 1*
I/Os
Bank 1
Bank 0
VersaTile
User Nonvolatile FlashROM
Charge Pumps
CCC-GL
Bank 1
Note: *Bank 0 for the A3PN030 device
Figure 1-1 • ProASIC3 Device Architecture Overview with Two I/O Banks and No RAM
(A3PN010 and A3PN030)
Bank 1
I/Os
Bank 2
Bank 0
VersaTile
User Nonvolatile FlashROM
Charge Pumps
CCC-GL
Bank 1
Figure 1-2 •
ProASIC3 nano Architecture Overview with Three I/O Banks and No RAM (A3PN015 and
A3PN020)
R ev i si o n 1 1
1 -3
ProASIC3 nano Device Overview
Bank 0
Bank 0
Bank 1
CCC
RAM Block
4,608-Bit Dual-Port
SRAM or FIFO Block
I/Os
ISP AES
Decryption
User Nonvolatile
FlashROM
Charge Pumps
Bank 0
Bank 1
VersaTile
Bank 1
Figure 1-3 •
ProASIC3 nano Device Architecture Overview with Two I/O Banks (A3PN060 and A3PN125)
Bank 0
CCC
Bank 1
Bank 3
RAM Block
4,608-Bit Dual-Port
SRAM or FIFO Block
ISP AES
Decryption
User Nonvolatile
FlashROM
Charge Pumps
Bank 1
Bank 3
I/Os
VersaTile
Bank 2
Figure 1-4 •
ProASIC3 nano Device Architecture Overview with Four I/O Banks (A3PN250)
The FPGA core consists of a sea of VersaTiles. Each VersaTile can be configured as a three-input logic
function, a D-flip-flop (with or without enable), or a latch by programming the appropriate flash switch
interconnections. The versatility of the ProASIC3 nano core tile as either a three-input lookup table (LUT)
equivalent or as a D-flip-flop/latch with enable allows for efficient use of the FPGA fabric. The VersaTile
capability is unique to the ProASIC3 family of third-generation architecture flash FPGAs. VersaTiles are
connected with any of the four levels of routing hierarchy. Flash switches are distributed throughout the
device to provide nonvolatile, reconfigurable interconnect programming. Maximum core utilization is
possible for virtually any design.
1- 4
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
VersaTiles
The ProASIC3 nano core consists of VersaTiles, which have been enhanced beyond the ProASICPLUS®
core tiles. The ProASIC3 nano VersaTile supports the following:
•
All 3-input logic functions—LUT-3 equivalent
•
Latch with clear or set
•
D-flip-flop with clear or set
•
Enable D-flip-flop with clear or set
Refer to Figure 1-5 for VersaTile configurations.
LUT-3 Equivalent
X1
X2
X3
LUT-3
D-Flip-Flop with Clear or Set
Y
Data
CLK
CLR
Enable D-Flip-Flop with Clear or Set
Y
D-FF
Data
CLK
Y
D-FF
Enable
CLR
Figure 1-5 •
VersaTile Configurations
User Nonvolatile FlashROM
ProASIC3 nano devices have 1 kbit of on-chip, user-accessible, nonvolatile FlashROM. The FlashROM
can be used in diverse system applications:
•
Internet protocol addressing (wireless or fixed)
•
System calibration settings
•
Device serialization and/or inventory control
•
Subscription-based business models (for example, set-top boxes)
•
Secure key storage for secure communications algorithms
•
Asset management/tracking
•
Date stamping
•
Version management
The FlashROM is written using the standard ProASIC3 nano IEEE 1532 JTAG programming interface.
The core can be individually programmed (erased and written), and on-chip AES decryption can be used
selectively to securely load data over public networks (except in the A3PN030 and smaller devices), as in
security keys stored in the FlashROM for a user design.
The FlashROM can be programmed via the JTAG programming interface, and its contents can be read
back either through the JTAG programming interface or via direct FPGA core addressing. Note that the
FlashROM can only be programmed from the JTAG interface and cannot be programmed from the
internal logic array.
The FlashROM is programmed as 8 banks of 128 bits; however, reading is performed on a byte-by-byte
basis using a synchronous interface. A 7-bit address from the FPGA core defines which of the 8 banks
and which of the 16 bytes within that bank are being read. The three most significant bits (MSBs) of the
FlashROM address determine the bank, and the four least significant bits (LSBs) of the FlashROM
address define the byte.
The ProASIC3 nano development software solutions, Libero® System-on-Chip (SoC) software and
Designer, have extensive support for the FlashROM. One such feature is auto-generation of sequential
programming files for applications requiring a unique serial number in each part. Another feature enables
the inclusion of static data for system version control. Data for the FlashROM can be generated quickly
and easily using Libero SoC and Designer software tools. Comprehensive programming file support is
also included to allow for easy programming of large numbers of parts with differing FlashROM contents.
R ev i si o n 1 1
1 -5
ProASIC3 nano Device Overview
SRAM and FIFO
ProASIC3 nano devices (except the A3PN030 and smaller devices) have embedded SRAM blocks along
their north and south sides. Each variable-aspect-ratio SRAM block is 4,608 bits in size. Available
memory configurations are 256×18, 512×9, 1k×4, 2k×2, and 4k×1 bits. The individual blocks have
independent read and write ports that can be configured with different bit widths on each port. For
example, data can be sent through a 4-bit port and read as a single bitstream. The embedded SRAM
blocks can be initialized via the device JTAG port (ROM emulation mode) using the UJTAG macro
(except in A3PN030 and smaller devices).
In addition, every SRAM block has an embedded FIFO control unit. The control unit allows the SRAM
block to be configured as a synchronous FIFO without using additional core VersaTiles. The FIFO width
and depth are programmable. The FIFO also features programmable Almost Empty (AEMPTY) and
Almost Full (AFULL) flags in addition to the normal Empty and Full flags. The embedded FIFO control
unit contains the counters necessary for generation of the read and write address pointers. The
embedded SRAM/FIFO blocks can be cascaded to create larger configurations.
PLL and CCC
Higher density ProASIC3 nano devices using either the two I/O bank or four I/O bank architectures
provide the designer with very flexible clock conditioning capabilities. A3PN060, A3PN125, and
A3PN250 contain six CCCs. One CCC (center west side) has a PLL. The A3PN030 and smaller devices
use different CCCs in their architecture. These CCC-GLs contain a global MUX but do not have any
PLLs or programmable delays.
For devices using the six CCC block architecture, these six CCC blocks are located at the four corners
and the centers of the east and west sides.
All six CCC blocks are usable; the four corner CCCs and the east CCC allow simple clock delay
operations as well as clock spine access. The inputs of the six CCC blocks are accessible from the
FPGA core or from dedicated connections to the CCC block, which are located near the CCC.
The CCC block has these key features:
•
Wide input frequency range (fIN_CCC) = 1.5 MHz to 350 MHz
•
Output frequency range (fOUT_CCC) = 0.75 MHz to 350 MHz
•
Clock delay adjustment via programmable and fixed delays from –7.56 ns to +11.12 ns
•
2 programmable delay types for clock skew minimization
•
Clock frequency synthesis (for PLL only)
Additional CCC specifications:
•
Internal phase shift = 0°, 90°, 180°, and 270°. Output phase shift depends on the output divider
configuration (for PLL only).
•
Output duty cycle = 50% ± 1.5% or better (for PLL only)
•
Low output jitter: worst case < 2.5% × clock period peak-to-peak period jitter when single global
network used (for PLL only)
•
Maximum acquisition time = 300 µs (for PLL only)
•
Low power consumption of 5 mW
•
Exceptional tolerance to input period jitter—allowable input jitter is up to 1.5 ns (for PLL only)
•
Four precise phases; maximum misalignment between adjacent phases of 40 ps × (350 MHz /
fOUT_CCC) (for PLL only)
Global Clocking
ProASIC3 nano devices have extensive support for multiple clocking domains. In addition to the CCC
and PLL support described above, there is a comprehensive global clock distribution network.
Each VersaTile input and output port has access to nine VersaNets: six chip (main) and three quadrant
global networks. The VersaNets can be driven by the CCC or directly accessed from the core via
multiplexers (MUXes). The VersaNets can be used to distribute low-skew clock signals or for rapid
distribution of high fanout nets.
1- 6
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
I/Os with Advanced I/O Standards
ProASIC3 nano FPGAs feature a flexible I/O structure, supporting a range of voltages (1.5 V, 1.8 V,
2.5 V, and 3.3 V).
The I/Os are organized into banks, with two, three, or four banks per device. The configuration of these
banks determines the I/O standards supported.
Each I/O module contains several input, output, and enable registers. These registers allow the
implementation of various single-data-rate applications for all versions of nano devices and double-datarate applications for the A3PN060, A3PN125, and A3PN250 devices.
ProASIC3 nano devices support LVTTL and LVCMOS I/O standards, are hot-swappable, and support
cold-sparing and Schmitt trigger.
Hot-swap (also called hot-plug, or hot-insertion) is the operation of hot-insertion or hot-removal of a card
in a powered-up system.
Cold-sparing (also called cold-swap) refers to the ability of a device to leave system data undisturbed
when the system is powered up, while the component itself is powered down, or when power supplies
are floating.
Wide Range I/O Support
ProASIC3 nano devices support JEDEC-defined wide range I/O operation. ProASIC3 nano supports the
JESD8-B specification, covering both 3 V and 3.3 V supplies, for an effective operating range of 2.7 V to
3.6 V.
Wider I/O range means designers can eliminate power supplies or power conditioning components from
the board or move to less costly components with greater tolerances. Wide range eases I/O bank
management and provides enhanced protection from system voltage spikes, while providing the flexibility
to easily run custom voltage applications.
Specifying I/O States During Programming
You can modify the I/O states during programming in FlashPro. In FlashPro, this feature is supported for
PDB files generated from Designer v8.5 or greater. See the FlashPro User’s Guide for more information.
Note: PDB files generated from Designer v8.1 to Designer v8.4 (including all service packs) have
limited display of Pin Numbers only.
1. Load a PDB from the FlashPro GUI. You must have a PDB loaded to modify the I/O states during
programming.
2. From the FlashPro GUI, click PDB Configuration. A FlashPoint – Programming File Generator
window appears.
3. Click the Specify I/O States During Programming button to display the Specify I/O States During
Programming dialog box.
4. Sort the pins as desired by clicking any of the column headers to sort the entries by that header.
Select the I/Os you wish to modify (Figure 1-6 on page 1-8).
5. Set the I/O Output State. You can set Basic I/O settings if you want to use the default I/O settings
for your pins, or use Custom I/O settings to customize the settings for each pin. Basic I/O state
settings:
1 – I/O is set to drive out logic High
0 – I/O is set to drive out logic Low
Last Known State – I/O is set to the last value that was driven out prior to entering the
programming mode, and then held at that value during programming
R ev i si o n 1 1
1 -7
ProASIC3 nano Device Overview
Z -Tri-State: I/O is tristated
Figure 1-6 •
I/O States During Programming Window
6. Click OK to return to the FlashPoint – Programming File Generator window.
I/O States During programming are saved to the ADB and resulting programming files after completing
programming file generation.
1- 8
R ev isio n 1 1
2 – ProASIC3 nano DC and Switching Characteristics
General Specifications
The Z feature grade does not support the enhanced nano features of Schmitt trigger input, cold-sparing,
and hot-swap I/O capability. Refer to the "ProASIC3 nano Ordering Information" section on page III for
more information.
DC and switching characteristics for –F speed grade targets are based only on simulation.
The characteristics provided for the –F speed grade are subject to change after establishing FPGA
specifications. Some restrictions might be added and will be reflected in future revisions of this
document. The –F speed grade is only supported in the commercial temperature range.
Operating Conditions
Stresses beyond those listed in Table 2-1 may cause permanent damage to the device.
Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Absolute Maximum Ratings are stress ratings only; functional operation of the device at these or any
other conditions beyond those listed under the Recommended Operating Conditions specified in
Table 2-2 on page 2-2 is not implied.
Table 2-1 • Absolute Maximum Ratings
Symbol
Parameter
Limits
Units
VCC
DC core supply voltage
–0.3 to 1.65
V
VJTAG
JTAG DC voltage
–0.3 to 3.75
V
VPUMP
Programming voltage
–0.3 to 3.75
V
VCCPLL
Analog power supply (PLL)
–0.3 to 1.65
V
VCCI
DC I/O output buffer supply voltage
–0.3 to 3.75
V
VI
I/O input voltage
–0.3 V to 3.6 V
V
TSTG 1
Storage temperature
–65 to +150
°C
1
Junction temperature
+125
°C
TJ
Notes:
1. For flash programming and retention maximum limits, refer to Table 2-3 on page 2-2, and for recommended operating
limits, refer to Table 2-2 on page 2-2.
2. VMV pins must be connected to the corresponding VCCI pins. See the "VMVx I/O Supply Voltage (quiet)" section on
page 3-1 for further information.
3. The device should be operated within the limits specified by the datasheet. During transitions, the input signal may
undershoot or overshoot according to the limits shown in Table 2-4 on page 2-3.
R ev i si o n 1 1
2 -1
ProASIC3 nano DC and Switching Characteristics
Table 2-2 • Recommended Operating Conditions 1, 2
Symbol
TA
–20 to +85
–40 to +100
°C
1.425 to 1.575
1.425 to 1.575
V
1.4 to 3.6
1.4 to 3.6
V
3.15 to 3.45
3.15 to 3.45
V
0 to 3.6
0 to 3.6
V
1.425 to 1.575
1.425 to 1.575
V
1.425 to 1.575
1.425 to 1.575
V
1.8 V DC supply voltage
1.7 to 1.9
1.7 to 1.9
V
2.5 V DC supply voltage
2.3 to 2.7
2.3 to 2.7
V
1.5 V DC core supply voltage
VJTAG
JTAG DC voltage
VPUMP 4
Programming voltage
Programming Mode
Operation
VCCPLL
6
Analog power supply (PLL)
4
5
1.5 V DC core supply voltage
VCCI and 1.5 V DC supply voltage
VMV 7
3
2
Units
°C
–20 to +70
Junction temperature
3
Industrial
2
Ambient temperature
TJ
VCC
Extended
Commercial
Parameter
–40 to +85
3.3 V DC supply voltage
3.0 to 3.6
3.0 to 3.6
V
3.3 V Wide Range supply voltage 8
2.7 to 3.6
2.7 to 3.6
V
Notes:
1. All parameters representing voltages are measured with respect to GND unless otherwise specified.
2. To ensure targeted reliability standards are met across ambient and junction operating temperatures, Microsemi
recommends that the user follow best design practices using Microsemi’s timing and power simulation tools.
3. The ranges given here are for power supplies only. The recommended input voltage ranges specific to each I/O
standard are given in Table 2-14 on page 2-16. VMV and VCCI should be at the same voltage within a given I/O bank.
4. The programming temperature range supported is Tambient = 0°C to 85°C.
5. VPUMP can be left floating during operation (not programming mode).
6. VCCPLL pins should be tied to VCC pins. See the "Pin Descriptions and Packaging" chapter for further information.
7. VMV pins must be connected to the corresponding VCCI pins. See the "Pin Descriptions and Packaging" chapter for
further information.
8. 3.3 V Wide Range is compliant to the JESD8-B specification and supports 3.0 V VCCI operation.
Table 2-3 • Flash Programming Limits – Retention, Storage and Operating Temperature1
Product
Grade
Commercial
Industrial
Maximum Operating
Programming Program Retention
Maximum Storage
Cycles
(biased/unbiased) Temperature TSTG (°C) 2 Junction Temperature TJ (°C) 2
500
20 years
110
100
500
20 years
110
100
Notes:
1. This is a stress rating only; functional operation at any condition other than those indicated is not implied.
2. These limits apply for program/data retention only. Refer to Table 2-1 on page 2-1 and Table 2-2 for device operating
conditions and absolute limits.
2- 2
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-4 • Overshoot and Undershoot Limits 1
VCCI and VMV
Average VCCI–GND Overshoot or Undershoot
Duration as a Percentage of Clock Cycle 2
Maximum Overshoot/
Undershoot 2
10%
1.4 V
5%
1.49 V
2.7 V or less
3V
3.3 V
3.6 V
10%
1.1 V
5%
1.19 V
10%
0.79 V
5%
0.88 V
10%
0.45 V
5%
0.54 V
Notes:
1. Based on reliability requirements at 85°C.
2. The duration is allowed at one out of six clock cycles. If the overshoot/undershoot occurs at one out of two cycles, the
maximum overshoot/undershoot has to be reduced by 0.15 V.
I/O Power-Up and Supply Voltage Thresholds for Power-On Reset
(Commercial and Industrial)
Sophisticated power-up management circuitry is designed into every ProASIC®3 device. These circuits
ensure easy transition from the powered-off state to the powered-up state of the device. The many
different supplies can power up in any sequence with minimized current spikes or surges. In addition, the
I/O will be in a known state through the power-up sequence. The basic principle is shown in Figure 2-1
on page 2-4.
There are five regions to consider during power-up.
ProASIC3 I/Os are activated only if ALL of the following three conditions are met:
1. VCC and VCCI are above the minimum specified trip points (Figure 2-1 on page 2-4).
2. VCCI > VCC – 0.75 V (typical)
3. Chip is in the operating mode.
VCCI Trip Point:
Ramping up: 0.6 V < trip_point_up < 1.2 V
Ramping down: 0.5 V < trip_point_down < 1.1 V
VCC Trip Point:
Ramping up: 0.6 V < trip_point_up < 1.1 V
Ramping down: 0.5 V < trip_point_down < 1 V
VCC and VCCI ramp-up trip points are about 100 mV higher than ramp-down trip points. This specifically
built-in hysteresis prevents undesirable power-up oscillations and current surges. Note the following:
•
During programming, I/Os become tristated and weakly pulled up to VCCI.
•
JTAG supply, PLL power supplies, and charge pump VPUMP supply have no influence on I/O
behavior.
PLL Behavior at Brownout Condition
Microsemi recommends using monotonic power supplies or voltage regulators to ensure proper powerup behavior. Power ramp-up should be monotonic at least until VCC and VCCPLLX exceed brownout
activation levels. The VCC activation level is specified as 1.1 V worst-case (see Figure 2-1 on page 2-4
for more details).
When PLL power supply voltage and/or VCC levels drop below the VCC brownout levels (0.75 V ±
0.25 V), the PLL output lock signal goes low and/or the output clock is lost. Refer to the
"Power-Up/-Down Behavior of Low Power Flash Devices" chapter of the ProASIC3 nano FPGA Fabric
User’s Guide for information on clock and lock recovery.
R ev i si o n 1 1
2 -3
ProASIC3 nano DC and Switching Characteristics
Internal Power-Up Activation Sequence
1. Core
2. Input buffers
3. Output buffers, after 200 ns delay from input buffer activation
VCC = VCCI + VT
where VT can be from 0.58 V to 0.9 V (typically 0.75 V)
VCC
VCC = 1.575 V
Region 1: I/O Buffers are OFF
Region 4: I/O
buffers are ON.
I/Os are functional
but slower because VCCI
is below specification. For the
same reason, input buffers do
Region 5: I/O buffers are ON
and power supplies are within
specification.
I/Os meet the entire datasheet
and timer specifications for
speed, VIH / VIL , VOH / VOL , etc.
not meet VIH / VIL levels, and output
buffers do not meet VOH/VOL levels.
VCC = 1.425 V
Region 2: I/O buffers are ON.
I/Os are functional but slower because
VCCI / VCC are below specification.
For the same reason, input
buffers do not meet VIH / VIL levels, and
output buffers do not meet VOH / VOL levels.
Activation trip point:
Va = 0.85 V ± 0.25 V
Deactivation trip point:
Vd = 0.75 V ± 0.25 V
Region 1: I/O buffers are OFF
Activation trip point:
Va = 0.9 V ± 0.3 V
Deactivation trip point:
Vd = 0.8 V ± 0.3 V
Figure 2-1 •
2- 4
Region 3: I/O buffers are ON.
I/Os are functional; I/O DC
specifications are met,
but I/Os are slower because
the VCC is below specification.
Min VCCI datasheet specification
voltage at a selected I/O
standard; i.e., 1.425 V or 1.7 V
or 2.3 V or 3.0 V
I/O State as a Function of VCCI and VCC Voltage Levels
R ev isio n 1 1
VCCI
ProASIC3 nano Flash FPGAs
Thermal Characteristics
Introduction
The temperature variable in the Designer software refers to the junction temperature, not the ambient
temperature. This is an important distinction because dynamic and static power consumption cause the
chip junction to be higher than the ambient temperature.
EQ 1 can be used to calculate junction temperature.
TJ = Junction Temperature = T + TA
EQ 1
where:
TA = Ambient Temperature
T = Temperature gradient between junction (silicon) and ambient T = ja * P
ja = Junction-to-ambient of the package. ja numbers are located in Table 2-5.
P = Power dissipation
Package Thermal Characteristics
The device junction-to-case thermal resistivity is jc and the junction-to-ambient air thermal resistivity is
ja. The thermal characteristics for ja are shown for two air flow rates. The absolute maximum junction
temperature is 100°C. EQ 2 shows a sample calculation of the absolute maximum power dissipation
allowed for a 484-pin FBGA package at commercial temperature and in still air.
·
junction temp. (C) – Max. ambient temp. (C)- = 100C – 70C = 1.463 W
----------------------------------------------------------------------------------------------------------------------------------------Maximum Power Allowed = Max.
------------------------------------20.5C/W
 ja (C/W)
EQ 2
Table 2-5 • Package Thermal Resistivities
ja
Package Type
Quad Flat No Lead (QFN)
Very Thin Quad Flat Pack (VQFP)
Device
Pin Count
jc
All devices
48
TBD
TBD
TBD
TBD
C/W
68
TBD
TBD
TBD
TBD
C/W
100
TBD
TBD
TBD
TBD
C/W
100
10.0
35.3
29.4
27.1
C/W
All devices
Still Air 200 ft./min.
500 ft./min. Units
Temperature and Voltage Derating Factors
Table 2-6 • Temperature and Voltage Derating Factors for Timing Delays
(normalized to TJ = 70°C, VCC = 1.425 V)
Junction Temperature (°C)
Array Voltage VCC (V)
–40°C
–20°C
0°C
25°C
70°C
85°C
100°C
1.425
0.968
0.973
0.979
0.991
1.000
1.006
1.013
1.500
0.888
0.894
0.899
0.910
0.919
0.924
0.930
1.575
0.836
0.841
0.845
0.856
0.864
0.870
0.875
R ev i si o n 1 1
2 -5
ProASIC3 nano DC and Switching Characteristics
Calculating Power Dissipation
Quiescent Supply Current
Table 2-7 • Quiescent Supply Current Characteristics
A3PN010
A3PN015
A3PN020
A3PN060
A3PN125
A3PN250
600 µA
1 mA
1 mA
2 mA
2 mA
3 mA
Max. (Commercial)
5 mA
5 mA
5 mA
10 mA
10 mA
20 mA
Max. (Industrial)
8 mA
8 mA
8 mA
15 mA
15 mA
30 mA
Typical (25°C)
Note: IDD includes VCC, VPUMP, and VCCI, currents.
Power per I/O Pin
Table 2-8 • Summary of I/O Input Buffer Power (Per Pin) – Default I/O Software Settings
VCCI (V)
Dynamic Power, PAC9 (µW/MHz)1
3.3 V LVTTL / 3.3 V LVCMOS
3.3
16.45
3.3 V LVTTL / 3.3 V LVCMOS – Schmitt Trigger
3.3
18.93
3.3 V LVCMOS wide range2
3.3
16.45
3.3 V LVCMOS wide range – Schmitt Trigger
3.3
18.93
2.5 V LVCMOS
2.5
4.73
2.5 V LVCMOS – Schmitt Trigger
2.5
6.14
1.8 V LVCMOS
1.8
1.68
1.8 V LVCMOS – Schmitt Trigger
1.8
1.80
1.5 V LVCMOS (JESD8-11)
1.5
0.99
1.5 V LVCMOS (JESD8-11) – Schmitt Trigger
1.5
0.96
Single-Ended
Notes:
1. PAC9 is the total dynamic power measured on VCCI.
2. All LVCMOS 3.3 V software macros support LVCMOS 3.3 V wide range as specified in the JESD8-B
specification.
2- 6
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-9 • Summary of I/O Output Buffer Power (per pin) – Default I/O Software Settings1
CLOAD (pF) 2
VCCI (V)
Dynamic Power, PAC10 (µW/MHz)3
10
3.3
162.01
10
3.3
162.01
2.5 V LVCMOS
10
2.5
91.96
1.8 V LVCMOS
10
1.8
46.95
1.5 V LVCMOS (JESD8-11)
10
1.5
32.22
Single-Ended
3.3 V LVTTL / 3.3 V LVCMOS
3.3 V LVCMOS wide range
4
Notes:
1. Dynamic power consumption is given for standard load and software default drive strength and output
slew.
2. Values for A3PN020, A3PN015, and A3PN010. A3PN060, A3PN125, and A3PN250 correspond to a
default loading of 35 pF.
3. PAC10 is the total dynamic power measured on VCCI.
4. All LVCMOS3.3 V software macros support LVCMOS 3.3 V wide range as specified in the JESD8-B
specification.
R ev i si o n 1 1
2 -7
ProASIC3 nano DC and Switching Characteristics
Power Consumption of Various Internal Resources
Table 2-10 • Different Components Contributing to Dynamic Power Consumption in ProASIC3 nano Devices
A3PN250
A3PN125
A3PN060
A3PN020
A3PN015
A3PN010
Device Specific Dynamic Contributions
(µW/MHz)
PAC1
Clock contribution of a Global Rib
11.03
11.03
9.3
9.3
9.3
9.3
PAC2
Clock contribution of a Global Spine
1.58
0.81
0.81
0.4
0.4
0.4
PAC3
Clock contribution of a VersaTile row
0.81
PAC4
Clock contribution of a VersaTile used as a
sequential module
0.12
PAC5
First contribution of a VersaTile used as a
sequential module
0.07
PAC6
Second contribution of a VersaTile used as a
sequential module
0.29
PAC7
Contribution of a VersaTile used as a
combinatorial Module
0.29
PAC8
Average contribution of a routing net
0.70
PAC9
Contribution of an I/O input pin
(standard-dependent)
See Table 2-8 on page 2-6.
PAC10
Contribution of an I/O output pin
(standard-dependent)
See Table 2-9 on page 2-7.
PAC11
Average contribution of a RAM block during a read
operation
25.00
N/A
PAC12
Average contribution of a RAM block during a write
operation
30.00
N/A
PAC13
Dynamic contribution for PLL
2.60
N/A
Parameter
Definition
Note: For a different output load, drive strength, or slew rate, Microsemi recommends using the Microsemi Power
spreadsheet calculator or SmartPower tool in Libero SoC.
Table 2-11 • Different Components Contributing to the Static Power Consumption in ProASIC3 nano Devices
PDC1
Array static power in Active mode
PDC4
Static PLL
contribution 1
PDC5
Bank quiescent power (VCCI-dependent)
A3PN010
A3PN015
A3PN020
A3PN060
Definition
A3PN125
Parameter
A3PN250
Device Specific Static Power (mW)
See Table 2-7 on page 2-6.
2.55
N/A
See Table 2-7 on page 2-6.
Notes:
1. Minimum contribution of the PLL when running at lowest frequency.
2. For a different output load, drive strength, or slew rate, Microsemi recommends using the Microsemi Power spreadsheet
calculator or SmartPower tool in Libero SoC.
2- 8
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
Power Calculation Methodology
This section describes a simplified method to estimate power consumption of an application. For more
accurate and detailed power estimations, use the SmartPower tool in Libero SoC.
The power calculation methodology described below uses the following variables:
•
The number of PLLs as well as the number and the frequency of each output clock generated
•
The number of combinatorial and sequential cells used in the design
•
The internal clock frequencies
•
The number and the standard of I/O pins used in the design
•
The number of RAM blocks used in the design
•
Toggle rates of I/O pins as well as VersaTiles—guidelines are provided in Table 2-12 on
page 2-11.
•
Enable rates of output buffers—guidelines are provided for typical applications in Table 2-13 on
page 2-11.
•
Read rate and write rate to the memory—guidelines are provided for typical applications in
Table 2-13 on page 2-11. The calculation should be repeated for each clock domain defined in the
design.
Methodology
Total Power Consumption—PTOTAL
PTOTAL = PSTAT + PDYN
PSTAT is the total static power consumption.
PDYN is the total dynamic power consumption.
Total Static Power Consumption—PSTAT
PSTAT = PDC1 + NINPUTS* PDC2 + NOUTPUTS* PDC3
NINPUTS is the number of I/O input buffers used in the design.
NOUTPUTS is the number of I/O output buffers used in the design.
Total Dynamic Power Consumption—PDYN
PDYN = PCLOCK + PS-CELL + PC-CELL + PNET + PINPUTS + POUTPUTS + PMEMORY + PPLL
Global Clock Contribution—PCLOCK
PCLOCK = (PAC1 + NSPINE*PAC2 + NROW*PAC3 + NS-CELL* PAC4) * FCLK
NSPINE is the number of global spines used in the user design—guidelines are provided in the "Spine
Architecture" section of the Global Resources chapter in the ProASIC3 nano FPGA Fabric User's
Guide.
NROW is the number of VersaTile rows used in the design—guidelines are provided in the "Spine
Architecture" section of the Global Resources chapter in the ProASIC3 nano FPGA Fabric User's
Guide.
FCLK is the global clock signal frequency.
NS-CELL is the number of VersaTiles used as sequential modules in the design.
PAC1, PAC2, PAC3, and PAC4 are device-dependent.
Sequential Cells Contribution—PS-CELL
PS-CELL = NS-CELL * (PAC5 + 1 / 2 * PAC6) * FCLK
NS-CELL is the number of VersaTiles used as sequential modules in the design. When a multi-tile
sequential cell is used, it should be accounted for as 1.
1 is the toggle rate of VersaTile outputs—guidelines are provided in Table 2-12 on page 2-11.
FCLK is the global clock signal frequency.
R ev i si o n 1 1
2 -9
ProASIC3 nano DC and Switching Characteristics
Combinatorial Cells Contribution—PC-CELL
PC-CELL = NC-CELL* 1 / 2 * PAC7 * FCLK
NC-CELL is the number of VersaTiles used as combinatorial modules in the design.
1 is the toggle rate of VersaTile outputs—guidelines are provided in Table 2-12 on page 2-11.
FCLK is the global clock signal frequency.
Routing Net Contribution—PNET
PNET = (NS-CELL + NC-CELL) * 1 / 2 * PAC8 * FCLK
NS-CELL is the number of VersaTiles used as sequential modules in the design.
NC-CELL is the number of VersaTiles used as combinatorial modules in the design.
1 is the toggle rate of VersaTile outputs—guidelines are provided in Table 2-12 on page 2-11.
FCLK is the global clock signal frequency.
I/O Input Buffer Contribution—PINPUTS
PINPUTS = NINPUTS * 2 / 2 * PAC9 * FCLK
NINPUTS is the number of I/O input buffers used in the design.
2 is the I/O buffer toggle rate—guidelines are provided in Table 2-12 on page 2-11.
FCLK is the global clock signal frequency.
I/O Output Buffer Contribution—POUTPUTS
POUTPUTS = NOUTPUTS * 2 / 2 * 1 * PAC10 * FCLK
NOUTPUTS is the number of I/O output buffers used in the design.
2 is the I/O buffer toggle rate—guidelines are provided in Table 2-12 on page 2-11.
1 is the I/O buffer enable rate—guidelines are provided in Table 2-13 on page 2-11.
FCLK is the global clock signal frequency.
RAM Contribution—PMEMORY
PMEMORY = PAC11 * NBLOCKS * FREAD-CLOCK * 2 + PAC12 * NBLOCK * FWRITE-CLOCK * 3
NBLOCKS is the number of RAM blocks used in the design.
FREAD-CLOCK is the memory read clock frequency.
2 is the RAM enable rate for read operations.
FWRITE-CLOCK is the memory write clock frequency.
3 is the RAM enable rate for write operations—guidelines are provided in Table 2-13 on page 2-11.
PLL Contribution—PPLL
PPLL = PDC4 + PAC13 * FCLKOUT
FCLKOUT is the output clock frequency.1
1.
2- 10
The PLL dynamic contribution depends on the input clock frequency, the number of output clock signals generated by the
PLL, and the frequency of each output clock. If a PLL is used to generate more than one output clock, include each output
clock in the formula by adding its corresponding contribution (PAC14 * FCLKOUT product) to the total PLL contribution.
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Guidelines
Toggle Rate Definition
A toggle rate defines the frequency of a net or logic element relative to a clock. It is a percentage. If the
toggle rate of a net is 100%, this means that this net switches at half the clock frequency. Below are
some examples:
•
The average toggle rate of a shift register is 100% because all flip-flop outputs toggle at half of the
clock frequency.
•
The average toggle rate of an 8-bit counter is 25%:
–
Bit 0 (LSB) = 100%
–
Bit 1
= 50%
–
Bit 2
= 25%
–
…
–
Bit 7 (MSB) = 0.78125%
–
Average toggle rate = (100% + 50% + 25% + 12.5% + . . . + 0.78125%) / 8
Enable Rate Definition
Output enable rate is the average percentage of time during which tristate outputs are enabled. When
nontristate output buffers are used, the enable rate should be 100%.
Table 2-12 • Toggle Rate Guidelines Recommended for Power Calculation
Component
1
2
Definition
Guideline
Toggle rate of VersaTile outputs
10%
I/O buffer toggle rate
10%
Table 2-13 • Enable Rate Guidelines Recommended for Power Calculation
Component
1
2
3
Definition
Guideline
I/O output buffer enable rate
100%
RAM enable rate for read operations
12.5%
RAM enable rate for write operations
12.5%
R ev i si o n 1 1
2- 11
ProASIC3 nano DC and Switching Characteristics
User I/O Characteristics
Timing Model
I/O Module
(Non-Registered)
Combinational Cell
Combinational Cell
Y
LVCMOS 2.5V Output Drive
Strength = 8 mA High Slew Rate
Y
tPD = 0.56 ns
tPD = 0.49 ns
tDP = 2.25 ns
I/O Module
(Non-Registered)
Combinational Cell
Y
tDP = 2.87 ns
tPD = 0.87 ns
I/O Module
(Non-Registered)
Combinational Cell
I/O Module
(Registered)
Y
tPY = 1.04 ns
Input LVCMOS 2.5 V
D
LVTTL Output drive strength = 4 mA
High slew rate
tPD = 0.51 ns
Q
I/O Module
(Non-Registered)
Combinational Cell
Y
tICLKQ = 0.24 ns
tISUD = 0.26 ns
LVCMOS 1.5 V Output drive strength = 2 mA
High slew rate
tDP = 3.02 ns
tPD = 0.47 ns
Input LVTTL
Clock
Register Cell
tPY = 0.84 ns
D
Combinational Cell
Y
Q
I/O Module
(Non-Registered)
tPY = 1.14 ns
Figure 2-2 •
2- 12
I/O Module
(Registered)
Register Cell
D
Q
D
tPD = 0.47 ns
tCLKQ = 0.55 ns
tSUD = 0.43 ns
LVCMOS 1.5 V
LVTTL Output drive strength = 8 mA
High slew rate
tDP = 2.21 ns
Q
tDP = 2.21 ns
tCLKQ = 0.55 ns
tSUD = 0.43 ns
Input LVTTL
Clock
Input LVTTL
Clock
tPY = 0.84 ns
tPY = 0.84 ns
LVTTL 3.3 V Output drive
strength = 8 mA High slew rate
tOCLKQ = 0.59 ns
tOSUD = 0.31 ns
Timing Model
Operating Conditions: –2 Speed, Commercial Temperature Range (TJ = 70°C), Worst Case
VCC = 1.425 V, with Default Loading at 10 pF
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
tPY
tDIN
D
PAD
Q
DIN
Y
CLK
tPY = MAX(tPY(R), tPY(F))
tDIN = MAX(tDIN(R), tDIN(F))
To Array
I/O Interface
VIH
PAD
Vtrip
Vtrip
VIL
VCC
50%
50%
Y
GND
tPY
(F)
tPY
(R)
VCC
50%
DIN
GND
50%
tDIN
tDIN
(R)
Figure 2-3 •
(F)
Input Buffer Timing Model and Delays (example)
R ev i si o n 1 1
2- 13
ProASIC3 nano DC and Switching Characteristics
tDOUT
tDP
D Q
D
PAD
DOUT
Std
Load
CLK
From Array
tDP = MAX(tDP(R), tDP(F))
tDOUT = MAX(tDOUT(R), tDOUT(F))
I/O Interface
tDOUT
(R)
D
50%
tDOUT
VCC
(F)
50%
0V
VCC
DOUT
50%
50%
0V
VOH
Vtrip
Vtrip
VOL
PAD
tDP
(R)
Figure 2-4 •
2- 14
Output Buffer Model and Delays (example)
R ev i sio n 1 1
tDP
(F)
ProASIC3 nano Flash FPGAs
tEOUT
D
Q
CLK
E
tZL, tZH, tHZ, tLZ, tZLS, tZHS
EOUT
D
Q
PAD
DOUT
CLK
D
tEOUT = MAX(tEOUT(r), tEOUT(f))
I/O Interface
VCC
D
VCC
50%
tEOUT (F)
50%
E
tEOUT (R)
VCC
50%
EOUT
tZL
PAD
50%
50%
tHZ
Vtrip
tZH
50%
tLZ
VCCI
90% VCCI
Vtrip
VOL
10% VCCI
VCC
D
VCC
E
50%
tEOUT (R)
50%
tEOUT (F)
VCC
EOUT
PAD
50%
tZLS
VOH
Vtrip
Figure 2-5 •
50%
50%
tZHS
Vtrip
VOL
Tristate Output Buffer Timing Model and Delays (example)
R ev i si o n 1 1
2- 15
ProASIC3 nano DC and Switching Characteristics
Overview of I/O Performance
Summary of I/O DC Input and Output Levels – Default I/O Software
Settings
Table 2-14 • Summary of Maximum and Minimum DC Input and Output Levels
Applicable to Commercial and Industrial Conditions—Software Default Settings
Equivalent
Software
Default
Drive
Drive
Strength Slew Min.
I/O Standard Strength Option2 Rate V
VIL
VIH
VOL
VOH
IOL1 IOH1
mA mA
Max
V
Min.
V
Max.
V
Max. V
Min.
V
2.4
3.3 V LVTTL/
3.3 V
LVCMOS
8 mA
8 mA
High –0.3
0.8
2
3.6
0.4
8
8
3.3 V
LVCMOS
Wide Range
100 µA
8 mA
High –0.3
0.8
2
3.6
0.2
2.5 V
LVCMOS
8 mA
8 mA
High –0.3
0.7
1.7
3.6
0.7
1.7
8
8
1.8 V
LVCMOS
4 mA
4 mA
High –0.3 0.35 * VCCI 0.65 * VCCI 3.6
0.45
VCCI – 0.45
4
4
1.5 V
LVCMOS
2 mA
2 mA
High –0.3 0.35 * VCCI 0.65 * VCCI 3.6 0.25 * VCCI 0.75 * VCCI
2
2
VCCI – 0.2 100 100
µA µA
Notes:
1. Currents are measured at 85°C junction temperature.
2. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models .
3. All LVCMOS 3.3 V software macros support LVCMOS 3.3 V wide range, as specified in the JESD8-B specification.
Table 2-15 • Summary of Maximum and Minimum DC Input Levels
Applicable to Commercial and Industrial Conditions
Commercial 1
DC I/O Standards
Industrial 2
IIL 3
IIH 4
IIL 3
IIH 4
µA
µA
µA
µA
3.3 V LVTTL / 3.3 V LVCMOS
10
10
15
15
3.3 V LVCMOS Wide Range
10
10
15
15
2.5 V LVCMOS
10
10
15
15
1.8 V LVCMOS
10
10
15
15
1.5 V LVCMOS
10
10
15
15
Notes:
1.
2.
3.
4.
2- 16
Commercial range (–20°C < TA < 70°C)
Industrial range (–40°C < TA < 85°C)
IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Summary of I/O Timing Characteristics – Default I/O Software Settings
Table 2-16 • Summary of AC Measuring Points
Standard
Measuring Trip Point (Vtrip)
3.3 V LVTTL / 3.3 V LVCMOS
1.4 V
3.3 V LVCMOS Wide Range
1.4 V
2.5 V LVCMOS
1.2 V
1.8 V LVCMOS
0.90 V
1.5 V LVCMOS
0.75 V
Table 2-17 • I/O AC Parameter Definitions
Parameter
Parameter Definition
tDP
Data to Pad delay through the Output Buffer
tPY
Pad to Data delay through the Input Buffer
tDOUT
Data to Output Buffer delay through the I/O interface
tEOUT
Enable to Output Buffer Tristate Control delay through the I/O interface
tDIN
Input Buffer to Data delay through the I/O interface
tHZ
Enable to Pad delay through the Output Buffer—HIGH to Z
tZH
Enable to Pad delay through the Output Buffer—Z to HIGH
tLZ
Enable to Pad delay through the Output Buffer—LOW to Z
tZL
Enable to Pad delay through the Output Buffer—Z to LOW
tZHS
Enable to Pad delay through the Output Buffer with delayed enable—Z to HIGH
tZLS
Enable to Pad delay through the Output Buffer with delayed enable—Z to LOW
R ev i si o n 1 1
2- 17
ProASIC3 nano DC and Switching Characteristics
tDP (ns)
tDIN (ns)
tPYS (ns)
tE O U T (ns)
tZL (ns)
35
0.60
4.57
0.04 1.13
1.52
0.43
4.64 3.92 2.60 3.14
3.3 V LVCMOS
Wide Range
100 µA 8 mA
High
35
0.60
6.78
0.04 1.57
2.18
0.43
6.78 5.72 3.72 4.35
tHZ (ns)
tDOUT (ns)
High
tLZ (ns)
Capacitive Load (pF)
8 mA
tZH (ns)
Slew Rate
8
3.3 V LVTTL /
3.3 V LVCMOS
tPY (ns)
Equivalent Software Default
Drive Strength Option1
I/O Standard
Drive Strength (mA)
Table 2-18 • Summary of I/O Timing Characteristics—Software Default Settings (at 35 pF)
STD Speed Grade, Commercial-Case Conditions: TJ = 70°C, Worst Case VCC = 1.425 V
For A3PN060, A3PN125, and A3PN250
2.5 V LVCMOS
8
8 mA
High
35
0.60
4.94
0.04 1.43
1.63
0.43
4.71 4.94 2.60 2.98
1.8 V LVCMOS
4
4 mA
High
35
0.60
6.53
0.04 1.35
1.90
0.43
5.53 6.53 2.62 2.89
1.5 V LVCMOS
2
2 mA
High
35
0.60
7.86
0.04 1.56
2.14
0.43
6.45 7.86 2.66 2.83
Notes:
1. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
2. All LVCMOS 3.3 V software macros support LVCMOS 3.3 V wide range, as specified in the JESD8-B specification.
3. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Capacitive Load (pF)
tDOUT (ns)
tDP (ns)
tDIN (ns)
tPY (ns)
tPYS (ns)
tEO UT (ns)
tZL (ns)
tZH (ns)
tLZ (ns)
tHZ (ns)
3.3 V LVCMOS
Wide Range
Slew Rate
3.3 V LVTTL /
3.3 V LVCMOS
Equivalent Software Default
Drive Strength Option1
I/O Standard
Drive Strength (mA)
Table 2-19 • Summary of I/O Timing Characteristics—Software Default Settings (at 10 pF)
STD Speed Grade, Commercial-Case Conditions: TJ = 70°C, Worst Case VCC = 1.425 V
For A3PN020, A3PN015, and A3PN010
8
8 mA
High
10
0.60
2.73
0.04
1.13
1.52
0.43
2.77
2.23
2.60
3.14
100 µA 8 mA
High
10
0.60
3.94
0.04
1.57
2.18
0.43
3.94
3.16
3.72
4.35
2.5 V LVCMOS
8
8 mA
High
10
0.60
2.76
0.04
1.43
1.63
0.43
2.80
2.60
2.60
2.98
1.8 V LVCMOS
4
4 mA
High
10
0.60
3.22
0.04
1.35
1.90
0.43
3.24
3.22
2.62
2.89
1.5 V LVCMOS
2
2 mA
High
10
0.60
3.76
0.04
1.56
2.14
0.43
3.74
3.76
2.66
2.83
Notes:
1. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
2. All LVCMOS 3.3 V software macros support LVCMOS 3.3 V wide range, as specified in the JESD8-B specification.
3. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 18
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Detailed I/O DC Characteristics
Table 2-20 • Input Capacitance
Symbol
Definition
Conditions
Min.
Max.
Units
CIN
Input capacitance
VIN = 0, f = 1.0 MHz
8
pF
CINCLK
Input capacitance on the clock pin
VIN = 0, f = 1.0 MHz
8
pF
Table 2-21 • I/O Output Buffer Maximum Resistances 1
Standard
3.3 V LVTTL / 3.3 V LVCMOS
Drive Strength
RPULL-DOWN
()2
RPULL-UP
()3
2 mA
100
300
4 mA
100
300
6 mA
50
150
50
150
8 mA
3.3 V LVCMOS Wide Range
100 µA
2.5 V LVCMOS
Same as equivalent
software default drive
2 mA
100
200
4 mA
100
200
6 mA
50
100
8 mA
50
100
1.8 V LVCMOS
2 mA
200
225
4 mA
100
112
1.5 V LVCMOS
2 mA
200
224
Notes:
1. These maximum values are provided for informational reasons only. Minimum output buffer resistance
values depend on VCCI, drive strength selection, temperature, and process. For board design
considerations and detailed output buffer resistances, use the corresponding IBIS models, located at
http://www.microsemi.com/soc/download/ibis/default.aspx.
2. R(PULL-DOWN-MAX) = (VOLspec) / IOLspec
3. R(PULL-UP-MAX) = (VCCImax – VOHspec) / IOHspec
Table 2-22 • I/O Weak Pull-Up/Pull-Down Resistances
Minimum and Maximum Weak Pull-Up/Pull-Down Resistance Values
R(WEAK PULL-UP)1
()
R(WEAK PULL-DOWN)2
()
VCCI
Min.
Max.
Min.
Max.
3.3 V
10 K
45 K
10 K
45 K
3.3 V (wide range I/Os)
10 K
45 K
10 K
45 K
2.5 V
11 K
55 K
12 K
74 K
1.8 V
18 K
70 K
17 K
110 K
1.5 V
19 K
90 K
19 K
140 K
Notes:
1. R(WEAK PULL-UP-MAX) = (VCCImax – VOHspec) / I(WEAK PULL-UP-MIN)
2. R(WEAK PULLDOWN-MAX) = (VOLspec) / I(WEAK PULLDOWN-MIN)
R ev i si o n 1 1
2- 19
ProASIC3 nano DC and Switching Characteristics
Table 2-23 • I/O Short Currents IOSH/IOSL
3.3 V LVTTL / 3.3 V LVCMOS
3.3 V LVCMOS Wide Range
2.5 V LVCMOS
1.8 V LVCMOS
1.5 V LVCMOS
Drive Strength
IOSL (mA)*
IOSH (mA)*
2 mA
25
27
4 mA
25
27
6 mA
51
54
8 mA
51
54
100 µA
Same as equivalent software
default drive
2 mA
16
18
4 mA
16
18
6 mA
32
37
8 mA
32
37
2 mA
9
11
4 mA
17
22
2 mA
13
16
Note: *TJ = 100°C
The length of time an I/O can withstand IOSH/IOSL events depends on the junction temperature. The
reliability data below is based on a 3.3 V, 8 mA I/O setting, which is the worst case for this type of
analysis.
For example, at 100°C, the short current condition would have to be sustained for more than six months
to cause a reliability concern. The I/O design does not contain any short circuit protection, but such
protection would only be needed in extremely prolonged stress conditions.
Table 2-24 • Duration of Short Circuit Event before Failure
Temperature
2- 20
Time before Failure
–40°C
> 20 years
–20°C
> 20 years
0°C
> 20 years
25°C
> 20 years
70°C
5 years
85°C
2 years
100°C
6 months
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-25 • Schmitt Trigger Input Hysteresis
Hysteresis Voltage Value (Typ.) for Schmitt Mode Input Buffers
Input Buffer Configuration
Hysteresis Value (typ.)
3.3 V LVTTL / LVCMOS (Schmitt trigger mode)
240 mV
2.5 V LVCMOS (Schmitt trigger mode)
140 mV
1.8 V LVCMOS (Schmitt trigger mode)
80 mV
1.5 V LVCMOS (Schmitt trigger mode)
60 mV
Table 2-26 • I/O Input Rise Time, Fall Time, and Related I/O Reliability
Input Buffer
Input Rise/Fall Time (min.)
Input Rise/Fall Time (max.)
Reliability
LVTTL/LVCMOS
(Schmitt trigger
disabled)
No requirement
10 ns *
20 years (100°C)
LVTTL/LVCMOS
(Schmitt trigger
enabled)
No requirement
No requirement, but input
noise voltage cannot exceed
Schmitt hysteresis
20 years (100°C)
Note: The maximum input rise/fall time is related to the noise induced into the input buffer trace. If the
noise is low, then the rise time and fall time of input buffers can be increased beyond the
maximum value. The longer the rise/fall times, the more susceptible the input signal is to the
board noise. Microsemi recommends signal integrity evaluation/characterization of the system to
ensure that there is no excessive noise coupling into input signals.
R ev i si o n 1 1
2- 21
ProASIC3 nano DC and Switching Characteristics
Single-Ended I/O Characteristics
3.3 V LVTTL / 3.3 V LVCMOS
Low-Voltage Transistor–Transistor Logic (LVTTL) is a general-purpose standard (EIA/JESD) for 3.3 V
applications. It uses an LVTTL input buffer and push-pull output buffer.
Table 2-27 • Minimum and Maximum DC Input and Output Levels
3.3 V LVTTL /
3.3 V LVCMOS
VIL
VIH
VOL
VOH
IOL IOH
IOSL
IOSH
IIL1 IIH2
mA mA
Max.
mA3
Max.
mA3
µA4 µA4
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
V
2 mA
–0.3
0.8
2
3.6
0.4
2.4
2
2
25
27
10
10
4 mA
–0.3
0.8
2
3.6
0.4
2.4
4
4
25
27
10
10
6 mA
–0.3
0.8
2
3.6
0.4
2.4
6
6
51
54
10
10
8 mA
–0.3
0.8
2
3.6
0.4
2.4
8
8
51
54
10
10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
R=1k
Test Point
Enable Path
Test Point
Datapath
Figure 2-6 •
35 pF
R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
35 pF for tZH / tZHS / tZL / tZLS
35 pF for tHZ / tLZ
AC Loading
Table 2-28 • 3.3 V LVTTL/LVCMOS AC Waveforms, Measuring Points, and Capacitive Loads
Input LOW (V)
0
Input HIGH (V)
Measuring Point* (V)
CLOAD (pF)
3.3
1.4
10
Notes:
1. Measuring point = Vtrip. See Table 2-16 on page 2-17 for a complete table of trip points.
2. Capacitive Load for A3PN060, A3PN125, and A3PN250 is 35 pF.
2- 22
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Timing Characteristics
Table 2-29 • 3.3 V LVTTL / 3.3 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 3.0 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
9.70
0.04
1.13
1.52
0.43
9.88
8.82
2.31
2.50
ns
–1
0.51
8.26
0.04
0.96
1.29
0.36
8.40
7.50
1.96
2.13
ns
–2
0.45
7.25
0.03
0.84
1.13
0.32
7.37
6.59
1.72
1.87
ns
Std.
0.60
9.70
0.04
1.13
1.52
0.43
9.88
8.82
2.31
2.50
ns
–1
0.51
8.26
0.04
0.96
1.29
0.36
8.40
7.50
1.96
2.13
ns
–2
0.45
7.25
0.03
0.84
1.13
0.32
7.37
6.59
1.72
1.87
ns
Std.
0.60
6.90
0.04
1.13
1.52
0.43
7.01
6.22
2.61
3.01
ns
–1
0.51
5.87
0.04
0.96
1.29
0.36
5.97
5.29
2.22
2.56
ns
–2
0.45
5.15
0.03
0.84
1.13
0.32
5.24
4.64
1.95
2.25
ns
Std.
0.60
6.90
0.04
1.13
1.52
0.43
7.01
6.22
2.61
3.01
ns
–1
0.51
5.87
0.04
0.96
1.29
0.36
5.97
5.29
2.22
2.56
ns
–2
0.45
5.15
0.03
0.84
1.13
0.32
5.24
4.64
1.95
2.25
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-30 • 3.3 V LVTTL / 3.3 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 3.0 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
7.19
0.04
1.13
1.52
0.43
7.32
6.40
2.30
2.62
ns
–1
0.51
6.12
0.04
0.96
1.29
0.36
6.22
5.44
1.96
2.23
ns
–2
0.45
5.37
0.03
0.84
1.13
0.32
5.46
4.78
1.72
1.96
ns
Std.
0.60
7.19
0.04
1.13
1.52
0.43
7.32
6.40
2.30
2.62
ns
–1
0.51
6.12
0.04
0.96
1.29
0.36
6.22
5.44
1.96
2.23
ns
–2
0.45
5.37
0.03
0.84
1.13
0.32
5.46
4.78
1.72
1.96
ns
Std.
0.60
4.57
0.04
1.13
1.52
0.43
4.64
3.92
2.60
3.14
ns
–1
0.51
3.89
0.04
0.96
1.29
0.36
3.95
3.33
2.22
2.67
ns
–2
0.45
3.41
0.03
0.84
1.13
0.32
3.47
2.93
1.95
2.34
ns
Std.
0.60
4.57
0.04
1.13
1.52
0.43
4.64
3.92
2.60
3.14
ns
–1
0.51
3.89
0.04
0.96
1.29
0.36
3.95
3.33
2.22
2.67
ns
–2
0.45
3.41
0.03
0.84
1.13
0.32
3.47
2.93
1.95
2.34
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 23
ProASIC3 nano DC and Switching Characteristics
Table 2-31 • 3.3 V LVTTL / 3.3 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 3.0 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
5.48
0.04
1.13
1.52
0.43
5.58
5.21
2.31
2.50
ns
–1
0.51
4.66
0.04
0.96
1.29
0.36
4.74
4.43
1.96
2.13
ns
–2
0.45
4.09
0.03
0.84
1.13
0.32
4.16
3.89
1.72
1.87
ns
Std.
0.60
5.48
0.04
1.13
1.52
0.43
5.58
5.21
2.31
2.50
ns
–1
0.51
4.66
0.04
0.96
1.29
0.36
4.74
4.43
1.96
2.13
ns
–2
0.45
4.09
0.03
0.84
1.13
0.32
4.16
3.89
1.72
1.87
ns
Std.
0.60
4.33
0.04
1.13
1.52
0.43
4.40
4.14
2.61
3.01
ns
–1
0.51
3.69
0.04
0.96
1.29
0.36
3.75
3.52
2.22
2.56
ns
–2
0.45
3.24
0.03
0.84
1.13
0.32
3.29
3.09
1.95
2.25
ns
Std.
0.60
4.33
0.04
1.13
1.52
0.43
4.40
4.14
2.61
3.01
ns
–1
0.51
3.69
0.04
0.96
1.29
0.36
3.75
3.52
2.22
2.56
ns
–2
0.45
3.24
0.03
0.84
1.13
0.32
3.29
3.09
1.95
2.25
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-32 • 3.3 V LVTTL / 3.3 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 3.0 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
3.56
0.04
1.13
1.52
0.43
3.62
3.03
2.30
2.62
ns
–1
0.51
3.03
0.04
0.96
1.29
0.36
3.08
2.58
1.96
2.23
ns
–2
0.45
2.66
0.03
0.84
1.13
0.32
2.70
2.26
1.72
1.96
ns
Std.
0.60
3.56
0.04
1.13
1.52
0.43
3.62
3.03
2.30
2.62
ns
–1
0.51
3.03
0.04
0.96
1.29
0.36
3.08
2.58
1.96
2.23
ns
–2
0.45
2.66
0.03
0.84
1.13
0.32
2.70
2.26
1.72
1.96
ns
Std.
0.60
2.73
0.04
1.13
1.52
0.43
2.77
2.23
2.60
3.14
ns
–1
0.51
2.32
0.04
0.96
1.29
0.36
2.36
1.90
2.22
2.67
ns
–2
0.45
2.04
0.03
0.84
1.13
0.32
2.07
1.67
1.95
2.34
ns
Std.
0.60
2.73
0.04
1.13
1.52
0.43
2.77
2.23
2.60
3.14
ns
–1
0.51
2.32
0.04
0.96
129
0.36
2.36
1.90
2.22
2.67
ns
–2
0.45
2.04
0.03
0.84
1.13
0.32
2.07
1.67
1.95
2.34
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 24
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
3.3 V LVCMOS Wide Range
Table 2-33 • Minimum and Maximum DC Input and Output Levels for 3.3 V LVCMOS Wide Range
3.3 V LVCMOS
Wide Range
Equivalent
Software
Default
Drive
Strength
Option3
Min.
V
100 µA
2 mA
–0.3
0.8
2
3.6
0.2
VDD – 0.2
100
100
10
10
100 µA
4 mA
–0.3
0.8
2
3.6
0.2
VDD – 0.2
100
100
10
10
100 µA
6 mA
–0.3
0.8
2
3.6
0.2
VDD – 0.2
100
100
10
10
100 µA
8 mA
–0.3
0.8
2
3.6
0.2
VDD – 0.2
100
100
10
10
Drive Strength
VIL
VIH
Max.
V
Min.
V
Max.
V
VOL
VOH
IOL
IOH
IIL1
IIH2
Max.
V
Min.
V
mA
mA
µA4
µA4
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
4. Currents are measured at 85°C junction temperature.
5. All LVMCOS 3.3 V software macros support LVCMOS 3.3 V Wide Range, as specified in the JESD8-B specification.
6. Software default selection highlighted in gray.
R ev i si o n 1 1
2- 25
ProASIC3 nano DC and Switching Characteristics
Timing Characteristics
Table 2-34 • 3.3 V LVCMOS Wide Range Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.7 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Equivalent
Software
Default
Drive
Drive
Strength Speed
Grade
Strength
Option1
100 µA
100 µA
100 µA
100 µA
2 mA
4 mA
6 mA
8 mA
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
Std.
0.60
14.73
0.04
1.57
2.18
0.43
–1
0.51
12.53
0.04
1.33
1.85
–2
0.45
11.00
0.03
1.17
Std.
0.60
14.73
0.04
–1
0.51
12.53
–2
0.45
Std.
tZL
tZH
tLZ
tHZ
Units
14.73 13.16
3.26
3.38
ns
0.36
12.53 11.19
2.77
2.87
ns
1.62
0.32
11.00
9.83
2.43
2.52
ns
1.57
2.18
0.43
14.73 13.16
3.26
3.38
ns
0.04
1.33
1.85
0.36
12.53 11.19
2.77
2.87
ns
11.00
0.03
1.17
1.62
0.32
11.00
9.83
2.43
2.52
ns
0.60
10.38
0.04
1.57
2.18
0.43
10.38
9.21
3.72
4.16
ns
–1
0.51
8.83
0.04
1.33
1.85
0.36
8.83
7.83
3.17
3.54
ns
–2
0.45
7.75
0.03
1.17
1.62
0.32
7.75
6.88
2.78
3.11
ns
Std.
0.60
10.38
0.04
1.57
2.18
0.43
10.38
9.21
3.72
4.16
ns
–1
0.51
8.83
0.04
1.33
1.85
0.36
8.83
7.83
3.17
3.54
ns
–2
0.45
7.75
0.03
1.17
1.62
0.32
7.75
6.88
2.78
3.11
ns
Notes:
1. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 26
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-35 • 3.3 V LVCMOS Wide Range High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.7 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Equivalent
Software
Default
Drive
Drive
Strength Speed
Grade
Strength
Option1
100 µA
100 µA
100 µA
100 µA
2 mA
4 mA
6 mA
8 mA
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
10.83
0.04
1.57
2.18
0.43
10.83
9.48
3.25
3.56
ns
–1
0.51
9.22
0.04
1.33
1.85
0.36
9.22
8.06
2.77
3.03
ns
–2
0.45
8.09
0.03
1.17
1.62
0.32
8.09
7.08
2.43
2.66
ns
Std.
0.60
10.83
0.04
1.57
2.18
0.43
10.83
9.48
3.25
3.56
ns
–1
0.51
9.22
0.04
1.33
1.85
0.36
9.22
8.06
2.77
3.03
ns
–2
0.45
8.09
0.03
1.17
1.62
0.32
8.09
7.08
2.43
2.66
ns
Std.
0.60
6.78
0.04
1.57
2.18
0.43
6.78
5.72
3.72
4.35
ns
–1
0.51
5.77
0.04
1.33
1.85
0.36
5.77
4.87
3.16
3.70
ns
–2
0.45
5.06
0.03
1.17
1.62
0.32
5.06
4.27
2.78
3.25
ns
Std.
0.60
6.78
0.04
1.57
2.18
0.43
6.78
5.72
3.72
4.35
ns
–1
0.51
5.77
0.04
1.33
1.85
0.36
5.77
4.87
3.16
3.70
ns
–2
0.45
5.06
0.03
1.17
1.62
0.32
5.06
4.27
2.78
3.25
ns
Notes:
1. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
3. Software default selection highlighted in gray.
R ev i si o n 1 1
2- 27
ProASIC3 nano DC and Switching Characteristics
Table 2-36 • 3.3 V LVCMOS Wide Range Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.7 V
Software Default Load at 35 pF for A3PN020, A3PN015, A3PN010
Equivalent
Software
Default
Drive
Drive
Strength Speed
Grade
Strength
Option1
100 µA
100 µA
100 µA
100 µA
2 mA
4 mA
6 mA
8 mA
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
8.20
0.04
1.57
2.18
0.43
8.20
7.68
3.26
3.38
ns
–1
0.51
6.97
0.04
1.33
1.85
0.36
6.97
6.53
2.77
2.87
ns
–2
0.45
6.12
0.03
1.17
1.62
0.32
6.12
5.73
2.43
2.52
ns
Std.
0.60
8.20
0.04
1.57
2.18
0.43
8.20
7.68
3.26
3.38
ns
–1
0.51
6.97
0.04
1.33
1.85
0.36
6.97
6.53
2.77
2.87
ns
–2
0.45
6.12
0.03
1.17
1.62
0.32
6.12
5.73
2.43
2.52
ns
Std.
0.60
6.42
0.04
1.57
2.18
0.43
6.42
6.05
3.72
4.16
ns
–1
0.51
5.46
0.04
1.33
1.85
0.36
5.46
5.14
3.17
3.54
ns
–2
0.45
4.79
0.03
1.17
1.62
0.32
4.79
4.52
2.78
3.11
ns
Std.
0.60
6.42
0.04
1.57
2.18
0.43
6.42
6.05
3.72
4.16
ns
–1
0.51
5.46
0.04
1.33
1.85
0.36
5.46
5.14
3.17
3.54
ns
–2
0.45
4.79
0.03
1.17
1.62
0.32
4.79
4.52
2.78
3.11
ns
Notes:
1. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 28
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-37 • 3.3 V LVCMOS Wide Range High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.7 V
Software Default Load at 35 pF for A3PN020, A3PN015, A3PN010
Equivalent
Software
Default
Drive
Drive
Strength Speed
Grade
Strength
Option1
100 µA
100 µA
100 µA
100 µA
2 mA
4 mA
6 mA
8 mA
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
5.23
0.04
1.57
2.18
0.43
5.23
4.37
3.25
3.56
ns
–1
0.51
4.45
0.04
1.33
1.85
0.36
4.45
3.71
2.77
3.03
ns
–2
0.45
3.90
0.03
1.17
1.62
0.32
3.90
3.26
2.43
2.66
ns
Std.
0.60
5.23
0.04
1.57
2.18
0.43
5.23
4.37
3.25
3.56
ns
–1
0.51
4.45
0.04
1.33
1.85
0.36
4.45
3.71
2.77
3.03
ns
–2
0.45
3.90
0.03
1.17
1.62
0.32
3.90
3.26
2.43
2.66
ns
Std.
0.60
3.94
0.04
1.57
2.18
0.43
3.94
3.16
3.72
4.35
ns
–1
0.51
3.35
0.04
1.33
1.85
0.36
3.35
2.69
3.16
3.70
ns
–2
0.45
2.94
0.03
1.17
1.62
0.32
2.94
2.36
2.78
3.25
ns
Std.
0.60
3.94
0.04
1.57
2.18
0.43
3.94
3.16
3.72
4.35
ns
–1
0.51
3.35
0.04
1.33
1.85
0.36
3.35
2.69
3.16
3.70
ns
–2
0.45
2.94
0.03
1.17
1.62
0.32
2.94
2.36
2.78
3.25
ns
Notes:
1. The minimum drive strength for any LVCMOS 3.3 V software configuration when run in wide range is ±100 µA. Drive
strength displayed in the software is supported for normal range only. For a detailed I/V curve, refer to the IBIS models.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
3. Software default selection highlighted in gray.
R ev i si o n 1 1
2- 29
ProASIC3 nano DC and Switching Characteristics
2.5 V LVCMOS
Low-Voltage CMOS for 2.5 V is an extension of the LVCMOS standard (JESD8-5) used for generalpurpose 2.5 V applications.
Table 2-38 • Minimum and Maximum DC Input and Output Levels
2.5 V LVCMOS
VIL
VIH
VOL
VOH
IOL IOH
IOSL
IOSH
IIL1
IIH2
Drive Strength
Min.
V
Max.
V
Min.
V
Max.
V
Max.
V
Min.
V
mA
mA
Max.
mA3
Max.
mA3
µA4
µA4
2 mA
–0.3
0.7
1.7
3.6
0.7
1.7
2
2
16
18
10
10
4 mA
–0.3
0.7
1.7
3.6
0.7
1.7
4
4
16
18
10
10
6 mA
–0.3
0.7
1.7
3.6
0.7
1.7
6
6
32
37
10
10
8 mA
–0.3
0.7
1.7
3.6
0.7
1.7
8
8
32
37
10
10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
R=1k
Test Point
Enable Path
Test Point
Datapath
Figure 2-7 •
35 pF
R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
35 pF for tZH / tZHS / tZL / tZLS
35 pF for tHZ / tLZ
AC Loading
Table 2-39 • 2.5 V LVCMOS AC Waveforms, Measuring Points, and Capacitive Loads
Input LOW (V)
0
Input HIGH (V)
Measuring Point* (V)
CLOAD (pF)
2.5
1.2
10
Notes:
1. Measuring point = Vtrip. See Table 2-16 on page 2-17 for a complete table of trip points.
2. Capacitive Load for A3PN060, A3PN125, and A3PN250 is 35 pF.
2- 30
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Timing Characteristics
Table 2-40 • 2.5 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.3 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
11.29
0.04
1.43
1.63
0.43
10.64
11.29
2.27
2.29
ns
–1
0.51
9.61
0.04
1.22
1.39
0.36
9.05
9.61
1.93
1.95
ns
–2
0.45
8.43
0.03
1.07
1.22
0.32
7.94
8.43
1.70
1.71
ns
Std.
0.60
11.29
0.04
1.43
1.63
0.43
10.64
11.29
2.27
2.29
ns
–1
0.51
9.61
0.04
1.22
1.39
0.36
9.05
9.61
1.93
1.95
ns
–2
0.45
8.43
0.03
1.07
1.22
0.32
7.94
8.43
1.70
1.71
ns
Std.
0.60
7.73
0.04
1.43
1.63
0.43
7.70
7.73
2.60
2.89
ns
–1
0.51
6.57
0.04
1.22
1.39
0.36
6.55
6.57
2.21
2.46
ns
–2
0.45
5.77
0.03
1.07
1.22
0.32
5.75
5.77
1.94
2.16
ns
Std.
0.60
7.73
0.04
1.43
1.63
0.43
7.70
7.73
2.60
2.89
ns
–1
0.51
6.57
0.04
1.22
1.39
0.36
6.55
6.57
2.21
2.46
ns
–2
0.45
5.77
0.03
1.07
1.22
0.32
5.75
5.77
1.94
2.16
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-41 • 2.5 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.3 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
8.38
0.04
1.43
1.63
0.43
7.36
8.38
2.27
2.37
ns
–1
0.51
7.13
0.04
1.22
1.39
0.36
6.26
7.13
1.93
2.02
ns
–2
0.45
6.26
0.03
1.07
1.22
0.32
5.50
6.26
1.69
1.77
ns
Std.
0.60
8.38
0.04
1.43
1.63
0.43
7.36
8.38
2.27
2.37
ns
–1
0.51
7.13
0.04
1.22
1.39
0.36
6.26
7.13
1.93
2.02
ns
–2
0.45
6.26
0.03
1.07
1.22
0.32
5.50
6.26
1.69
1.77
ns
Std.
0.60
4.94
0.04
1.43
1.63
0.43
4.71
4.94
2.60
2.98
ns
–1
0.51
4.20
0.04
1.22
1.39
0.36
4.01
4.20
2.21
2.54
ns
–2
0.45
3.69
0.03
1.07
1.22
0.32
3.52
3.69
1.94
2.23
ns
Std.
0.60
4.94
0.04
1.43
1.63
0.43
4.71
4.94
2.60
2.98
ns
–1
0.51
4.20
0.04
1.22
1.39
0.36
4.01
4.20
2.21
2.54
ns
–2
0.45
3.69
0.03
1.07
1.22
0.32
3.52
3.69
1.94
2.23
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 31
ProASIC3 nano DC and Switching Characteristics
Table 2-42 • 2.5 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.3 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
6.40
0.04
1.43
1.63
0.43
6.16
6.40
2.27
2.29
ns
–1
0.51
5.45
0.04
1.22
1.39
0.36
5.24
5.45
1.93
1.95
ns
–2
0.45
4.78
0.03
1.07
1.22
0.32
4.60
4.78
1.70
1.71
ns
Std.
0.60
6.40
0.04
1.43
1.63
0.43
6.16
6.40
2.27
2.29
ns
–1
0.51
5.45
0.04
1.22
1.39
0.36
5.24
5.45
1.93
1.95
ns
–2
0.45
4.78
0.03
1.07
1.22
0.32
4.60
4.78
1.70
1.71
ns
Std.
0.60
5.00
0.04
1.43
1.63
0.43
4.90
5.00
2.60
2.89
ns
–1
0.51
4.26
0.04
1.22
1.39
0.36
4.17
4.26
2.21
2.46
ns
–2
0.45
3.74
0.03
1.07
1.22
0.32
3.66
3.74
1.94
2.16
ns
Std.
0.60
5.00
0.04
1.43
1.63
0.43
4.90
5.00
2.60
2.89
ns
–1
0.51
4.26
0.04
1.22
1.39
0.36
4.17
4.26
2.21
2.46
ns
–2
0.45
3.74
0.03
1.07
1.22
0.32
3.66
3.74
1.94
2.16
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-43 • 2.5 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 2.3 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
4 mA
6 mA
8 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
3.70
0.04
1.43
1.63
0.43
3.66
3.70
2.27
2.37
ns
–1
0.51
3.15
0.04
1.22
1.39
0.36
3.12
3.15
1.93
2.02
ns
–2
0.45
2.77
0.03
1.07
1.22
0.32
2.74
2.77
1.69
1.77
ns
Std.
0.60
3.70
0.04
1.43
1.63
0.43
3.66
3.70
2.27
2.37
ns
–1
0.51
3.15
0.04
1.22
1.39
0.36
3.12
3.15
1.93
2.02
ns
–2
0.45
2.77
0.03
1.07
1.22
0.32
2.74
2.77
1.69
1.77
ns
Std.
0.60
2.76
0.04
1.43
1.63
0.43
2.80
2.60
2.60
2.98
ns
–1
0.51
2.35
0.04
1.22
1.39
0.36
2.38
2.21
2.21
2.54
ns
–2
0.45
2.06
0.03
1.07
1.22
0.32
2.09
1.94
1.94
2.23
ns
Std.
0.60
2.76
0.04
1.43
1.63
0.43
2.80
2.60
2.60
2.98
ns
–1
0.51
2.35
0.04
1.22
1.39
0.36
2.38
2.21
2.21
2.54
ns
–2
0.45
2.06
0.03
1.07
1.22
0.32
2.09
1.94
1.94
2.23
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 32
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
1.8 V LVCMOS
Low-voltage CMOS for 1.8 V is an extension of the LVCMOS standard (JESD8-5) used for generalpurpose 1.8 V applications. It uses a 1.8 V input buffer and a push-pull output buffer.
Table 2-44 • Minimum and Maximum DC Input and Output Levels
1.8 V LVCMOS
VIL
Max.
V
VOL
VOH
IOL IOH IOSL
IOSH IIL1 IIH2
Max.
V
Max.
V
Min.
V
mA mA
Max.
mA3
Max.
mA3 µA4 µA4
VIH
Drive Strength
Min.
V
Min.
V
2 mA
–0.3 0.35 * VCCI 0.65 * VCCI
3.6
0.45
VCCI – 0.45
2
2
9
11
10
10
4 mA
–0.3 0.35 * VCCI 0.65 * VCCI
3.6
0.45
VCCI – 0.45
4
4
17
22
10
10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
R=1k
Test Point
Enable Path
Test Point
Datapath
Figure 2-8 •
35 pF
R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
35 pF for tZH / tZHS / tZL / tZLS
35 pF for tHZ / tLZ
AC Loading
Table 2-45 • 1.8 V LVCMOS AC Waveforms, Measuring Points, and Capacitive Loads
Input LOW (V)
0
Input HIGH (V)
Measuring Point* (V)
CLOAD (pF)
1.8
0.9
10
Notes:
1. Measuring point = Vtrip. See Table 2-16 on page 2-17 for a complete table of trip points.
2. Capacitive Load for A3PN060, A3PN125, and A3PN250 is 35 pF.
R ev i si o n 1 1
2- 33
ProASIC3 nano DC and Switching Characteristics
Timing Characteristics
Table 2-46 • 1.8 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.7 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
4 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
15.36
0.04
1.35
1.90
0.43
13.46
15.36
2.23
1.78
ns
–1
0.51
13.07
0.04
1.15
1.61
0.36
11.45
13.07
1.90
1.51
ns
–2
0.45
11.47
0.03
1.01
1.42
0.32
10.05
11.47
1.67
1.33
ns
Std.
0.60
10.32
0.04
1.35
1.90
0.43
9.92
10.32
2.63
2.78
ns
–1
0.51
8.78
0.04
1.15
1.61
0.36
8.44
8.78
2.23
2.37
ns
–2
0.45
7.71
0.03
1.01
1.42
0.32
7.41
7.71
1.96
2.08
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-47 • 1.8 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.7 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
4 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
11.42
0.04
1.35
1.90
0.43
8.65
11.42
2.23
1.84
ns
–1
0.51
9.71
0.04
1.15
1.61
0.36
7.36
9.71
1.89
1.57
ns
–2
0.45
8.53
0.03
1.01
1.42
0.32
6.46
8.53
1.66
1.37
ns
Std.
0.60
6.53
0.04
1.35
1.90
0.43
5.53
6.53
2.62
2.89
ns
–1
0.51
5.56
0.04
1.15
1.61
0.36
4.70
5.56
2.23
2.45
ns
–2
0.45
4.88
0.03
1.01
1.42
0.32
4.13
4.88
1.96
2.15
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 34
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-48 • 1.8 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.7 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
4 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
8.52
0.04
1.35
1.90
0.43
7.99
8.52
2.23
1.78
ns
–1
0.51
7.25
0.04
1.15
1.61
0.36
6.80
7.25
1.90
1.51
ns
–2
0.45
6.36
0.03
1.01
1.42
0.32
5.97
6.36
1.67
1.33
ns
Std.
0.60
6.59
0.04
1.35
1.90
0.43
6.44
6.59
2.63
2.78
ns
–1
0.51
5.60
0.04
1.15
1.61
0.36
5.48
5.60
2.23
2.37
ns
–2
0.45
4.92
0.03
1.01
1.42
0.32
4.81
4.92
1.96
2.08
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-49 • 1.8 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.7 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
4 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
4.79
0.04
1.35
1.90
0.43
4.27
4.79
2.23
1.84
ns
–1
0.51
4.08
0.04
1.15
1.61
0.36
3.63
4.08
1.89
1.57
ns
–2
0.45
3.58
0.03
1.01
1.42
0.32
3.19
3.58
1.66
1.37
ns
Std.
0.60
3.22
0.04
1.35
1.90
0.43
3.24
3.22
2.62
2.89
ns
–1
0.51
2.74
0.04
1.15
1.61
0.36
2.75
2.74
2.23
2.45
ns
–2
0.45
2.40
0.03
1.01
1.42
0.32
2.42
2.40
1.95
2.15
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 35
ProASIC3 nano DC and Switching Characteristics
1.5 V LVCMOS (JESD8-11)
Low-Voltage CMOS for 1.5 V is an extension of the LVCMOS standard (JESD8-5) used for generalpurpose 1.5 V applications. It uses a 1.5 V input buffer and a push-pull output buffer.
Table 2-50 • Minimum and Maximum DC Input and Output Levels
1.5 V LVCMOS
VIL
Max.
V
VIH
Drive Strength
Min.
V
Min.
V
Max.
V
2 mA
–0.3 0.35 * VCCI 0.65 * VCCI
3.6
VOL
VOH
IOL IOH IOSL IOSH IIL1 IIH2
Max.
V
Min.
V
Max.
mA mA mA3
0.25 * VCCI 0.75 * VCCI
2
2
13
Max.
mA3 µA4 µA4
16
10
10
Notes:
1. IIL is the input leakage current per I/O pin over recommended operation conditions where –0.3 V < VIN < VIL.
2. IIH is the input leakage current per I/O pin over recommended operating conditions VIH < VIN < VCCI. Input current is
larger when operating outside recommended ranges.
3. Currents are measured at high temperature (100°C junction temperature) and maximum voltage.
4. Currents are measured at 85°C junction temperature.
5. Software default selection highlighted in gray.
R=1k
Test Point
Enable Path
Test Point
Datapath
Figure 2-9 •
35 pF
R to VCCI for tLZ / tZL / tZLS
R to GND for tHZ / tZH / tZHS
35 pF for tZH / tZHS / tZL / tZLS
35 pF for tHZ / tLZ
AC Loading
Table 2-51 • 1.5 V LVCMOS AC Waveforms, Measuring Points, and Capacitive Loads
Input LOW (V)
0
Input HIGH (V)
Measuring Point* (V)
CLOAD (pF)
1.5
0.75
10
Notes:
1. Measuring point = Vtrip. See Table 2-16 on page 2-17 for a complete table of trip points.
2. Capacitive Load for A3PN060, A3PN125, and A3PN250 is 35 pF.
2- 36
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Timing Characteristics
Table 2-52 • 1.5 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.4 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
12.58
0.04
1.56
2.14
0.43
12.18
12.58
2.67
2.71
ns
–1
0.51
10.70
0.04
1.32
1.82
0.36
10.36
10.70
2.27
2.31
ns
–2
0.45
9.39
0.03
1.16
1.59
0.32
9.09
9.39
1.99
2.03
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-53 • 1.5 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.4 V
Software Default Load at 35 pF for A3PN060, A3PN125, A3PN250
Drive
Strength
2 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
7.86
0.04
1.56
2.14
0.43
6.45
7.86
2.66
2.83
ns
–1
0.51
6.68
0.04
1.32
1.82
0.36
5.49
6.68
2.26
2.41
ns
–2
0.45
5.87
0.03
1.16
1.59
0.32
4.82
5.87
1.99
2.12
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-54 • 1.5 V LVCMOS Low Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.4 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
8.01
0.04
1.56
2.14
0.43
8.03
8.01
2.67
2.71
ns
–1
0.51
6.81
0.04
1.32
1.82
0.36
6.83
6.81
2.27
2.31
ns
–2
0.45
5.98
0.03
1.16
1.58
0.32
6.00
5.98
2.10
2.03
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-55 • 1.5 V LVCMOS High Slew
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V, Worst-Case VCCI = 1.4 V
Software Default Load at 10 pF for A3PN020, A3PN015, A3PN010
Drive
Strength
2 mA
Speed
Grade
tDOUT
tDP
tDIN
tPY
tPYS
tEOUT
tZL
tZH
tLZ
tHZ
Units
Std.
0.60
3.76
0.04
1.52
2.14
0.43
3.74
3.76
2.66
2.83
ns
–1
0.51
3.20
0.04
1.32
1.82
0.36
3.18
3.20
2.26
2.41
ns
–2
0.45
2.81
0.03
1.16
1.59
0.32
2.79
2.81
1.99
2.12
ns
Notes:
1. Software default selection highlighted in gray.
2. For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 37
ProASIC3 nano DC and Switching Characteristics
I/O Register Specifications
Fully Registered I/O Buffers with Synchronous Enable and
Asynchronous Preset
INBUF
Preset
L
DOUT
Data_out
E
Y
F
Core
Array
G
PRE
D
Q
DFN1E1P1
TRIBUF
CLKBUF
CLK
INBUF
Enable
PRE
D
Q
C DFN1E1P1
INBUF
Data
E
E
EOUT
B
H
I
A
J
K
INBUF
INBUF
D_Enable
CLK
CLKBUF
Enable
Data Input I/O Register with:
Active High Enable
Active High Preset
Positive-Edge Triggered
PRE
D
Q
DFN1E1P1
E
Data Output Register and
Enable Output Register with:
Active High Enable
Active High Preset
Postive-Edge Triggered
Figure 2-10 • Timing Model of Registered I/O Buffers with Synchronous Enable and Asynchronous Preset
2- 38
R ev i sio n 1 1
Pad Out
D
ProASIC3 nano Flash FPGAs
Table 2-56 • Parameter Definition and Measuring Nodes
Parameter Name
Parameter Definition
Measuring Nodes
(from, to)*
tOCLKQ
Clock-to-Q of the Output Data Register
H, DOUT
tOSUD
Data Setup Time for the Output Data Register
F, H
tOHD
Data Hold Time for the Output Data Register
F, H
tOSUE
Enable Setup Time for the Output Data Register
G, H
tOHE
Enable Hold Time for the Output Data Register
G, H
tOPRE2Q
Asynchronous Preset-to-Q of the Output Data Register
tOREMPRE
Asynchronous Preset Removal Time for the Output Data Register
L, H
tORECPRE
Asynchronous Preset Recovery Time for the Output Data Register
L, H
tOECLKQ
Clock-to-Q of the Output Enable Register
tOESUD
Data Setup Time for the Output Enable Register
J, H
tOEHD
Data Hold Time for the Output Enable Register
J, H
tOESUE
Enable Setup Time for the Output Enable Register
K, H
tOEHE
Enable Hold Time for the Output Enable Register
K, H
tOEPRE2Q
Asynchronous Preset-to-Q of the Output Enable Register
tOEREMPRE
Asynchronous Preset Removal Time for the Output Enable Register
I, H
tOERECPRE
Asynchronous Preset Recovery Time for the Output Enable Register
I, H
tICLKQ
Clock-to-Q of the Input Data Register
A, E
tISUD
Data Setup Time for the Input Data Register
C, A
tIHD
Data Hold Time for the Input Data Register
C, A
tISUE
Enable Setup Time for the Input Data Register
B, A
tIHE
Enable Hold Time for the Input Data Register
B, A
tIPRE2Q
Asynchronous Preset-to-Q of the Input Data Register
D, E
tIREMPRE
Asynchronous Preset Removal Time for the Input Data Register
D, A
tIRECPRE
Asynchronous Preset Recovery Time for the Input Data Register
D, A
L, DOUT
H, EOUT
I, EOUT
Note: *See Figure 2-10 on page 2-38 for more information.
R ev i si o n 1 1
2- 39
ProASIC3 nano DC and Switching Characteristics
Fully Registered I/O Buffers with Synchronous Enable and
Asynchronous Clear
D
CC
Q
DFN1E1C1
EE
Data_out FF
D
Q
DFN1E1C1
TRIBUF
INBUF
Data
Core
Array
Pad Out
DOUT
Y
GG
INBUF
Enable
BB
EOUT
E
E
CLR
CLR
LL
INBUF
CLR
CLKBUF
CLK
HH
AA
JJ
DD
KK
Data Input I/O Register with
Active High Enable
Active High Clear
Positive-Edge Triggered
D
Q
DFN1E1C1
E
INBUF
CLKBUF
CLK
Enable
INBUF
D_Enable
CLR
Data Output Register and
Enable Output Register with
Active High Enable
Active High Clear
Positive-Edge Triggered
Figure 2-11 • Timing Model of the Registered I/O Buffers with Synchronous Enable and Asynchronous Clear
2- 40
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-57 • Parameter Definition and Measuring Nodes
Parameter Name
Parameter Definition
Measuring Nodes
(from, to)*
tOCLKQ
Clock-to-Q of the Output Data Register
HH, DOUT
tOSUD
Data Setup Time for the Output Data Register
FF, HH
tOHD
Data Hold Time for the Output Data Register
FF, HH
tOSUE
Enable Setup Time for the Output Data Register
GG, HH
tOHE
Enable Hold Time for the Output Data Register
GG, HH
tOCLR2Q
Asynchronous Clear-to-Q of the Output Data Register
tOREMCLR
Asynchronous Clear Removal Time for the Output Data Register
LL, HH
tORECCLR
Asynchronous Clear Recovery Time for the Output Data Register
LL, HH
tOECLKQ
Clock-to-Q of the Output Enable Register
tOESUD
Data Setup Time for the Output Enable Register
JJ, HH
tOEHD
Data Hold Time for the Output Enable Register
JJ, HH
tOESUE
Enable Setup Time for the Output Enable Register
KK, HH
tOEHE
Enable Hold Time for the Output Enable Register
KK, HH
tOECLR2Q
Asynchronous Clear-to-Q of the Output Enable Register
II, EOUT
tOEREMCLR
Asynchronous Clear Removal Time for the Output Enable Register
II, HH
tOERECCLR
Asynchronous Clear Recovery Time for the Output Enable Register
II, HH
tICLKQ
Clock-to-Q of the Input Data Register
AA, EE
tISUD
Data Setup Time for the Input Data Register
CC, AA
tIHD
Data Hold Time for the Input Data Register
CC, AA
tISUE
Enable Setup Time for the Input Data Register
BB, AA
tIHE
Enable Hold Time for the Input Data Register
BB, AA
tICLR2Q
Asynchronous Clear-to-Q of the Input Data Register
DD, EE
tIREMCLR
Asynchronous Clear Removal Time for the Input Data Register
DD, AA
tIRECCLR
Asynchronous Clear Recovery Time for the Input Data Register
DD, AA
LL, DOUT
HH, EOUT
Note: *See Figure 2-11 on page 2-40 for more information.
R ev i si o n 1 1
2- 41
ProASIC3 nano DC and Switching Characteristics
Input Register
tICKMPWH tICKMPWL
CLK
50%
50%
Enable
50%
1
50%
50%
50%
tIHD
tISUD
Data
50%
50%
50%
0
tIWPRE
50%
tIRECPRE
tIREMPRE
50%
50%
tIHE
Preset
tISUE
50%
tIWCLR
50%
Clear
tIRECCLR
tIREMCLR
50%
50%
tIPRE2Q
50%
Out_1
50%
tICLR2Q
50%
tICLKQ
Figure 2-12 • Input Register Timing Diagram
Timing Characteristics
Table 2-58 • Input Data Register Propagation Delays
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1 Std. Units
tICLKQ
Clock-to-Q of the Input Data Register
0.24 0.27 0.32
ns
tISUD
Data Setup Time for the Input Data Register
0.26 0.30 0.35
ns
tIHD
Data Hold Time for the Input Data Register
0.00 0.00 0.00
ns
tICLR2Q
Asynchronous Clear-to-Q of the Input Data Register
0.45 0.52 0.61
ns
tIPRE2Q
Asynchronous Preset-to-Q of the Input Data Register
0.45 0.52 0.61
ns
tIREMCLR
Asynchronous Clear Removal Time for the Input Data Register
0.00 0.00 0.00
ns
tIRECCLR
Asynchronous Clear Recovery Time for the Input Data Register
0.22 0.25 0.30
ns
tIREMPRE
Asynchronous Preset Removal Time for the Input Data Register
0.00 0.00 0.00
ns
tIRECPRE
Asynchronous Preset Recovery Time for the Input Data Register
0.22 0.25 0.30
ns
tIWCLR
Asynchronous Clear Minimum Pulse Width for the Input Data Register
0.22 0.25 0.30
ns
tIWPRE
Asynchronous Preset Minimum Pulse Width for the Input Data Register
0.22 0.25 0.30
ns
tICKMPWH
Clock Minimum Pulse Width HIGH for the Input Data Register
0.36 0.41 0.48
ns
tICKMPWL
Clock Minimum Pulse Width LOW for the Input Data Register
0.32 0.37 0.43
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 42
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Output Register
tOCKMPWH tOCKMPWL
CLK
50%
50%
50%
50%
50%
50%
50%
tOSUD tOHD
1
Data_out
Enable
50%
50%
0
50%
tOWPRE
tOHE
Preset
tOSUE
tOREMPRE
tORECPRE
50%
50%
50%
tOWCLR
50%
Clear
tOREMCLR
tORECCLR
50%
50%
tOPRE2Q
50%
DOUT
50%
tOCLR2Q
50%
tOCLKQ
Figure 2-13 • Output Register Timing Diagram
Timing Characteristics
Table 2-59 • Output Data Register Propagation Delays
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std. Units
tOCLKQ
Clock-to-Q of the Output Data Register
0.59 0.67 0.79
ns
tOSUD
Data Setup Time for the Output Data Register
0.31 0.36 0.42
ns
tOHD
Data Hold Time for the Output Data Register
0.00 0.00 0.00
ns
tOCLR2Q
Asynchronous Clear-to-Q of the Output Data Register
0.80 0.91 1.07
ns
tOPRE2Q
Asynchronous Preset-to-Q of the Output Data Register
0.80 0.91 1.07
ns
tOREMCLR
Asynchronous Clear Removal Time for the Output Data Register
0.00 0.00 0.00
ns
tORECCLR
Asynchronous Clear Recovery Time for the Output Data Register
0.22 0.25 0.30
ns
tOREMPRE
Asynchronous Preset Removal Time for the Output Data Register
0.00 0.00 0.00
ns
tORECPRE
Asynchronous Preset Recovery Time for the Output Data Register
0.22 0.25 0.30
ns
tOWCLR
Asynchronous Clear Minimum Pulse Width for the Output Data Register
0.22 0.25 0.30
ns
tOWPRE
Asynchronous Preset Minimum Pulse Width for the Output Data Register
0.22 0.25 0.30
ns
tOCKMPWH
Clock Minimum Pulse Width HIGH for the Output Data Register
0.36 0.41 0.48
ns
tOCKMPWL
Clock Minimum Pulse Width LOW for the Output Data Register
0.32 0.37 0.43
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 43
ProASIC3 nano DC and Switching Characteristics
Output Enable Register
tOECKMPWH tOECKMPWL
CLK
50%
50%
50%
50%
50%
50%
50%
tOESUD tOEHD
1
D_Enable
Enable
Preset
50%
0 50%
50%
tOEWPRE
50%
tOESUEtOEHE
tOEREMPRE
tOERECPRE
50%
50%
tOEWCLR
50%
Clear
tOEPRE2Q
EOUT
50%
50%
tOEREMCLR
tOERECCLR
50%
50%
tOECLR2Q
50%
tOECLKQ
Figure 2-14 • Output Enable Register Timing Diagram
Timing Characteristics
Table 2-60 • Output Enable Register Propagation Delays
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std. Units
tOECLKQ
Clock-to-Q of the Output Enable Register
0.44 0.51 0.59
ns
tOESUD
Data Setup Time for the Output Enable Register
0.31 0.36 0.42
ns
tOEHD
Data Hold Time for the Output Enable Register
0.00 0.00 0.00
ns
tOECLR2Q
Asynchronous Clear-to-Q of the Output Enable Register
0.67 0.76 0.89
ns
tOEPRE2Q
Asynchronous Preset-to-Q of the Output Enable Register
0.67 0.76 0.89
ns
tOEREMCLR Asynchronous Clear Removal Time for the Output Enable Register
0.00 0.00 0.00
ns
Asynchronous Clear Recovery Time for the Output Enable Register
0.22 0.25 0.30
ns
tOEREMPRE Asynchronous Preset Removal Time for the Output Enable Register
0.00 0.00 0.00
ns
tOERECPRE
Asynchronous Preset Recovery Time for the Output Enable Register
0.22 0.25 0.30
ns
tOEWCLR
Asynchronous Clear Minimum Pulse Width for the Output Enable Register
0.22 0.25 0.30
ns
tOEWPRE
Asynchronous Preset Minimum Pulse Width for the Output Enable Register
0.22 0.25 0.30
ns
tOECKMPWH Clock Minimum Pulse Width HIGH for the Output Enable Register
0.36 0.41 0.48
ns
tOECKMPWL Clock Minimum Pulse Width LOW for the Output Enable Register
0.32 0.37 0.43
ns
tOERECCLR
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 44
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
DDR Module Specifications
Input DDR Module
Input DDR
INBUF
Data
A
D
Out_QF
(to core)
E
Out_QR
(to core)
FF1
B
CLK
CLKBUF
FF2
C
CLR
INBUF
DDR_IN
Figure 2-15 • Input DDR Timing Model
Table 2-61 • Parameter Definitions
Parameter Name
Parameter Definition
Measuring Nodes (from, to)
tDDRICLKQ1
Clock-to-Out Out_QR
B, D
tDDRICLKQ2
Clock-to-Out Out_QF
B, E
tDDRISUD
Data Setup Time of DDR input
A, B
tDDRIHD
Data Hold Time of DDR input
A, B
tDDRICLR2Q1
Clear-to-Out Out_QR
C, D
tDDRICLR2Q2
Clear-to-Out Out_QF
C, E
tDDRIREMCLR
Clear Removal
C, B
tDDRIRECCLR
Clear Recovery
C, B
R ev i si o n 1 1
2- 45
ProASIC3 nano DC and Switching Characteristics
CLK
tDDRISUD
Data
1
2
3
4
5
tDDRIHD
6
7
8
9
tDDRIRECCLR
CLR
tDDRIREMCLR
tDDRICLKQ1
tDDRICLR2Q1
Out_QF
2
6
4
tDDRICLKQ2
tDDRICLR2Q2
Out_QR
3
7
5
Figure 2-16 • Input DDR Timing Diagram
Timing Characteristics
Table 2-62 • Input DDR Propagation Delays
Commercial-Case Conditions: TJ = 70°C, Worst Case VCC = 1.425 V
Parameter
Description
–2
–1
Std.
Units
tDDRICLKQ1
Clock-to-Out Out_QR for Input DDR
0.27
0.31
0.37
ns
tDDRICLKQ2
Clock-to-Out Out_QF for Input DDR
0.39
0.44
0.52
ns
tDDRISUD
Data Setup for Input DDR (Fall)
0.28
0.32
0.38
ns
Data Setup for Input DDR (Rise)
0.25
0.28
0.33
ns
Data Hold for Input DDR (Fall)
0.00
0.00
0.00
ns
Data Hold for Input DDR (Rise)
0.00
0.00
0.00
ns
tDDRICLR2Q1
Asynchronous Clear-to-Out Out_QR for Input DDR
0.46
0.53
0.62
ns
tDDRICLR2Q2
Asynchronous Clear-to-Out Out_QF for Input DDR
0.57
0.65
0.76
ns
tDDRIREMCLR
Asynchronous Clear Removal time for Input DDR
0.00
0.00
0.00
ns
tDDRIRECCLR
Asynchronous Clear Recovery time for Input DDR
0.22
0.25
0.30
ns
tDDRIWCLR
Asynchronous Clear Minimum Pulse Width for Input DDR
0.22
0.25
0.30
ns
tDDRICKMPWH
Clock Minimum Pulse Width High for Input DDR
0.36
0.41
0.48
ns
tDDRICKMPWL
Clock Minimum Pulse Width Low for Input DDR
0.32
0.37
0.43
ns
FDDRIMAX
Maximum Frequency for Input DDR
350.00
350.00
350.00
MHz
tDDRIHD
Note: For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 46
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Output DDR Module
Output DDR
A
Data_F
(from core)
X
FF1
B
CLK
CLKBUF
E
X
C
X
D
Data_R
(from core)
Out
0
X
1
X
OUTBUF
FF2
B
X
CLR
INBUF
C
X
DDR_OUT
Figure 2-17 • Output DDR Timing Model
Table 2-63 • Parameter Definitions
Parameter Name
Parameter Definition
Measuring Nodes (from, to)
tDDROCLKQ
Clock-to-Out
B, E
tDDROCLR2Q
Asynchronous Clear-to-Out
C, E
tDDROREMCLR
Clear Removal
C, B
tDDRORECCLR
Clear Recovery
C, B
tDDROSUD1
Data Setup Data_F
A, B
tDDROSUD2
Data Setup Data_R
D, B
tDDROHD1
Data Hold Data_F
A, B
tDDROHD2
Data Hold Data_R
D, B
R ev i si o n 1 1
2- 47
ProASIC3 nano DC and Switching Characteristics
CLK
tDDROSUD2 tDDROHD2
1
Data_F
2
tDDROREMCLR
Data_R 6
4
3
5
tDDROHD1
7
8
9
10
11
tDDRORECCLR
tDDROREMCLR
CLR
tDDROCLR2Q
Out
tDDROCLKQ
7
2
8
3
9
4
10
–2
–1
Std.
Units
Figure 2-18 • Output DDR Timing Diagram
Timing Characteristics
Table 2-64 • Output DDR Propagation Delays
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
tDDROCLKQ
Clock-to-Out of DDR for Output DDR
0.70
0.80
0.94
ns
tDDROSUD1
Data_F Data Setup for Output DDR
0.38
0.43
0.51
ns
tDDROSUD2
Data_R Data Setup for Output DDR
0.38
0.43
0.51
ns
tDDROHD1
Data_F Data Hold for Output DDR
0.00
0.00
0.00
ns
tDDROHD2
Data_R Data Hold for Output DDR
0.00
0.00
0.00
ns
tDDROCLR2Q
Asynchronous Clear-to-Out for Output DDR
0.80
0.91
1.07
ns
tDDROREMCLR
Asynchronous Clear Removal Time for Output DDR
0.00
0.00
0.00
ns
tDDRORECCLR
Asynchronous Clear Recovery Time for Output DDR
0.22
0.25
0.30
ns
tDDROWCLR1
Asynchronous Clear Minimum Pulse Width for Output DDR
0.22
0.25
0.30
ns
tDDROCKMPWH
Clock Minimum Pulse Width HIGH for the Output DDR
0.36
0.41
0.48
ns
tDDROCKMPWL
Clock Minimum Pulse Width LOW for the Output DDR
0.32
0.37
0.43
ns
FDDOMAX
Maximum Frequency for the Output DDR
350.00 350.00 350.00
MHz
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 48
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
VersaTile Characteristics
VersaTile Specifications as a Combinatorial Module
The ProASIC3 library offers all combinations of LUT-3 combinatorial functions. In this section, timing
characteristics are presented for a sample of the library. For more details, refer to the Fusion, IGLOO®/e,
and ProASIC3/E Macro Library Guide.
A
A
B
A
OR2
Y
AND2
A
Y
B
B
B
XOR2
A
B
C
Y
A
A
B
C
NOR2
B
A
A
Y
INV
NAND3
A
MAJ3
B
Y
NAND2
XOR3
Y
Y
0
MUX2
B
Y
Y
1
C
S
Figure 2-19 • Sample of Combinatorial Cells
R ev i si o n 1 1
2- 49
ProASIC3 nano DC and Switching Characteristics
tPD
A
NAND2 or
Any Combinatorial
Logic
B
Y
tPD = MAX(tPD(RR), tPD(RF), tPD(FF), tPD(FR))
where edges are applicable for the particular
combinatorial cell
VCC
50%
50%
A, B, C
GND
VCC
50%
50%
OUT
GND
VCC
tPD
tPD
(FF)
(RR)
OUT
tPD
(FR)
50%
tPD
GND
(RF)
Figure 2-20 • Timing Model and Waveforms
2- 50
R ev i sio n 1 1
50%
ProASIC3 nano Flash FPGAs
Timing Characteristics
Table 2-65 • Combinatorial Cell Propagation Delays
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Combinatorial Cell
Equation
Parameter
–2
–1
Std.
Units
Y = !A
tPD
0.40
0.46
0.54
ns
Y=A·B
tPD
0.47
0.54
0.63
ns
Y = !(A · B)
tPD
0.47
0.54
0.63
ns
Y=A+B
tPD
0.49
0.55
0.65
ns
NOR2
Y = !(A + B)
tPD
0.49
0.55
0.65
ns
XOR2
Y = A B
tPD
0.74
0.84
0.99
ns
MAJ3
Y = MAJ(A, B, C)
tPD
0.70
0.79
0.93
ns
XOR3
Y = A  B C
tPD
0.87
1.00
1.17
ns
MUX2
Y = A !S + B S
tPD
0.51
0.58
0.68
ns
AND3
Y=A·B·C
tPD
0.56
0.64
0.75
ns
INV
AND2
NAND2
OR2
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for
derating values.
VersaTile Specifications as a Sequential Module
The ProASIC3 library offers a wide variety of sequential cells, including flip-flops and latches. Each has a
data input and optional enable, clear, or preset. In this section, timing characteristics are presented for a
representative sample from the library. For more details, refer to the Fusion, IGLOO/e, and ProASIC3/E
Macro Library Guide.
Data
D
Q
Out
Data
En
DFN1
D
Out
Q
DFN1E1
CLK
CLK
PRE
Data
D
Q
Out
Data
En
DFN1C1
D
Q
Out
DFI1E1P1
CLK
CLK
CLR
Figure 2-21 • Sample of Sequential Cells
R ev i si o n 1 1
2- 51
ProASIC3 nano DC and Switching Characteristics
tCKMPWH tCKMPWL
CLK
50%
50%
tSUD
50%
Data
EN
PRE
50%
tRECPRE
tREMPRE
50%
50%
50%
CLR
tPRE2Q
50%
tREMCLR
tRECCLR
tWCLR
Out
50%
50%
0
tWPRE
tHE
50%
50%
tHD
50%
tSUE
50%
50%
50%
50%
tCLR2Q
50%
50%
tCLKQ
Figure 2-22 • Timing Model and Waveforms
Timing Characteristics
Table 2-66 • Register Delays
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std.
Units
tCLKQ
Clock-to-Q of the Core Register
0.55 0.63 0.74
ns
tSUD
Data Setup Time for the Core Register
0.43 0.49 0.57
ns
tHD
Data Hold Time for the Core Register
0.00 0.00 0.00
ns
tSUE
Enable Setup Time for the Core Register
0.45 0.52 0.61
ns
tHE
Enable Hold Time for the Core Register
0.00 0.00 0.00
ns
tCLR2Q
Asynchronous Clear-to-Q of the Core Register
0.40 0.45 0.53
ns
tPRE2Q
Asynchronous Preset-to-Q of the Core Register
0.40 0.45 0.53
ns
tREMCLR
Asynchronous Clear Removal Time for the Core Register
0.00 0.00 0.00
ns
tRECCLR
Asynchronous Clear Recovery Time for the Core Register
0.22 0.25 0.30
ns
tREMPRE
Asynchronous Preset Removal Time for the Core Register
0.00 0.00 0.00
ns
tRECPRE
Asynchronous Preset Recovery Time for the Core Register
0.22 0.25 0.30
ns
tWCLR
Asynchronous Clear Minimum Pulse Width for the Core Register
0.22 0.25 0.30
ns
tWPRE
Asynchronous Preset Minimum Pulse Width for the Core Register
0.22 0.25 0.30
ns
tCKMPWH
Clock Minimum Pulse Width HIGH for the Core Register
0.36 0.41 0.48
ns
tCKMPWL
Clock Minimum Pulse Width LOW for the Core Register
0.32 0.37 0.43
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 52
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Global Resource Characteristics
A3PN250 Clock Tree Topology
Clock delays are device-specific. Figure 2-23 is an example of a global tree used for clock routing. The
global tree presented in Figure 2-23 is driven by a CCC located on the west side of the A3PN250 device.
It is used to drive all D-flip-flops in the device.
Central
Global Rib
VersaTile
Rows
CCC
Global Spine
Figure 2-23 • Example of Global Tree Use in an A3PN250 Device for Clock Routing
R ev i si o n 1 1
2- 53
ProASIC3 nano DC and Switching Characteristics
Global Tree Timing Characteristics
Global clock delays include the central rib delay, the spine delay, and the row delay. Delays do not
include I/O input buffer clock delays, as these are I/O standard–dependent, and the clock may be driven
and conditioned internally by the CCC module. For more details on clock conditioning capabilities, refer
to the "Clock Conditioning Circuits" section on page 2-57. Table 2-67 to Table 2-72 on page 2-56 present
minimum and maximum global clock delays within each device. Minimum and maximum delays are
measured with minimum and maximum loading.
Timing Characteristics
Table 2-67 • A3PN010 Global Resource
Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
–2
Parameter Description
Min.
1
–1
Max.
2
Min.
1
Std.
Max.
2
Min.
1
Max. 2 Units
tRCKL
Input LOW Delay for Global Clock
0.60
0.79
0.69
0.90
0.81
1.06
ns
tRCKH
Input HIGH Delay for Global Clock
0.62
0.84
0.70
0.96
0.82
1.12
ns
tRCKMPWH
Minimum Pulse Width HIGH for Global Clock
0.75
0.85
1.00
ns
tRCKMPWL
Minimum Pulse Width LOW for Global Clock
0.85
0.96
1.13
ns
tRCKSW
Maximum Skew for Global Clock
0.22
0.26
0.30
ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element,
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element, located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-68 • A3PN015 Global Resource
Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
–2
Parameter Description
–1
Std.
Min. 1
Max. 2
Min. 1
Max. 2
Min. 1
Max. 2 Units
tRCKL
Input LOW Delay for Global Clock
0.66
0.91
0.75
1.04
0.89
1.22
ns
tRCKH
Input HIGH Delay for Global Clock
0.67
0.96
0.77
1.10
0.90
1.29
ns
tRCKMPWH
Minimum Pulse Width HIGH for Global Clock
0.75
0.85
1.00
ns
tRCKMPWL
Minimum Pulse Width LOW for Global Clock
0.85
0.96
1.13
ns
tRCKSW
Maximum Skew for Global Clock
0.29
0.33
0.39
ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element,
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element, located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 54
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Table 2-69 • A3PN020 Global Resource
Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
–2
Parameter Description
Min.
1
Max.
–1
2
Min.
1
Max.
Std.
2
Min.
1
Max. 2 Units
tRCKL
Input LOW Delay for Global Clock
0.66
0.91
0.75
1.04
0.89
1.22
ns
tRCKH
Input HIGH Delay for Global Clock
0.67
0.96
0.77
1.10
0.90
1.29
ns
tRCKMPWH
Minimum Pulse Width HIGH for Global Clock
0.75
0.85
1.00
ns
tRCKMPWL
Minimum Pulse Width LOW for Global Clock
0.85
0.96
1.13
ns
tRCKSW
Maximum Skew for Global Clock
0.29
0.33
0.39
ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element,
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element, located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-70 • A3PN060 Global Resource
Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
–2
Parameter Description
–1
Std.
Min. 1
Max. 2
Min. 1
Max. 2
Min. 1
Max. 2 Units
tRCKL
Input LOW Delay for Global Clock
0.72
0.91
0.82
1.04
0.96
1.22
ns
tRCKH
Input HIGH Delay for Global Clock
0.71
0.94
0.81
1.07
0.96
1.26
ns
tRCKMPWH
Minimum Pulse Width HIGH for Global Clock
0.75
0.85
1.00
ns
tRCKMPWL
Minimum Pulse Width LOW for Global Clock
0.85
0.96
1.13
ns
tRCKSW
Maximum Skew for Global Clock
0.23
0.26
0.31
ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element,
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element, located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 55
ProASIC3 nano DC and Switching Characteristics
Table 2-71 • A3PN125 Global Resource
Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
–2
Parameter Description
Min.
1
Max.
–1
2
Min.
1
Max.
Std.
2
Min.
1
Max. 2 Units
tRCKL
Input LOW Delay for Global Clock
0.76
0.99
0.87
1.12
1.02
1.32
ns
tRCKH
Input HIGH Delay for Global Clock
0.76
1.02
0.87
1.17
1.02
1.37
ns
tRCKMPWH
Minimum Pulse Width HIGH for Global Clock
0.75
0.85
1.00
ns
tRCKMPWL
Minimum Pulse Width LOW for Global Clock
0.85
0.96
1.13
ns
tRCKSW
Maximum Skew for Global Clock
0.26
0.30
0.35
ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element,
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element, located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
Table 2-72 • A3PN250 Global Resource
Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
–2
Parameter Description
–1
Std.
Min. 1
Max. 2
Min. 1
Max. 2
Min. 1
Max. 2 Units
tRCKL
Input LOW Delay for Global Clock
0.79
1.02
0.90
1.16
1.06
1.36
ns
tRCKH
Input HIGH Delay for Global Clock
0.78
1.04
0.88
1.18
1.04
1.39
ns
tRCKMPWH
Minimum Pulse Width HIGH for Global Clock
0.75
0.85
1.00
ns
tRCKMPWL
Minimum Pulse Width LOW for Global Clock
0.85
0.96
1.13
ns
tRCKSW
Maximum Skew for Global Clock
0.26
0.30
0.35
ns
Notes:
1. Value reflects minimum load. The delay is measured from the CCC output to the clock pin of a sequential element,
located in a lightly loaded row (single element is connected to the global net).
2. Value reflects maximum load. The delay is measured on the clock pin of the farthest sequential element, located in a fully
loaded row (all available flip-flops are connected to the global net in the row).
3. For specific junction temperature and voltage-supply levels, refer to Table 2-6 on page 2-5 for derating values.
2- 56
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Clock Conditioning Circuits
CCC Electrical Specifications
Timing Characteristics
Table 2-73 • ProASIC3 nano CCC/PLL Specification
Parameter
Minimum
Clock Conditioning Circuitry Input Frequency fIN_CCC
1.5
Clock Conditioning Circuitry Output Frequency fOUT_CCC
0.75
Delay Increments in Programmable Delay Blocks 1,2
Typical
Maximum
Units
350
MHz
350
MHz
2003
ps
Number of Programmable Values in Each Programmable Delay
Block
32
Serial Clock (SCLK) for Dynamic PLL 4,5
125
MHz
Input Cycle-to-Cycle Jitter (peak magnitude)
1.5
ns
Acquisition Time
LockControl = 0
300
µs
LockControl = 1
6.0
ms
LockControl = 0
1.6
ns
LockControl = 1
0.8
ns
Tracking Jitter 7
Output Duty Cycle
48.5
51.5
%
Delay Range in Block: Programmable Delay
1 1,2
1.25
15.65
ns
Delay Range in Block: Programmable Delay
2 1,2
0.025
15.65
ns
Delay Range in Block: Fixed Delay 1,2
VCO Output Peak-to-Peak Period Jitter
2.2
FCCC_OUT6
ns
Max Peak-to-Peak Jitter Data
6,8,9
SSO2
SSO4
SSO 8
SSO 16
0.50%
0.50%
0.70%
1.00%
0.75 MHz to 50MHz
50 MHz to 250 MHz
1.00%
3.00%
5.00%
9.00%
250 MHz to 350 MHz
2.50%
4.00%
6.00%
12.00%
Notes:
1. This delay is a function of voltage and temperature. See Table 2-6 on page 2-5 for deratings.
2. TJ = 25°C, VCC = 1.5 V
3. When the CCC/PLL core is generated by Microsemi core generator software, not all delay values of the specified delay
increments are available. Refer to the Libero SoC Online Help for more information.
4. Maximum value obtained for a –2 speed-grade device in worst-case commercial conditions. For specific junction
temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
5. The A3PN010, A3PN015, and A3PN020 devices do not support PLLs.
6. VCO output jitter is calculated as a percentage of the VCO frequency. The jitter (in ps) can be calculated by multiplying
the VCO period by the % jitter. The VCO jitter (in ps) applies to CCC_OUT regardless of the output divider settings. For
example, if the jitter on VCO is 300 ps, the jitter on CCC_OUT is also 300 ps, regardless of the output divider settings.
7. Tracking jitter is defined as the variation in clock edge position of PLL outputs with reference to the PLL input clock
edge. Tracking jitter does not measure the variation in PLL output period, which is covered by the period jitter
parameter.
8. Measurements done with LVTTL 3.3 V 8 mA I/O drive strength and high slew rate. VCC/VCCPLL = 1.425 V, VCCI =
3.3 , VQ/PQ/TQ type of packages, 20 pF load.
9. SSOs are outputs that are synchronous to a single clock domain, and have their clock-to-out times within ± 200 ps of
each other.
R ev i si o n 1 1
2- 57
ProASIC3 nano DC and Switching Characteristics
Output Signal
Tperiod_max
Tperiod_min
Note: Peak-to-peak jitter measurements are defined by Tpeak-to-peak = Tperiod_max – Tperiod_min.
Figure 2-24 • Peak-to-Peak Jitter Definition
2- 58
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Embedded SRAM and FIFO Characteristics
SRAM
RAM512X18
RAM4K9
ADDRA11
ADDRA10
DOUTA8
DOUTA7
RADDR8
RADDR7
RD17
RD16
ADDRA0
DINA8
DINA7
DOUTA0
RADDR0
RD0
RW1
RW0
DINA0
WIDTHA1
WIDTHA0
PIPEA
WMODEA
BLKA
WENA
CLKA
PIPE
REN
RCLK
ADDRB11
ADDRB10
DOUTB8
DOUTB7
ADDRB0
DOUTB0
DINB8
DINB7
WADDR8
WADDR7
WADDR0
WD17
WD16
WD0
DINB0
WW1
WW0
WIDTHB1
WIDTHB0
PIPEB
WMODEB
BLKB
WENB
CLKB
WEN
WCLK
RESET
RESET
Figure 2-25 • RAM Models
R ev i si o n 1 1
2- 59
ProASIC3 nano DC and Switching Characteristics
Timing Waveforms
tCYC
tCKH
tCKL
CLK
tAS
tAH
A1
A0
[R|W]ADDR
A2
tBKS
tBKH
BLK
tENS
tENH
WEN
tCKQ1
DOUT|RD
Dn
D0
D1
D2
tDOH1
Figure 2-26 • RAM Read for Pass-Through Output. Applicable to both RAM4K9 and RAM512x18.
tCYC
tCKH
tCKL
CLK
t
AS
tAH
A0
[R|W]ADDR
A1
A2
tBKS
tBKH
BLK
tENH
tENS
WEN
tCKQ2
DOUT|RD
Dn
D0
D1
tDOH2
Figure 2-27 • RAM Read for Pipelined Output. Applicable to both RAM4K9 and RAM512x18.
2- 60
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
tCYC
tCKH
tCKL
CLK
tAS
tAH
A0
[R|W]ADDR
A1
A2
tBKS
tBKH
BLK
tENS
tENH
WEN
tDS
DI0
DIN|WD
tDH
DI1
Dn
DOUT|RD
D2
Figure 2-28 • RAM Write, Output Retained. Applicable to both RAM4K9 and RAM512x18.
tCYC
tCKH
tCKL
CLK
tAS
tAH
A0
ADDR
A1
A2
tBKS
tBKH
BLK
tENS
WEN
tDS
DI0
DIN
DOUT
(pass-through)
DOUT
(pipelined)
tDH
DI1
Dn
DI2
DI0
DI1
DI0
Dn
DI1
Figure 2-29 • RAM Write, Output as Write Data (WMODE = 1). Applicable to both RAM4K9 only.
R ev i si o n 1 1
2- 61
ProASIC3 nano DC and Switching Characteristics
tCYC
tCKH
tCKL
CLK
RESET
tRSTBQ
DOUT|RD
Dm
Dn
Figure 2-30 • RAM Reset. Applicable to both RAM4K9 and RAM512x18.
2- 62
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Timing Characteristics
Table 2-74 • RAM4K9
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std. Units
tAS
Address Setup time
0.25
0.28
0.33
ns
tAH
Address Hold time
0.00
0.00
0.00
ns
tENS
REN, WEN Setup time
0.14
0.16
0.19
ns
tENH
REN, WEN Hold time
0.10
0.11
0.13
ns
tBKS
BLK Setup time
0.23
0.27
0.31
ns
tBKH
BLK Hold time
0.02
0.02
0.02
ns
tDS
Input data (DIN) Setup time
0.18
0.21
0.25
ns
tDH
Input data (DIN) Hold time
0.00
0.00
0.00
ns
tCKQ1
Clock High to New Data Valid on DOUT (output retained, WMODE = 0)
1.79
2.03
2.39
ns
Clock High to New Data Valid on DOUT (flow-through, WMODE = 1)
2.36
2.68
3.15
ns
tCKQ2
Clock High to New Data Valid on DOUT (pipelined)
0.89
1.02
1.20
ns
tC2CWWL1
Address collision clk-to-clk delay for reliable write after write on same 0.33
address; applicable to closing edge
0.28
0.25
ns
tC2CWWH1
Address collision clk-to-clk delay for reliable write after write on same 0.30
address; applicable to rising edge
0.26
0.23
ns
tC2CRWH1
Address collision clk-to-clk delay for reliable read access after write on same 0.45
address; applicable to opening edge
0.38
0.34
ns
tC2CWRH1
Address collision clk-to-clk delay for reliable write access after read on same 0.49
address; applicable to opening edge
0.42
0.37
ns
tRSTBQ
RESET Low to Data Out Low on DOUT (flow through)
0.92
1.05
1.23
ns
RESET Low to Data Out Low on DOUT (pipelined)
0.92
1.05
1.23
ns
tREMRSTB
RESET Removal
0.29
0.33
0.38
ns
tRECRSTB
RESET Recovery
1.50
1.71
2.01
ns
tMPWRSTB
RESET Minimum Pulse Width
0.21
0.24
0.29
ns
tCYC
Clock Cycle time
3.23
3.68
4.32
ns
FMAX
Maximum Frequency
310
272
231
MHz
Notes:
1. For more information, refer to the application note Simultaneous Read-Write Operations in Dual-Port SRAM for FlashBased cSoCs and FPGAs.
2. For specific junction temperature and voltage-supply levels, refer to Table 3-6 on page 3-4 for derating values.
R ev i si o n 1 1
2- 63
ProASIC3 nano DC and Switching Characteristics
Table 2-75 • RAM512X18
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std. Units
tAS
Address setup time
0.25 0.28 0.33
ns
tAH
Address hold time
0.00 0.00 0.00
ns
tENS
REN, WEN setup time
0.09 0.10 0.12
ns
tENH
REN, WEN hold time
0.06 0.07 0.08
ns
tDS
Input data (WD) setup time
0.18 0.21 0.25
ns
tDH
Input data (WD) hold time
0.00 0.00 0.00
ns
tCKQ1
Clock High to new data valid on RD (output retained)
2.16 2.46 2.89
ns
Clock High to new data valid on RD (pipelined)
0.90 1.02 1.20
ns
1
Address collision clk-to-clk delay for reliable read access after write on same 0.50 0.43 0.38
address; applicable to opening edge
ns
tC2CWRH1
Address collision clk-to-clk delay for reliable write access after read on same 0.59 0.50 0.44
address; applicable to opening edge
ns
tRSTBQ
RESET LOW to data out LOW on RD (flow-through)
0.92 1.05 1.23
ns
RESET LOW to data out LOW on RD (pipelined)
0.92 1.05 1.23
ns
tREMRSTB
RESET removal
0.29 0.33 0.38
ns
tRECRSTB
RESET recovery
1.50 1.71 2.01
ns
tMPWRSTB
RESET minimum pulse width
0.21 0.24 0.29
ns
tCYC
Clock cycle time
3.23 3.68 4.32
ns
FMAX
Maximum frequency
310
tCKQ2
tC2CRWH
272
231 MHz
Notes:
1. For more information, refer to the application note Simultaneous Read-Write Operations in Dual-Port SRAM for FlashBased cSoCs and FPGAs.
2. For specific junction temperature and voltage-supply levels, refer to Table 3-6 on page 3-4 for derating values.
2- 64
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
FIFO
FIFO4K18
RW2
RW1
RW0
WW2
WW1
WW0
ESTOP
FSTOP
RD17
RD16
RD0
FULL
AFULL
EMPTY
AEMPTY
AEVAL11
AEVAL10
AEVAL0
AFVAL11
AFVAL10
AFVAL0
REN
RBLK
RCLK
WD17
WD16
WD0
WEN
WBLK
WCLK
RPIPE
RESET
Figure 2-31 • FIFO Model
R ev i si o n 1 1
2- 65
ProASIC3 nano DC and Switching Characteristics
Timing Waveforms
tCYC
RCLK
tENH
tENS
REN
tBKH
tBKS
RBLK
tCKQ1
RD
(flow-through)
Dn
D0
D1
D2
D0
D1
tCKQ2
RD
(pipelined)
Dn
Figure 2-32 • FIFO Read
tCYC
WCLK
tENS
tENH
WEN
WBLK
tBKS
tBKH
tDS
WD
DI0
tDH
DI1
Figure 2-33 • FIFO Write
2- 66
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
RCLK/
WCLK
tMPWRSTB
tRSTCK
RESET
tRSTFG
EMPTY
tRSTAF
AEMPTY
tRSTFG
FULL
tRSTAF
AFULL
WA/RA
(Address Counter)
MATCH (A0)
Figure 2-34 • FIFO Reset
tCYC
RCLK
tRCKEF
EMPTY
tCKAF
AEMPTY
WA/RA
(Address Counter) NO MATCH
NO MATCH
Dist = AEF_TH
MATCH (EMPTY)
Figure 2-35 • FIFO EMPTY Flag and AEMPTY Flag Assertion
R ev i si o n 1 1
2- 67
ProASIC3 nano DC and Switching Characteristics
tCYC
WCLK
tWCKFF
FULL
tCKAF
AFULL
WA/RA NO MATCH
(Address Counter)
NO MATCH
Dist = AFF_TH
MATCH (FULL)
Figure 2-36 • FIFO FULL Flag and AFULL Flag Assertion
WCLK
WA/RA MATCH
(Address Counter) (EMPTY)
RCLK
NO MATCH
1st Rising
Edge
After 1st
Write
NO MATCH
NO MATCH
NO MATCH
Dist = AEF_TH + 1
2nd Rising
Edge
After 1st
Write
tRCKEF
EMPTY
tCKAF
AEMPTY
Figure 2-37 • FIFO EMPTY Flag and AEMPTY Flag Deassertion
RCLK
WA/RA
(Address Counter)
WCLK
MATCH (FULL)
NO MATCH
1st Rising
Edge
After 1st
Read
NO MATCH
NO MATCH
NO MATCH
Dist = AFF_TH – 1
1st Rising
Edge
After 2nd
Read
tWCKF
FULL
tCKAF
AFULL
Figure 2-38 • FIFO FULL Flag and AFULL Flag Deassertion
2- 68
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
Timing Characteristics
Table 2-76 • FIFO
Worst Commercial-Case Conditions: TJ = 70°C, VCC = 1.425 V
Parameter
Description
–2
–1
Std.
Units
tENS
REN, WEN Setup Time
1.38
1.57
1.84
ns
tENH
REN, WEN Hold Time
0.02
0.02
0.02
ns
tBKS
BLK Setup Time
0.22
0.25
0.30
ns
tBKH
BLK Hold Time
0.00
0.00
0.00
ns
tDS
Input Data (WD) Setup Time
0.18
0.21
0.25
ns
tDH
Input Data (WD) Hold Time
0.00
0.00
0.00
ns
tCKQ1
Clock High to New Data Valid on RD (flow-through)
2.36
2.68
3.15
ns
tCKQ2
Clock High to New Data Valid on RD (pipelined)
0.89
1.02
1.20
ns
tRCKEF
RCLK High to Empty Flag Valid
1.72
1.96
2.30
ns
tWCKFF
WCLK High to Full Flag Valid
1.63
1.86
2.18
ns
tCKAF
Clock High to Almost Empty/Full Flag Valid
6.19
7.05
8.29
ns
tRSTFG
RESET LOW to Empty/Full Flag Valid
1.69
1.93
2.27
ns
tRSTAF
RESET LOW to Almost Empty/Full Flag Valid
6.13
6.98
8.20
ns
tRSTBQ
RESET Low to Data Out Low on RD (flow-through)
0.92
1.05
1.23
ns
RESET Low to Data Out Low on RD (pipelined)
0.92
1.05
1.23
ns
tREMRSTB
RESET Removal
0.29
0.33
0.38
ns
tRECRSTB
RESET Recovery
1.50
1.71
2.01
ns
tMPWRSTB
RESET Minimum Pulse Width
0.21
0.24
0.29
ns
tCYC
Clock Cycle Time
3.23
3.68
4.32
ns
FMAX
Maximum Frequency for FIFO
310
272
231
MHz
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for derating values.
R ev i si o n 1 1
2- 69
ProASIC3 nano DC and Switching Characteristics
Embedded FlashROM Characteristics
tSU
CLK
tSU
tHOLD
Address
tSU
tHOLD
A0
tHOLD
A1
tCKQ2
tCKQ2
D0
Data
tCKQ2
D0
D1
Figure 2-39 • Timing Diagram
Timing Characteristics
Table 2-77 • Embedded FlashROM Access Time
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std.
Units
tSU
Address Setup Time
0.53
0.61
0.71
ns
tHOLD
Address Hold Time
0.00
0.00
0.00
ns
tCK2Q
Clock to Out
16.23
18.48
21.73
ns
FMAX
Maximum Clock Frequency
15.00
15.00
15.00
MHz
2- 70
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
JTAG 1532 Characteristics
JTAG timing delays do not include JTAG I/Os. To obtain complete JTAG timing, add I/O buffer delays to
the corresponding standard selected; refer to the I/O timing characteristics in the "User I/O
Characteristics" section on page 2-12 for more details.
Timing Characteristics
Table 2-78 • JTAG 1532
Commercial-Case Conditions: TJ = 70°C, Worst-Case VCC = 1.425 V
Parameter
Description
–2
–1
Std.
Units
tDISU
Test Data Input Setup Time
0.53
0.60
0.71
ns
tDIHD
Test Data Input Hold Time
1.07
1.21
1.42
ns
tTMSSU
Test Mode Select Setup Time
0.53
0.60
0.71
ns
tTMDHD
Test Mode Select Hold Time
1.07
1.21
1.42
ns
tTCK2Q
Clock to Q (data out)
6.39
7.24
8.52
ns
tRSTB2Q
Reset to Q (data out)
21.31
24.15
28.41
ns
FTCKMAX
TCK Maximum Frequency
23.00
20.00
17.00
MHz
tTRSTREM
ResetB Removal Time
0.00
0.00
0.00
ns
tTRSTREC
ResetB Recovery Time
0.21
0.24
0.28
ns
tTRSTMPW
ResetB Minimum Pulse
TBD
TBD
TBD
ns
Note: For specific junction temperature and voltage supply levels, refer to Table 2-6 on page 2-5 for
derating values.
R ev i si o n 1 1
2- 71
ProASIC3 nano DC and Switching Characteristics
2- 72
R ev i sio n 1 1
3 – Pin Descriptions and Packaging
Supply Pins
GND
Ground
Ground supply voltage to the core, I/O outputs, and I/O logic.
GNDQ
Ground (quiet)
Quiet ground supply voltage to input buffers of I/O banks. Within the package, the GNDQ plane is
decoupled from the simultaneous switching noise originated from the output buffer ground domain. This
minimizes the noise transfer within the package and improves input signal integrity. GNDQ must always
be connected to GND on the board.
VCC
Core Supply Voltage
Supply voltage to the FPGA core, nominally 1.5 V. VCC is required for powering the JTAG state machine
in addition to VJTAG. Even when a device is in bypass mode in a JTAG chain of interconnected devices,
both VCC and VJTAG must remain powered to allow JTAG signals to pass through the device.
VCCIBx
I/O Supply Voltage
Supply voltage to the bank's I/O output buffers and I/O logic. Bx is the I/O bank number. There are up to
eight I/O banks on low power flash devices plus a dedicated VJTAG bank. Each bank can have a
separate VCCI connection. All I/Os in a bank will run off the same VCCIBx supply. VCCI can be 1.5 V,
1.8 V, 2.5 V, or 3.3 V, nominal voltage. Unused I/O banks should have their corresponding VCCI pins tied
to GND.
VMVx
I/O Supply Voltage (quiet)
Quiet supply voltage to the input buffers of each I/O bank. x is the bank number. Within the package, the
VMV plane biases the input stage of the I/Os in the I/O banks. This minimizes the noise transfer within
the package and improves input signal integrity. Each bank must have at least one VMV connection, and
no VMV should be left unconnected. All I/Os in a bank run off the same VMVx supply. VMV is used to
provide a quiet supply voltage to the input buffers of each I/O bank. VMVx can be 1.5 V, 1.8 V, 2.5 V, or
3.3 V, nominal voltage. Unused I/O banks should have their corresponding VMV pins tied to GND. VMV
and VCCI should be at the same voltage within a given I/O bank. Used VMV pins must be connected to
the corresponding VCCI pins of the same bank (i.e., VMV0 to VCCIB0, VMV1 to VCCIB1, etc.).
VCCPLA/B/C/D/E/F
PLL Supply Voltage
Supply voltage to analog PLL, nominally 1.5 V.
When the PLLs are not used, the place-and-route tool automatically disables the unused PLLs to lower
power consumption. The user should tie unused VCCPLx and VCOMPLx pins to ground. Microsemi
recommends tying VCCPLx to VCC and using proper filtering circuits to decouple VCC noise from the
PLLs. Refer to the PLL Power Supply Decoupling section of the "Clock Conditioning Circuits in Low
Power Flash Devices and Mixed Signal FPGAs" chapter of the ProASIC3 nano Device Family User’s
Guide for a complete board solution for the PLL analog power supply and ground.
There is one VCCPLF pin on ProASIC3 nano devices.
VCOMPLA/B/C/D/E/F
PLL Ground
Ground to analog PLL power supplies. When the PLLs are not used, the place-and-route tool
automatically disables the unused PLLs to lower power consumption. The user should tie unused
VCCPLx and VCOMPLx pins to ground.
There is one VCOMPLF pin on ProASIC3 nano devices.
VJTAG
JTAG Supply Voltage
Low power flash devices have a separate bank for the dedicated JTAG pins. The JTAG pins can be run
at any voltage from 1.5 V to 3.3 V (nominal). Isolating the JTAG power supply in a separate I/O bank
R ev i si o n 1 1
3 -1
Pin Descriptions and Packaging
gives greater flexibility in supply selection and simplifies power supply and PCB design. If the JTAG
interface is neither used nor planned for use, the VJTAG pin together with the TRST pin could be tied to
GND. It should be noted that VCC is required to be powered for JTAG operation; VJTAG alone is
insufficient. If a device is in a JTAG chain of interconnected boards, the board containing the device can
be powered down, provided both VJTAG and VCC to the part remain powered; otherwise, JTAG signals
will not be able to transition the device, even in bypass mode.
Microsemi recommends that VPUMP and VJTAG power supplies be kept separate with independent
filtering capacitors rather than supplying them from a common rail.
VPUMP
Programming Supply Voltage
ProASIC3 devices support single-voltage ISP of the configuration flash and FlashROM. For
programming, VPUMP should be 3.3 V nominal. During normal device operation, VPUMP can be left
floating or can be tied (pulled up) to any voltage between 0 V and the VPUMP maximum. Programming
power supply voltage (VPUMP) range is listed in the datasheet.
When the VPUMP pin is tied to ground, it will shut off the charge pump circuitry, resulting in no sources of
oscillation from the charge pump circuitry.
For proper programming, 0.01 µF and 0.33 µF capacitors (both rated at 16 V) are to be connected in
parallel across VPUMP and GND, and positioned as close to the FPGA pins as possible.
Microsemi recommends that VPUMP and VJTAG power supplies be kept separate with independent
filtering capacitors rather than supplying them from a common rail.
User Pins
I/O
User Input/Output
The I/O pin functions as an input, output, tristate, or bidirectional buffer. Input and output signal levels are
compatible with the I/O standard selected.
During programming, I/Os become tristated and weakly pulled up to VCCI. With VCCI, VMV, and VCC
supplies continuously powered up, when the device transitions from programming to operating mode, the
I/Os are instantly configured to the desired user configuration.
Unused I/Os are configured as follows:
GL
•
Output buffer is disabled (with tristate value of high impedance)
•
Input buffer is disabled (with tristate value of high impedance)
•
Weak pull-up is programmed
Globals
GL I/Os have access to certain clock conditioning circuitry (and the PLL) and/or have direct access to the
global network (spines). Additionally, the global I/Os can be used as regular I/Os, since they have
identical capabilities. Unused GL pins are configured as inputs with pull-up resistors.
See more detailed descriptions of global I/O connectivity in the "Clock Conditioning Circuits in Low Power
Flash Devices and Mixed Signal FPGAs" chapter of the ProASIC3 nano Device Family User’s Guide. All
inputs labeled GC/GF are direct inputs into the quadrant clocks. For example, if GAA0 is used for an
input, GAA1 and GAA2 are no longer available for input to the quadrant globals. All inputs labeled
GC/GF are direct inputs into the chip-level globals, and the rest are connected to the quadrant globals.
The inputs to the global network are multiplexed, and only one input can be used as a global input.
Refer to the I/O Structure chapter of the ProASIC3 nano Device Family User’s Guide for an explanation
of the naming of global pins.
3- 2
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
JTAG Pins
Low power flash devices have a separate bank for the dedicated JTAG pins. The JTAG pins can be run
at any voltage from 1.5 V to 3.3 V (nominal). VCC must also be powered for the JTAG state machine to
operate, even if the device is in bypass mode; VJTAG alone is insufficient. Both VJTAG and VCC to the
part must be supplied to allow JTAG signals to transition the device. Isolating the JTAG power supply in a
separate I/O bank gives greater flexibility in supply selection and simplifies power supply and PCB
design. If the JTAG interface is neither used nor planned for use, the VJTAG pin together with the TRST
pin could be tied to GND.
TCK
Test Clock
Test clock input for JTAG boundary scan, ISP, and UJTAG. The TCK pin does not have an internal pullup/-down resistor. If JTAG is not used, Microsemi recommends tying off TCK to GND through a resistor
placed close to the FPGA pin. This prevents JTAG operation in case TMS enters an undesired state.
Note that to operate at all VJTAG voltages, 500  to 1 k will satisfy the requirements. Refer to Table 3-1
for more information.
Table 3-1 • Recommended Tie-Off Values for the TCK and TRST Pins
VJTAG
Tie-Off Resistance
VJTAG at 3.3 V
200  to 1 k
VJTAG at 2.5 V
200  to 1 k
VJTAG at 1.8 V
500  to 1 k
VJTAG at 1.5 V
500  to 1 k
Notes:
1. Equivalent parallel resistance if more than one device is on the JTAG chain
2. The TCK pin can be pulled up/down.
3. The TRST pin is pulled down.
TDI
Test Data Input
Serial input for JTAG boundary scan, ISP, and UJTAG usage. There is an internal weak pull-up resistor
on the TDI pin.
TDO
Test Data Output
Serial output for JTAG boundary scan, ISP, and UJTAG usage.
TMS
Test Mode Select
The TMS pin controls the use of the IEEE 1532 boundary scan pins (TCK, TDI, TDO, TRST). There is an
internal weak pull-up resistor on the TMS pin.
TRST
Boundary Scan Reset Pin
The TRST pin functions as an active-low input to asynchronously initialize (or reset) the boundary scan
circuitry. There is an internal weak pull-up resistor on the TRST pin. If JTAG is not used, an external pulldown resistor could be included to ensure the test access port (TAP) is held in reset mode. The resistor
values must be chosen from Table 3-1 and must satisfy the parallel resistance value requirement. The
values in Table 3-1 correspond to the resistor recommended when a single device is used, and the
equivalent parallel resistor when multiple devices are connected via a JTAG chain.
In critical applications, an upset in the JTAG circuit could allow entrance to an undesired JTAG state. In
such cases, Microsemi recommends tying off TRST to GND through a resistor placed close to the FPGA
pin.
Note that to operate at all VJTAG voltages, 500 W to 1 kW will satisfy the requirements.
R ev i si o n 1 1
3 -3
Pin Descriptions and Packaging
Special Function Pins
NC
No Connect
This pin is not connected to circuitry within the device. These pins can be driven to any voltage or can be
left floating with no effect on the operation of the device.
DC
Do Not Connect
This pin should not be connected to any signals on the PCB. These pins should be left unconnected.
Packaging
Semiconductor technology is constantly shrinking in size while growing in capability and functional
integration. To enable next-generation silicon technologies, semiconductor packages have also evolved
to provide improved performance and flexibility.
Microsemi consistently delivers packages that provide the necessary mechanical and environmental
protection to ensure consistent reliability and performance. Microsemi IC packaging technology
efficiently supports high-density FPGAs with large-pin-count Ball Grid Arrays (BGAs), but is also flexible
enough to accommodate stringent form factor requirements for Chip Scale Packaging (CSP). In addition,
Microsemi offers a variety of packages designed to meet your most demanding application and economic
requirements for today's embedded and mobile systems.
Related Documents
User’s Guides
ProASIC nano Device Family User’s Guide
http://www.microsemi.com/soc/documents/PA3_nano_UG.pdf
Packaging
The following documents provide packaging information and device selection for low power flash
devices.
Product Catalog
http://www.microsemi.com/soc/documents/ProdCat_PIB.pdf
Lists devices currently recommended for new designs and the packages available for each member of
the family. Use this document or the datasheet tables to determine the best package for your design, and
which package drawing to use.
Package Mechanical Drawings
http://www.microsemi.com/soc/documents/PckgMechDrwngs.pdf
This document contains the package mechanical drawings for all packages currently or previously
supplied by Microsemi. Use the bookmarks to navigate to the package mechanical drawings.
Additional packaging materials: http://www.microsemi.com/soc/products/solutions/package/docs.aspx.
3- 4
R ev isio n 1 1
4 – Package Pin Assignments
48-Pin QFN
Pin 1
48
1
Notes:
1. This is the bottom view of the package.
2. The die attach paddle of the package is tied to ground (GND).
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/docs.aspx.
R ev i si o n 1 1
4 -1
Package Pin Assignments
48-Pin QFN
48-Pin QFN
Pin Number
A3PN010
Function
Pin Number
A3PN010
Function
1
GEC0/IO37RSB1
36
IO07RSB0
2
IO36RSB1
37
IO06RSB0
3
GEA0/IO34RSB1
38
GDA0/IO05RSB0
4
IO22RSB1
39
IO03RSB0
5
GND
40
GDC0/IO01RSB0
6
VCCIB1
41
IO12RSB1
7
IO24RSB1
42
IO13RSB1
8
IO33RSB1
43
IO15RSB1
9
IO26RSB1
44
IO16RSB1
10
IO32RSB1
45
IO18RSB1
11
IO27RSB1
46
IO19RSB1
12
IO29RSB1
47
IO20RSB1
13
IO30RSB1
48
IO21RSB1
14
IO31RSB1
15
IO28RSB1
16
IO25RSB1
17
IO23RSB1
18
VCC
19
VCCIB1
20
IO17RSB1
21
IO14RSB1
22
TCK
23
TDI
24
TMS
25
VPUMP
26
TDO
27
TRST
28
VJTAG
29
IO11RSB0
30
IO10RSB0
31
IO09RSB0
32
IO08RSB0
33
VCCIB0
34
GND
35
VCC
4- 2
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
48-Pin QFN
48-Pin QFN
Pin Number
A3PN030Z
Function
Pin Number
A3PN030Z
Function
1
IO82RSB1
36
IO25RSB0
2
GEC0/IO73RSB1
37
IO24RSB0
3
GEA0/IO72RSB1
38
IO22RSB0
4
GEB0/IO71RSB1
39
IO20RSB0
5
GND
40
IO18RSB0
6
VCCIB1
41
IO16RSB0
7
IO68RSB1
42
IO14RSB0
8
IO67RSB1
43
IO10RSB0
9
IO66RSB1
44
IO08RSB0
10
IO65RSB1
45
IO06RSB0
11
IO64RSB1
46
IO04RSB0
12
IO62RSB1
47
IO02RSB0
13
IO61RSB1
48
IO00RSB0
14
IO60RSB1
15
IO57RSB1
16
IO55RSB1
17
IO53RSB1
18
VCC
19
VCCIB1
20
IO46RSB1
21
IO42RSB1
22
TCK
23
TDI
24
TMS
25
VPUMP
26
TDO
27
TRST
28
VJTAG
29
IO38RSB0
30
GDB0/IO34RSB0
31
GDA0/IO33RSB0
32
GDC0/IO32RSB0
33
VCCIB0
34
GND
35
VCC
R ev i si o n 1 1
4 -3
Package Pin Assignments
68-Pin QFN
Pin A1 Mark
68
1
Notes:
1. This is the bottom view of the package.
2. The die attach paddle of the package is tied to ground (GND).
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/docs.aspx.
4- 4
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
68-Pin QFN
68-Pin QFN
Pin Number
A3PN015 Function
Pin Number
A3PN015 Function
1
IO60RSB2
37
TRST
2
IO54RSB2
38
VJTAG
3
IO52RSB2
39
IO17RSB0
4
IO50RSB2
40
IO16RSB0
5
IO49RSB2
41
GDA0/IO15RSB0
6
GEC0/IO48RSB2
42
GDC0/IO14RSB0
7
GEA0/IO47RSB2
43
IO13RSB0
8
VCC
44
VCCIB0
9
GND
45
GND
10
VCCIB2
46
VCC
11
IO46RSB2
47
IO12RSB0
12
IO45RSB2
48
IO11RSB0
13
IO44RSB2
49
IO09RSB0
14
IO43RSB2
50
IO05RSB0
15
IO42RSB2
51
IO00RSB0
16
IO41RSB2
52
IO07RSB0
17
IO40RSB2
53
IO03RSB0
18
IO39RSB1
54
IO18RSB1
19
IO37RSB1
55
IO20RSB1
20
IO35RSB1
56
IO22RSB1
21
IO33RSB1
57
IO24RSB1
22
IO31RSB1
58
IO28RSB1
23
IO30RSB1
59
NC
24
VCC
60
GND
25
GND
61
NC
26
VCCIB1
62
IO32RSB1
27
IO27RSB1
63
IO34RSB1
28
IO25RSB1
64
IO36RSB1
29
IO23RSB1
65
IO61RSB2
30
IO21RSB1
66
IO58RSB2
31
IO19RSB1
67
IO56RSB2
32
TCK
68
IO63RSB2
33
TDI
34
TMS
35
VPUMP
36
TDO
R ev i si o n 1 1
4 -5
Package Pin Assignments
68-Pin QFN
68-Pin QFN
Pin Number
A3PN020
Function
Pin Number
A3PN020
Function
1
IO60RSB2
36
TDO
2
IO54RSB2
37
TRST
3
IO52RSB2
38
VJTAG
4
IO50RSB2
39
IO17RSB0
5
IO49RSB2
40
IO16RSB0
6
GEC0/IO48RSB2
41
GDA0/IO15RSB0
7
GEA0/IO47RSB2
42
GDC0/IO14RSB0
8
VCC
43
IO13RSB0
9
GND
44
VCCIB0
10
VCCIB2
45
GND
11
IO46RSB2
46
VCC
12
IO45RSB2
47
IO12RSB0
13
IO44RSB2
48
IO11RSB0
14
IO43RSB2
49
IO09RSB0
15
IO42RSB2
50
IO05RSB0
16
IO41RSB2
51
IO00RSB0
17
IO40RSB2
52
IO07RSB0
18
IO39RSB1
53
IO03RSB0
19
IO37RSB1
54
IO18RSB1
20
IO35RSB1
55
IO20RSB1
21
IO33RSB1
56
IO22RSB1
22
IO31RSB1
57
IO24RSB1
23
IO30RSB1
58
IO28RSB1
24
VCC
59
NC
25
GND
60
GND
26
VCCIB1
61
NC
27
IO27RSB1
62
IO32RSB1
28
IO25RSB1
63
IO34RSB1
29
IO23RSB1
64
IO36RSB1
30
IO21RSB1
65
IO61RSB2
31
IO19RSB1
66
IO58RSB2
32
TCK
67
IO56RSB2
33
TDI
68
IO63RSB2
34
TMS
35
VPUMP
4- 6
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
68-Pin QFN
68-Pin QFN
Pin Number A3PN030Z Function
Pin Number A3PN030Z Function
1
IO82RSB1
37
TRST
2
IO80RSB1
38
VJTAG
3
IO78RSB1
39
IO40RSB0
4
IO76RSB1
40
IO37RSB0
5
GEC0/IO73RSB1
41
GDB0/IO34RSB0
6
GEA0/IO72RSB1
42
GDA0/IO33RSB0
7
GEB0/IO71RSB1
43
GDC0/IO32RSB0
8
VCC
44
VCCIB0
9
GND
45
GND
10
VCCIB1
46
VCC
11
IO68RSB1
47
IO31RSB0
12
IO67RSB1
48
IO29RSB0
13
IO66RSB1
49
IO28RSB0
14
IO65RSB1
50
IO27RSB0
15
IO64RSB1
51
IO25RSB0
16
IO63RSB1
52
IO24RSB0
17
IO62RSB1
53
IO22RSB0
18
IO60RSB1
54
IO21RSB0
19
IO58RSB1
55
IO19RSB0
20
IO56RSB1
56
IO17RSB0
21
IO54RSB1
57
IO15RSB0
22
IO52RSB1
58
IO14RSB0
23
IO51RSB1
59
VCCIB0
24
VCC
60
GND
25
GND
61
VCC
26
VCCIB1
62
IO12RSB0
27
IO50RSB1
63
IO10RSB0
28
IO48RSB1
64
IO08RSB0
29
IO46RSB1
65
IO06RSB0
30
IO44RSB1
66
IO04RSB0
31
IO42RSB1
67
IO02RSB0
32
TCK
68
IO00RSB0
33
TDI
34
TMS
35
VPUMP
36
TDO
R ev i si o n 1 1
4 -7
Package Pin Assignments
100-Pin VQFP
100
1
Note: This is the top view of the package.
Note
For Package Manufacturing and Environmental information, visit the Resource Center at
http://www.microsemi.com/soc/products/solutions/package/docs.aspx.
4- 8
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin Number
A3PN030Z
Function
Pin Number
A3PN030Z
Function
Pin Number
A3PN030Z
Function
1
GND
36
IO51RSB1
71
IO29RSB0
2
IO82RSB1
37
VCC
72
IO28RSB0
3
IO81RSB1
38
GND
73
IO27RSB0
4
IO80RSB1
39
VCCIB1
74
IO26RSB0
5
IO79RSB1
40
IO49RSB1
75
IO25RSB0
6
IO78RSB1
41
IO47RSB1
76
IO24RSB0
7
IO77RSB1
42
IO46RSB1
77
IO23RSB0
8
IO76RSB1
43
IO45RSB1
78
IO22RSB0
9
GND
44
IO44RSB1
79
IO21RSB0
10
IO75RSB1
45
IO43RSB1
80
IO20RSB0
11
IO74RSB1
46
IO42RSB1
81
IO19RSB0
12
GEC0/IO73RSB1
47
TCK
82
IO18RSB0
13
GEA0/IO72RSB1
48
TDI
83
IO17RSB0
14
GEB0/IO71RSB1
49
TMS
84
IO16RSB0
15
IO70RSB1
50
NC
85
IO15RSB0
16
IO69RSB1
51
GND
86
IO14RSB0
17
VCC
52
VPUMP
87
VCCIB0
18
VCCIB1
53
NC
88
GND
19
IO68RSB1
54
TDO
89
VCC
20
IO67RSB1
55
TRST
90
IO12RSB0
21
IO66RSB1
56
VJTAG
91
IO10RSB0
22
IO65RSB1
57
IO41RSB0
92
IO08RSB0
23
IO64RSB1
58
IO40RSB0
93
IO07RSB0
24
IO63RSB1
59
IO39RSB0
94
IO06RSB0
25
IO62RSB1
60
IO38RSB0
95
IO05RSB0
26
IO61RSB1
61
IO37RSB0
96
IO04RSB0
27
IO60RSB1
62
IO36RSB0
97
IO03RSB0
28
IO59RSB1
63
GDB0/IO34RSB0
98
IO02RSB0
29
IO58RSB1
64
GDA0/IO33RSB0
99
IO01RSB0
30
IO57RSB1
65
GDC0/IO32RSB0
100
IO00RSB0
31
IO56RSB1
66
VCCIB0
32
IO55RSB1
67
GND
33
IO54RSB1
68
VCC
34
IO53RSB1
69
IO31RSB0
35
IO52RSB1
70
IO30RSB0
R ev i si o n 1 1
4 -9
Package Pin Assignments
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin Number
A3PN060
Function
Pin Number
A3PN060
Function
Pin Number
A3PN060
Function
1
GND
36
IO61RSB1
71
GBB2/IO27RSB0
2
GAA2/IO51RSB1
37
VCC
72
IO26RSB0
3
IO52RSB1
38
GND
73
GBA2/IO25RSB0
4
GAB2/IO53RSB1
39
VCCIB1
74
VMV0
5
IO95RSB1
40
IO60RSB1
75
GNDQ
6
GAC2/IO94RSB1
41
IO59RSB1
76
GBA1/IO24RSB0
7
IO93RSB1
42
IO58RSB1
77
GBA0/IO23RSB0
8
IO92RSB1
43
IO57RSB1
78
GBB1/IO22RSB0
9
GND
44
GDC2/IO56RSB1
79
GBB0/IO21RSB0
10
GFB1/IO87RSB1
45
GDB2/IO55RSB1
80
GBC1/IO20RSB0
11
GFB0/IO86RSB1
46
GDA2/IO54RSB1
81
GBC0/IO19RSB0
12
VCOMPLF
47
TCK
82
IO18RSB0
13
GFA0/IO85RSB1
48
TDI
83
IO17RSB0
14
VCCPLF
49
TMS
84
IO15RSB0
15
GFA1/IO84RSB1
50
VMV1
85
IO13RSB0
16
GFA2/IO83RSB1
51
GND
86
IO11RSB0
17
VCC
52
VPUMP
87
VCCIB0
18
VCCIB1
53
NC
88
GND
19
GEC1/IO77RSB1
54
TDO
89
VCC
20
GEB1/IO75RSB1
55
TRST
90
IO10RSB0
21
GEB0/IO74RSB1
56
VJTAG
91
IO09RSB0
22
GEA1/IO73RSB1
57
GDA1/IO49RSB0
92
IO08RSB0
23
GEA0/IO72RSB1
58
GDC0/IO46RSB0
93
GAC1/IO07RSB0
24
VMV1
59
GDC1/IO45RSB0
94
GAC0/IO06RSB0
25
GNDQ
60
GCC2/IO43RSB0
95
GAB1/IO05RSB0
26
GEA2/IO71RSB1
61
GCB2/IO42RSB0
96
GAB0/IO04RSB0
27
GEB2/IO70RSB1
62
GCA0/IO40RSB0
97
GAA1/IO03RSB0
28
GEC2/IO69RSB1
63
GCA1/IO39RSB0
98
GAA0/IO02RSB0
29
IO68RSB1
64
GCC0/IO36RSB0
99
IO01RSB0
30
IO67RSB1
65
GCC1/IO35RSB0
100
IO00RSB0
31
IO66RSB1
66
VCCIB0
32
IO65RSB1
67
GND
33
IO64RSB1
68
VCC
34
IO63RSB1
69
IO31RSB0
35
IO62RSB1
70
GBC2/IO29RSB0
4- 10
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin
Number
A3PN060Z
Pin
Number
A3PN060Z
Pin
Number
A3PN060Z
1
GND
36
IO61RSB1
71
GBB2/IO27RSB0
2
GAA2/IO51RSB1
37
VCC
72
IO26RSB0
3
IO52RSB1
38
GND
73
GBA2/IO25RSB0
4
GAB2/IO53RSB1
39
VCCIB1
74
VMV0
5
IO95RSB1
40
IO60RSB1
75
GNDQ
6
GAC2/IO94RSB1
41
IO59RSB1
76
GBA1/IO24RSB0
7
IO93RSB1
42
IO58RSB1
77
GBA0/IO23RSB0
8
IO92RSB1
43
IO57RSB1
78
GBB1/IO22RSB0
9
GND
44
GDC2/IO56RSB1
79
GBB0/IO21RSB0
10
GFB1/IO87RSB1
45
GDB2/IO55RSB1
80
GBC1/IO20RSB0
11
GFB0/IO86RSB1
46
GDA2/IO54RSB1
81
GBC0/IO19RSB0
12
VCOMPLF
47
TCK
82
IO18RSB0
13
GFA0/IO85RSB1
48
TDI
83
IO17RSB0
14
VCCPLF
49
TMS
84
IO15RSB0
15
GFA1/IO84RSB1
50
VMV1
85
IO13RSB0
16
GFA2/IO83RSB1
51
GND
86
IO11RSB0
17
VCC
52
VPUMP
87
VCCIB0
18
VCCIB1
53
NC
88
GND
19
GEC1/IO77RSB1
54
TDO
89
VCC
20
GEB1/IO75RSB1
55
TRST
90
IO10RSB0
21
GEB0/IO74RSB1
56
VJTAG
91
IO09RSB0
22
GEA1/IO73RSB1
57
GDA1/IO49RSB0
92
IO08RSB0
23
GEA0/IO72RSB1
58
GDC0/IO46RSB0
93
GAC1/IO07RSB0
24
VMV1
59
GDC1/IO45RSB0
94
GAC0/IO06RSB0
25
GNDQ
60
GCC2/IO43RSB0
95
GAB1/IO05RSB0
26
GEA2/IO71RSB1
61
GCB2/IO42RSB0
96
GAB0/IO04RSB0
27
GEB2/IO70RSB1
62
GCA0/IO40RSB0
97
GAA1/IO03RSB0
28
GEC2/IO69RSB1
63
GCA1/IO39RSB0
98
GAA0/IO02RSB0
29
IO68RSB1
64
GCC0/IO36RSB0
99
IO01RSB0
30
IO67RSB1
65
GCC1/IO35RSB0
100
IO00RSB0
31
IO66RSB1
66
VCCIB0
32
IO65RSB1
67
GND
33
IO64RSB1
68
VCC
34
IO63RSB1
69
IO31RSB0
35
IO62RSB1
70
GBC2/IO29RSB0
R ev i si o n 1 1
4- 11
Package Pin Assignments
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin Number
A3PN125
Function
Pin Number
A3PN125
Function
Pin Number
A3PN125
Function
1
GND
36
IO93RSB1
71
GBB2/IO43RSB0
2
GAA2/IO67RSB1
37
VCC
72
IO42RSB0
3
IO68RSB1
38
GND
73
GBA2/IO41RSB0
4
GAB2/IO69RSB1
39
VCCIB1
74
VMV0
5
IO132RSB1
40
IO87RSB1
75
GNDQ
6
GAC2/IO131RSB1
41
IO84RSB1
76
GBA1/IO40RSB0
7
IO130RSB1
42
IO81RSB1
77
GBA0/IO39RSB0
8
IO129RSB1
43
IO75RSB1
78
GBB1/IO38RSB0
9
GND
44
GDC2/IO72RSB1
79
GBB0/IO37RSB0
10
GFB1/IO124RSB1
45
GDB2/IO71RSB1
80
GBC1/IO36RSB0
11
GFB0/IO123RSB1
46
GDA2/IO70RSB1
81
GBC0/IO35RSB0
12
VCOMPLF
47
TCK
82
IO32RSB0
13
GFA0/IO122RSB1
48
TDI
83
IO28RSB0
14
VCCPLF
49
TMS
84
IO25RSB0
15
GFA1/IO121RSB1
50
VMV1
85
IO22RSB0
16
GFA2/IO120RSB1
51
GND
86
IO19RSB0
17
VCC
52
VPUMP
87
VCCIB0
18
VCCIB1
53
NC
88
GND
19
GEC0/IO111RSB1
54
TDO
89
VCC
20
GEB1/IO110RSB1
55
TRST
90
IO15RSB0
21
GEB0/IO109RSB1
56
VJTAG
91
IO13RSB0
22
GEA1/IO108RSB1
57
GDA1/IO65RSB0
92
IO11RSB0
23
GEA0/IO107RSB1
58
GDC0/IO62RSB0
93
IO09RSB0
24
VMV1
59
GDC1/IO61RSB0
94
IO07RSB0
25
GNDQ
60
GCC2/IO59RSB0
95
GAC1/IO05RSB0
26
GEA2/IO106RSB1
61
GCB2/IO58RSB0
96
GAC0/IO04RSB0
27
GEB2/IO105RSB1
62
GCA0/IO56RSB0
97
GAB1/IO03RSB0
28
GEC2/IO104RSB1
63
GCA1/IO55RSB0
98
GAB0/IO02RSB0
29
IO102RSB1
64
GCC0/IO52RSB0
99
GAA1/IO01RSB0
30
IO100RSB1
65
GCC1/IO51RSB0
100
GAA0/IO00RSB0
31
IO99RSB1
66
VCCIB0
32
IO97RSB1
67
GND
33
IO96RSB1
68
VCC
34
IO95RSB1
69
IO47RSB0
35
IO94RSB1
70
GBC2/IO45RSB0
4- 12
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin Number
A3PN125Z
Function
Pin Number
A3PN125Z
Function
Pin Number
A3PN125Z
Function
1
GND
36
IO93RSB1
71
GBB2/IO43RSB0
2
GAA2/IO67RSB1
37
VCC
72
IO42RSB0
3
IO68RSB1
38
GND
73
GBA2/IO41RSB0
4
GAB2/IO69RSB1
39
VCCIB1
74
VMV0
5
IO132RSB1
40
IO87RSB1
75
GNDQ
6
GAC2/IO131RSB1
41
IO84RSB1
76
GBA1/IO40RSB0
7
IO130RSB1
42
IO81RSB1
77
GBA0/IO39RSB0
8
IO129RSB1
43
IO75RSB1
78
GBB1/IO38RSB0
9
GND
44
GDC2/IO72RSB1
79
GBB0/IO37RSB0
10
GFB1/IO124RSB1
45
GDB2/IO71RSB1
80
GBC1/IO36RSB0
11
GFB0/IO123RSB1
46
GDA2/IO70RSB1
81
GBC0/IO35RSB0
12
VCOMPLF
47
TCK
82
IO32RSB0
13
GFA0/IO122RSB1
48
TDI
83
IO28RSB0
14
VCCPLF
49
TMS
84
IO25RSB0
15
GFA1/IO121RSB1
50
VMV1
85
IO22RSB0
16
GFA2/IO120RSB1
51
GND
86
IO19RSB0
17
VCC
52
VPUMP
87
VCCIB0
18
VCCIB1
53
NC
88
GND
19
GEC0/IO111RSB1
54
TDO
89
VCC
20
GEB1/IO110RSB1
55
TRST
90
IO15RSB0
21
GEB0/IO109RSB1
56
VJTAG
91
IO13RSB0
22
GEA1/IO108RSB1
57
GDA1/IO65RSB0
92
IO11RSB0
23
GEA0/IO107RSB1
58
GDC0/IO62RSB0
93
IO09RSB0
24
VMV1
59
GDC1/IO61RSB0
94
IO07RSB0
25
GNDQ
60
GCC2/IO59RSB0
95
GAC1/IO05RSB0
26
GEA2/IO106RSB1
61
GCB2/IO58RSB0
96
GAC0/IO04RSB0
27
GEB2/IO105RSB1
62
GCA0/IO56RSB0
97
GAB1/IO03RSB0
28
GEC2/IO104RSB1
63
GCA1/IO55RSB0
98
GAB0/IO02RSB0
29
IO102RSB1
64
GCC0/IO52RSB0
99
GAA1/IO01RSB0
30
IO100RSB1
65
GCC1/IO51RSB0
100
GAA0/IO00RSB0
31
IO99RSB1
66
VCCIB0
32
IO97RSB1
67
GND
33
IO96RSB1
68
VCC
34
IO95RSB1
69
IO47RSB0
35
IO94RSB1
70
GBC2/IO45RSB0
R ev i si o n 1 1
4- 13
Package Pin Assignments
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin Number
A3PN250 Function
Pin Number
A3PN250 Function
Pin Number
A3PN250 Function
1
GND
37
VCC
73
GBA2/IO20RSB1
2
GAA2/IO67RSB3
38
GND
74
VMV1
3
IO66RSB3
39
VCCIB2
75
GNDQ
4
GAB2/IO65RSB3
40
IO39RSB2
76
GBA1/IO19RSB0
5
IO64RSB3
41
IO38RSB2
77
GBA0/IO18RSB0
6
GAC2/IO63RSB3
42
IO37RSB2
78
GBB1/IO17RSB0
7
IO62RSB3
43
GDC2/IO36RSB2
79
GBB0/IO16RSB0
8
IO61RSB3
44
GDB2/IO35RSB2
80
GBC1/IO15RSB0
9
GND
45
GDA2/IO34RSB2
81
GBC0/IO14RSB0
10
GFB1/IO60RSB3
46
GNDQ
82
IO13RSB0
11
GFB0/IO59RSB3
47
TCK
83
IO12RSB0
12
VCOMPLF
48
TDI
84
IO11RSB0
13
GFA0/IO57RSB3
49
TMS
85
IO10RSB0
14
VCCPLF
50
VMV2
86
IO09RSB0
15
GFA1/IO58RSB3
51
GND
87
VCCIB0
16
GFA2/IO56RSB3
52
VPUMP
88
GND
17
VCC
53
NC
89
VCC
18
VCCIB3
54
TDO
90
IO08RSB0
19
GFC2/IO55RSB3
55
TRST
91
IO07RSB0
20
GEC1/IO54RSB3
56
VJTAG
92
IO06RSB0
21
GEC0/IO53RSB3
57
GDA1/IO33RSB1
93
GAC1/IO05RSB0
22
GEA1/IO52RSB3
58
GDC0/IO32RSB1
94
GAC0/IO04RSB0
23
GEA0/IO51RSB3
59
GDC1/IO31RSB1
95
GAB1/IO03RSB0
24
VMV3
60
IO30RSB1
96
GAB0/IO02RSB0
25
GNDQ
61
GCB2/IO29RSB1
97
GAA1/IO01RSB0
26
GEA2/IO50RSB2
62
GCA1/IO27RSB1
98
GAA0/IO00RSB0
27
GEB2/IO49RSB2
63
GCA0/IO28RSB1
99
GNDQ
28
GEC2/IO48RSB2
64
GCC0/IO26RSB1
100
VMV0
29
IO47RSB2
65
GCC1/IO25RSB1
30
IO46RSB2
66
VCCIB1
31
IO45RSB2
67
GND
32
IO44RSB2
68
VCC
33
IO43RSB2
69
IO24RSB1
34
IO42RSB2
70
GBC2/IO23RSB1
35
IO41RSB2
71
GBB2/IO22RSB1
36
IO40RSB2
72
IO21RSB1
4- 14
R ev i sio n 1 1
ProASIC3 nano Flash FPGAs
100-Pin VQFP
100-Pin VQFP
100-Pin VQFP
Pin Number A3PN250Z Function
Pin Number A3PN250Z Function
Pin Number A3PN250Z Function
1
GND
37
VCC
73
GBA2/IO20RSB1
2
GAA2/IO67RSB3
38
GND
74
VMV1
3
IO66RSB3
39
VCCIB2
75
GNDQ
4
GAB2/IO65RSB3
40
IO39RSB2
76
GBA1/IO19RSB0
5
IO64RSB3
41
IO38RSB2
77
GBA0/IO18RSB0
6
GAC2/IO63RSB3
42
IO37RSB2
78
GBB1/IO17RSB0
7
IO62RSB3
43
GDC2/IO36RSB2
79
GBB0/IO16RSB0
8
IO61RSB3
44
GDB2/IO35RSB2
80
GBC1/IO15RSB0
9
GND
45
GDA2/IO34RSB2
81
GBC0/IO14RSB0
10
GFB1/IO60RSB3
46
GNDQ
82
IO13RSB0
11
GFB0/IO59RSB3
47
TCK
83
IO12RSB0
12
VCOMPLF
48
TDI
84
IO11RSB0
13
GFA0/IO57RSB3
49
TMS
85
IO10RSB0
14
VCCPLF
50
VMV2
86
IO09RSB0
15
GFA1/IO58RSB3
51
GND
87
VCCIB0
16
GFA2/IO56RSB3
52
VPUMP
88
GND
17
VCC
53
NC
89
VCC
18
VCCIB3
54
TDO
90
IO08RSB0
19
GFC2/IO55RSB3
55
TRST
91
IO07RSB0
20
GEC1/IO54RSB3
56
VJTAG
92
IO06RSB0
21
GEC0/IO53RSB3
57
GDA1/IO33RSB1
93
GAC1/IO05RSB0
22
GEA1/IO52RSB3
58
GDC0/IO32RSB1
94
GAC0/IO04RSB0
23
GEA0/IO51RSB3
59
GDC1/IO31RSB1
95
GAB1/IO03RSB0
24
VMV3
60
IO30RSB1
96
GAB0/IO02RSB0
25
GNDQ
61
GCB2/IO29RSB1
97
GAA1/IO01RSB0
26
GEA2/IO50RSB2
62
GCA1/IO27RSB1
98
GAA0/IO00RSB0
27
GEB2/IO49RSB2
63
GCA0/IO28RSB1
99
GNDQ
28
GEC2/IO48RSB2
64
GCC0/IO26RSB1
100
VMV0
29
IO47RSB2
65
GCC1/IO25RSB1
30
IO46RSB2
66
VCCIB1
31
IO45RSB2
67
GND
32
IO44RSB2
68
VCC
33
IO43RSB2
69
IO24RSB1
34
IO42RSB2
70
GBC2/IO23RSB1
35
IO41RSB2
71
GBB2/IO22RSB1
36
IO40RSB2
72
IO21RSB1
R ev i si o n 1 1
4- 15
5 – Datasheet Information
List of Changes
The following table lists critical changes that were made in each revision of the ProASIC3 nano
datasheet.
Revision
Revision 11
(January 2013)
Changes
Page
The "ProASIC3 nano Ordering Information" section has been updated to mention "Y"
as "Blank" mentioning "Device Does Not Include License to Implement IP Based on
the Cryptography Research, Inc. (CRI) Patent Portfolio" (SAR 43219).
1-III
Added a Note stating "VMV pins must be connected to the corresponding VCCI pins. See
the "VMVx I/O Supply Voltage (quiet)" section on page 3-1 for further information." to
Table 2-1 • Absolute Maximum Ratings (SAR 38326).
2-1
Added a note to Table 2-2 · Recommended Operating Conditions 1, 2 (SAR 43646):
2-2
The programming temperature range supported is Tambient = 0°C to 85°C.
The note in Table 2-73 • ProASIC3 nano CCC/PLL Specification referring the reader to
SmartGen was revised to refer instead to the online help associated with the core
(SAR 42570).
2-57
Figure 2-32 • FIFO Read and Figure 2-33 • FIFO Write are new (SAR 34847).
2-66
Libero Integrated Design Environment (IDE) was changed to Libero System-on-Chip
(SoC) throughout the document (SAR 40288).
NA
Live at Power-Up (LAPU) has been replaced with ’Instant On’.
Revision 10
The "Security" section was modified to clarify that Microsemi does not support read(September 2012) back of programmed data.
Revision 9
(March 2012)
1-1
The "In-System Programming (ISP) and Security" section and "Security" section were
revised to clarify that although no existing security measures can give an absolute
guarantee, Microsemi FPGAs implement the best security available in the industry
(SAR 34668).
I, 1-1
Notes indicating that A3P015 is not recommended for new designs have been added
(SAR 36761).
I-IV
Notes indicating that nano-Z devices are not recommended for use in new designs
have been added. The "Devices Not Recommended For New Designs" section is new
(SAR 36702).
The Y security option and Licensed DPA Logo were added to the "ProASIC3 nano
Ordering Information" section. The trademarked Licensed DPA Logo identifies that a
product is covered by a DPA counter-measures license from Cryptography Research
(SAR 34726).
III
Corrected the Commercial Temperature range to reflect a range of 0°C to 70°C
instead of –20°C to 70°C in the "ProASIC3 nano Ordering Information", "Temperature
Grade Offerings", and the "Speed Grade and Temperature Grade Matrix" sections
(SAR 37097).
III-IV
The following sentence was removed from the "Advanced Architecture" section: "In
addition, extensive on-chip programming circuitry enables rapid, single-voltage (3.3 V)
programming of IGLOO nano devices via an IEEE 1532 JTAG interface" (SAR 34688).
1-3
The "Specifying I/O States During Programming" section is new (SAR 34698).
1-7
R ev i si o n 1 1
5 -1
Datasheet Information
Revision
Revision 9
(continued)
Changes
Page
The reference to guidelines for global spines and VersaTile rows, given in the "Global
Clock Contribution—PCLOCK" section, was corrected to the "Spine Architecture"
section of the Global Resources chapter in the IProASIC3 nano FPGA Fabric
User's Guide (SAR 34736).
2-9
Figure 2-3 has been modified for the DIN waveform; the Rise and Fall time label has
been changed to tDIN (37114).
2-13
The notes regarding drive strength in the "Summary of I/O Timing Characteristics –
Default I/O Software Settings" section and "3.3 V LVCMOS Wide Range" section
tables were revised for clarification. They now state that the minimum drive strength
for the default software configuration when run in wide range is ±100 µA. The drive
strength displayed in software is supported in normal range only. For a detailed I/V
curve, refer to the IBIS models (SAR 34759).
2-17,
2-25
The AC Loading figures in the "Single-Ended I/O Characteristics" section were
updated to match tables in the "Summary of I/O Timing Characteristics – Default I/O
Software Settings" section (SAR 34888).
2-22
Added values for minimum pulse width and removed the FRMAX row from Table 2-67
through Table 2-72 in the "Global Tree Timing Characteristics" section. Use the
software to determine the FRMAX for the device you are using (SAR 36956).
2-54
through
2-56
Table 2-73 • ProASIC3 nano CCC/PLL Specification was updated. A note was added
indicating that when the CCC/PLL core is generated by Microsemi core generator
software, not all delay values of the specified delay increments are available (SAR
34823).
2-57
The port names in the SRAM "Timing Waveforms", SRAM "Timing Characteristics"
tables, Figure 2-34 • FIFO Reset, and the FIFO "Timing Characteristics" tables were
revised to ensure consistency with the software names (SAR 35743).
2-60,
2-63,
2-67,
2-69
Reference was made to a new application note, Simultaneous Read-Write Operations
in Dual-Port SRAM for Flash-Based cSoCs and FPGAs, which covers these cases in
detail (SAR 34871).
The "Pin Descriptions and Packaging" chapter has been added (SAR 34772).
3-1
July 2010
The versioning system for datasheets has been changed. Datasheets are assigned a
revision number that increments each time the datasheet is revised. The "ProASIC3
nano Device Status" table on page II indicates the status for each device in the device
family.
N/A
Revision 8
(April 2010)
References to differential inputs were removed from the datasheet, since ProASIC3
nano devices do not support differential inputs (SAR 21449).
N/A
The "ProASIC3 nano Device Status" table is new.
5- 2
II
The JTAG DC voltage was revised in Table 2-2 • Recommended Operating
Conditions 1, 2 (SAR 24052). The maximum value for VPUMP programming voltage
(operation mode) was changed from 3.45 V to 3.6 V (SAR 25220).
2-2
The highest temperature in Table 2-6 • Temperature and Voltage Derating Factors for
Timing Delays was changed to 100ºC.
2-5
The typical value for A3PN010 was revised in Table 2-7 • Quiescent Supply Current
Characteristics. The note was revised to remove the statement that values do not
include I/O static contribution.
2-6
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
Revision
Revision 8
(continued)
Changes
The following tables were updated with available information:
Table 2-8 · Summary of I/O Input Buffer Power (Per Pin) – Default I/O Software
Settings; Table 2-9 · Summary of I/O Output Buffer Power (per pin) – Default I/O
Software Settings1; Table 2-10 • Different Components Contributing to Dynamic
Power Consumption in ProASIC3 nano Devices; Table 2-14 • Summary of Maximum
and Minimum DC Input and Output Levels; Table 2-18 • Summary of I/O Timing
Characteristics—Software Default Settings (at 35 pF); Table 2-19 • Summary of I/O
Timing Characteristics—Software Default Settings (at 10 pF)
Page
2-6
through
2-18
Table 2-22 • I/O Weak Pull-Up/Pull-Down Resistances was revised to add wide range
data and correct the formulas in the table notes (SAR 21348).
2-19
The text introducing Table 2-24 • Duration of Short Circuit Event before Failure was
revised to state six months at 100° instead of three months at 110° for reliability
concerns. The row for 110° was removed from the table.
2-20
Table 2-26 • I/O Input Rise Time, Fall Time, and Related I/O Reliability was revised to
give values with Schmitt trigger disabled and enabled (SAR 24634). The temperature
for reliability was changed to 100ºC.
2-21
Table 2-33 • Minimum and Maximum DC Input and Output Levels for 3.3 V LVCMOS
Wide Range and the timing tables in the "Single-Ended I/O Characteristics" section
were updated with available information. The timing tables for 3.3 V LVCMOS wide
range are new.
2-22
The following sentence was deleted from the "2.5 V LVCMOS" section: "It uses a 5 V–
tolerant input buffer and push-pull output buffer."
2-30
Values for tDDRISUD and FDDRIMAX were updated in Table 2-62 • Input DDR
Propagation Delays. Values for FDDOMAX were added to Table 2-64 • Output DDR
Propagation Delays (SAR 23919).
2-46,
2-48
Table 2-67 • A3PN010 Global Resource through Table 2-70 • A3PN060 Global
Resource were updated with available information.
2-54
through
2-55
Table 2-73 • ProASIC3 nano CCC/PLL Specification was revised (SAR 79390).
R ev i si o n 1 1
2-57
5 -3
Datasheet Information
Revision
Changes
Revision 7 (Jan 2010)
Page
All product tables and pin tables were updated to show clearly that A3PN030 is
Product Brief Advance available only in the Z feature at this time, as A3PN030Z. The nano-Z feature
grade devices are designated with a Z at the end of the part number.
v0.7
N/A
Packaging Advance
v0.6
N/A
The "68-Pin QFN" and "100-Pin VQFP" pin tables for A3PN030 were removed.
Only the Z grade for A3PN030 is available at this time.
Revision 6 (Aug 2009) The note for A3PN030 in the "ProASIC3 nano Devices" table was revised. It
Product Brief Advance states A3PN030 is available in the Z feature grade only.
I
v0.6
Packaging
v0.5
Advance
The "68-Pin QFN" pin table for A3PN030 is new.
The "48-Pin QFN", "68-Pin QFN", and "100-Pin VQFP" pin tables for A3PN030Z
are new.
3-7
4-3, 4-7,
4-9
The "100-Pin VQFP" pin table for A3PN060Z is new.
4-11
The "100-Pin VQFP" pin table for A3PN125Z is new
4-13
The "100-Pin VQFP" pin table for A3PN250Z is new.
4-15
Revision 5 (Mar 2009) All references to speed grade –F were removed from this document.
N/A
Product Brief Advance The"I/Os with Advanced I/O Standards" section was revised to add definitions of
v0.5
hot-swap and cold-sparing.
1-7
Revision 4 (Feb 2009) The "100-Pin VQFP" pin table for A3PN030 is new.
3-10
Packaging Advance
v0.4
Revision 3 (Feb 2009) The "100-Pin QFN" section was removed.
N/A
Packaging Advance
v0.3
Revision 2 (Nov 2008) The "ProASIC3 nano Devices" table was revised to change the maximum user
Product Brief Advance I/Os for A3PN020 and A3PN030. The following table note was removed: "Six chip
(main) and three quadrant global networks are available for A3PN060 and
v0.4
above."
The QN100 package was removed for all devices.
The "Device Marking" section is new.
Revision 1 (Oct 2008)
The A3PN030 device was added to product tables and replaces A3P030 entries
Product Brief Advance that were formerly in the tables.
v0.3
The "Wide Range I/O Support" section is new.
5- 4
I
N/A
III
I to IV
1-7
The "I/Os Per Package" table was updated to add the following information to
table note 4: "For nano devices, the VQ100 package is offered in both leaded and
RoHS-compliant versions. All other packages are RoHS-compliant only."
II
The "ProASIC3 nano Products Available in the Z Feature Grade" section was
updated to remove QN100 for A3PN250.
IV
The "General Description" section was updated to give correct information about
number of gates and dual-port RAM for ProASIC3 nano devices.
1-1
R ev isio n 1 1
ProASIC3 nano Flash FPGAs
Revision
Revision 1 (cont’d)
DC and Switching
Characteristics
Advance v0.2
Changes
Page
The device architecture figures, Figure 1-3 • ProASIC3 nano Device Architecture
Overview with Two I/O Banks (A3PN060 and A3PN125) through Figure 1-4 •
ProASIC3 nano Device Architecture Overview with Four I/O Banks (A3PN250),
were revised. Figure 1-1 • ProASIC3 Device Architecture Overview with Two I/O
Banks and No RAM (A3PN010 and A3PN030) is new.
1-3
through
1-4
The "PLL and CCC" section was revised to include information about CCC-GLs in
A3PN020 and smaller devices.
1-6
Table 2-2 • Recommended Operating Conditions 1, 2 was revised to add VMV to
the VCCI row. The following table note was added: "VMV pins must be connected
to the corresponding VCCI pins."
2-2
The values in Table 2-7 • Quiescent Supply Current Characteristics were revised
for A3PN010, A3PN015, and A3PN020.
2-6
A table note, "All LVCMOS 3.3 V software macros support LVCMOS 3.3 V wide 2-16, 2-18
range, as specified in the JESD8-B specification," was added to Table 2-14 •
Summary of Maximum and Minimum DC Input and Output Levels, Table 2-18 •
Summary of I/O Timing Characteristics—Software Default Settings (at 35 pF),
and Table 2-19 • Summary of I/O Timing Characteristics—Software Default
Settings (at 10 pF).
3.3 V LVCMOS Wide Range was added to Table 2-21 • I/O Output Buffer 2-19, 2-20
Maximum Resistances 1 and Table 2-23 • I/O Short Currents IOSH/IOSL.
Packaging Advance
v0.2
The "48-Pin QFN" pin diagram was revised.
4-2
Note 2 for the "48-Pin QFN", "68-Pin QFN", and "100-Pin VQFP" pin diagrams
was added/changed to "The die attach paddle of the package is tied to ground
(GND)."
4-2, 4-5,
4-9
The "100-Pin VQFP" pin diagram was revised to move the pin IDs to the upper
left corner instead of the upper right corner.
4-9
R ev i si o n 1 1
5 -5
Datasheet Information
Datasheet Categories
Categories
In order to provide the latest information to designers, some datasheet parameters are published before
data has been fully characterized from silicon devices. The data provided for a given device, as
highlighted in the "ProASIC3 nano Device Status" table on page II, is designated as either "Product
Brief," "Advance," "Preliminary," or "Production." The definitions of these categories are as follows:
Product Brief
The product brief is a summarized version of a datasheet (advance or production) and contains general
product information. This document gives an overview of specific device and family information.
Advance
This version contains initial estimated information based on simulation, other products, devices, or speed
grades. This information can be used as estimates, but not for production. This label only applies to the
DC and Switching Characteristics chapter of the datasheet and will only be used when the data has not
been fully characterized.
Preliminary
The datasheet contains information based on simulation and/or initial characterization. The information is
believed to be correct, but changes are possible.
Production
This version contains information that is considered to be final.
Export Administration Regulations (EAR)
The products described in this document are subject to the Export Administration Regulations (EAR).
They could require an approved export license prior to export from the United States. An export includes
release of product or disclosure of technology to a foreign national inside or outside the United States.
Safety Critical, Life Support, and High-Reliability Applications
Policy
The products described in this advance status document may not have completed the Microsemi
qualification process. Products may be amended or enhanced during the product introduction and
qualification process, resulting in changes in device functionality or performance. It is the responsibility of
each customer to ensure the fitness of any product (but especially a new product) for a particular
purpose, including appropriateness for safety-critical, life-support, and other high-reliability applications.
Consult the Microsemi SoC Products Group Terms and Conditions for specific liability exclusions relating
to life-support applications. A reliability report covering all of the SoC Products Group’s products is
available at http://www.microsemi.com/soc/documents/ORT_Report.pdf. Microsemi also offers a variety
of enhanced qualification and lot acceptance screening procedures. Contact your local sales office for
additional reliability information.
5- 6
R ev isio n 1 1
Microsemi Corporation (NASDAQ: MSCC) offers a comprehensive portfolio of semiconductor
solutions for: aerospace, defense and security; enterprise and communications; and industrial
and alternative energy markets. Products include high-performance, high-reliability analog and
RF devices, mixed signal and RF integrated circuits, customizable SoCs, FPGAs, and
complete subsystems. Microsemi is headquartered in Aliso Viejo, Calif. Learn more at
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