ATMEL AT91FR4042 At91 arm thumb microcontroller Datasheet

Features
• Incorporates the ARM7TDMI™ ARM® Thumb® Processor Core
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– High-performance 32-bit RISC Architecture
– High-density 16-bit Instruction Set
– Leader in MIPS/Watt
– Embedded ICE (In-circuit Emulation)
256K Bytes of On-chip SRAM (2 Mbits)
– 32-bit Data Bus, Single-clock Cycle Access
256K Words 16-bit Flash Memory (4 Mbits)
– Single Voltage Read/Write, 90 ns Access Time
– Sector Erase Architecture
– Fast Word Program Time of 30 µs (Typical); Fast Sector Erase Time of 10 sec. (Max)
– Low-power Operation: 25 mA Active (Read Current, f = 5 MHz, IOUT = 0 mA Typical),
50 µA Standby (Standby Current CMOS: NCSF = VDDIO - 0.3V to VDDIO Maximum)
– Data Polling, Toggle Bit and Ready/Busy End of Program Cycle Detection
– Reset Input for Device Initialization
– Factory-programmed AT91 Flash Uploader Software
Fully Programmable External Bus Interface (EBI)
– Up to 8 Chip Selects, Maximum External Address Space of 64M Bytes
– Software Programmable 8/16-bit External Data Bus
8-level Priority, Individually Maskable, Vectored Interrupt Controller
– 4 External Interrupts, Including a High-priority Low-latency Interrupt Request
32 Programmable I/O Lines
3-channel 16-bit Timer/Counter
– 3 External Clock Inputs, 2 Multi-purpose I/O Pins per Channel
2 USARTs
– 2 Dedicated Peripheral Data Controller (PDC) Channels per USART
Programmable Watchdog Timer
Advanced Power-saving Features
– CPU and Peripherals Can be De-activated Individually
Fully Static Operation:
– 0 Hz to 70 MHz Internal Frequency Range at VDDCORE = 1.65V, 85°C
2.7V to 3.6V I/O and Flash Operating Range, 1.65V to 1.95V Core Operating Range
-40°C to 85°C Temperature Range
Available in a 121-ball 10 x 10 x 1.2 mm BGA Package with 0.8 mm Ball Pitch
AT91 ARM®
Thumb®
Microcontrollers
AT91FR4042
Preliminary
Description
The AT91FR4042 is a member of the Atmel AT91 16/32-bit Microcontroller family,
which is based on the ARM7TDMI processor core. The processor has a high-performance 32-bit RISC architecture with a high-density 16-bit instruction set and very low
power consumption.
The AT91FR4042 ARM microcontroller features 2 Mbits of on-chip SRAM and 4 Mbits
of Flash memory in a single compact 121-ball BGA package. Its high level of integration and very small footprint make the device ideal for space-constrained applications.
The high-speed on-chip SRAM enables a performance of up to 63 MIPs and significant power reduction over an external SRAM inplementation.
The Flash memory may be programmed via the JTAG/ICE interface or the factory-programmed Flash Uploader using a single device supply, making the AT91FR4042
suitable for in-system programmable applications.
Rev. 2648B–ATARM–12/02
Preliminary
1
Preliminary
Pin Configuration
Figure 1. AT91FR4042 Pinout for 121-ball BGA Package (Top View)
A1 Corner
1
2
3
4
5
6
7
8
9
10
11
A
P21/TXD1
NTRI
P19
P16
P15
RXD0
GND
P11
P8
VDDCORE
IRQ2
TIOB2
P6
TCLK2
GND
P2
TIOB0
P22
RXD1
P20
SCK1
P18
P17
P12
FIQ
P10
IRQ1
VDDIO
P7
TIOA2
P4
TIOA1
GND
P1
TIOA0
VDDIO
GND
NUB
NWR1
P14
TXD0
NBUSY
P9
IRQ0
P5
TIOB1
P3
TCLK1
A16
D15
P0
TCLK0
P23
MCKI
NRST
P13
SCK0
VPP
NRSTF
A14
A15
D12
D14
VDDIO
P24
BMS
P25
NWDOVF
MCK0
A3
A8
D11
D10
D13
NC
NC
D3
TCK
NOE
NRD
B
C
D
E
F
GND
TMS
TDO
NWE
NWR0
GND
D9
A11
D7
D8
NC
NC
G
A2
TDI
NCS0
D2
D5
D4
D6
NC
NC
VDDIO
P30/A22
CS5
GND
NC
H
P26
VDDCORE VDDIO
NCS2
NC
NCSF
NC
D0
D1
P31/A23
CS4
J
NWAIT
GND
P27
NCS3
A5
NC
VDDIO
GND
GND
A19
NCS1
NLB
A0
GND
A7
VDDIO
A10
A13
GND
A17
GND
A1
A4
A6
VDDIO
A9
A12
GND
VDDIO
K
P29/A21
VDDCORE
CS6
L
2
A18
P28/A20
CS7
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
Pin Description
Table 1. AT91FR4042 Pin Description
Type
Active
Level
Output
All
I/O
–
External Chip Select
Output
Low
Used to select external devices
CS4 - CS7
External Chip Select
Output
High
A23 - A20 after reset
NWR0
Lower Byte 0 Write Signal
Output
Low
Used in Byte Write option
NWR1
Upper Byte 1 Write Signal
Output
Low
Used in Byte Write option
NRD
Read Signal
Output
Low
Used in Byte Write option
NWE
Write Enable
Output
Low
Used in Byte Select option
NOE
Output Enable
Output
Low
Used in Byte Select option
NUB
Upper Byte Select
Output
Low
Used in Byte Select option
NLB
Lower Byte Select
Output
Low
Used in Byte Select option
NWAIT
Wait Input
Input
Low
BMS
Boot Mode Select
Input
–
Sampled during reset; must be driven low
during reset for Flash to be used as boot
memory
FIQ
Fast Interrupt Request
Input
–
PIO-controlled after reset
IRQ0 - IRQ2
External Interrupt Request
Input
–
PIO-controlled after reset
TCLK0 - TCLK2
Timer External Clock
Input
–
PIO-controlled after reset
TIOA0 - TIOA2
Multi-purpose Timer I/O Pin A
I/O
–
PIO-controlled after reset
TIOB0 - TIOB2
Multi-purpose Timer I/O Pin B
I/O
–
PIO-controlled after reset
SCK0 - SCK1
External Serial Clock
I/O
–
PIO-controlled after reset
TXD0 - TXD1
Transmit Data Output
Output
–
PIO-controlled after reset
RXD0 - RXD1
Receive Data Input
Input
–
PIO-controlled after reset
PIO
P0 - P31
Parallel IO Line
I/O
–
WD
NWDOVF
Watchdog Overflow
Output
Low
MCKI
Master Clock Input
Input
–
MCKO
Master Clock Output
Output
–
NRST
Hardware Reset Input
Input
Low
Schmidt trigger
NTRI
Tri-state Mode Select
Input
Low
Sampled during reset
TMS
Test Mode Select
Input
–
Schmidt trigger, internal pull-up
TDI
Test Data Input
Input
–
Schmidt trigger, internal pull-up
TDO
Test Data Output
Output
–
TCK
Test Clock
Input
–
Module
EBI
Name
Function
A0 - A23
Address Bus
D0 - D15
Data Bus
NCS0 - NCS3
Comments
Valid after reset
AIC
Timer
USART
Open drain
Schmidt trigger
Clock
Reset
ICE
Schmidt trigger, internal pull-up
Preliminary
2648B–ATARM–12/02
3
Preliminary
Table 1. AT91FR4042 Pin Description (Continued)
Module
Flash
Memory
Power
4
Name
Function
Type
Active
Level
NCSF
Flash Memory Select
Input
Low
Enables Flash Memory when pulled low
NBUSY
Flash Memory Busy Output
Output
Low
Flash RDY/BUSY signal; open-drain
NRSTF
Flash Memory Reset Input
Input
Low
Resets Flash to standard operating mode
VDDIO
Power
Power
–
VDDCORE
Power
Power
–
GND
Ground
Ground
–
VPP
Power
Power
–
Comments
All VDDIO, VDDCORE and all GND pins
MUST be connected to their respective
supplies by the shortest route
See AT49BV/LV4096A
4-megabit (256K x 16/512K x 8) Single 2.7
Volt Flash Memory Datasheet
AT91FR4042
2648B–ATARM–12/02
Embedded
ICE
ARM7TDMI Core
D0 - D15
ASB
VDDCORE
VDDIO
GND
EBI: External Bus Interface
SRAM
256K Bytes
NRST
Reset
MCKI
ASB
Controller
Clock
P25/MCKO
D0-D15
A19
A1- A18
A0/NLB
A1 - A18
A0/NLB
NWR1/NUB
NWAIT
NCS0
NCS1
NRD/NOE
NWR0/NWE
P26/NCS2
P27/NCS3
P28/A20/CS7
P29/A21/CS6
P30/A22/CS5
P31/A23/CS4
AMBA Bridge
P12/FIQ
P9/IRQ0
P10/IRQ1
P11/IRQ2
EBI User
Interface
AIC: Advanced
Interrupt Controller
D0 - D15
APB
P13/SCK0
P14/TXD0
P15/RXD0
P20/SCK1
P21/TXD1/NTRI
P22/RXD1
2 PDC
Channels
MCU
AT91R40008
USART1
2 PDC
Channels
PS: Power Saving
TC: Timer
Counter
TC0
Chip ID
TC1
NWDOVF
WD: Watchdog Timer
TC2
A0 - A17
OE
FLASH MEMORY
P
I
O
AT49BV4096A
WE
GND
VPP
VCC
VCCQ
BYTE
RESET
RDY/BUSY
CE
GND
VPP
VDDIO
VDDIO
VDDIO
NRSTF
NBUSY
NCSF
P0/TCLK0
P3/TCLK1
P6/TCLK2
P1/TIOA0
P2/TIOB0
P4/TIOA1
P5/TIOB1
P7/TIOA2
P8/TIOB2
PIO: Parallel I/O Controller
5
AT91FR4042
Preliminary
P16
P17
P18
P19
P23
P24/BMS
USART0
P
I
O
Block Diagram
Figure 2. AT91FR4042
2648B–ATARM–12/02
TMS
TDO
TDI
TCK
Preliminary
Architectural
Overview
The AT91FR4042 integrates Atmel’s AT91R40008 ARM Thumb processor and an
AT49BV4096A 4-Mbit Flash memory die in a single compact 121-ball BGA package.
The address, data and control signals, except the Flash memory enable, are internally
interconnected.
The AT91R40008 architecture consists of two main buses, the Advanced System Bus
(ASB) and the Advanced Peripheral Bus (APB). Designed for maximum performance
and controlled by the memory controller, the ASB interfaces the ARM7TDMI processor
with the on-chip 32-bit SRAM memory, the External Bus Interface (EBI) connected to
the encapsulated Flash and the AMBA™ Bridge. The AMBA Bridge drives the APB,
which is designed for accesses to on-chip peripherals and optimized for low power
consumption.
The AT91FR4042 implements the ICE port of the ARM7TDMI processor on dedicated
pins, offering a complete, low-cost and easy-to-use debug solution for target debugging.
Memories
The AT91FR4042 embeds 256K bytes of internal SRAM. The internal memory is
directly connected to the 32-bit data bus and is single-cycle accessible. This provides
maximum performance of 63 MIPS at 70 MHz by using the ARM instruction set of the
processor, minimizing system power consumption and improving on the performance of
separate memory solutions.
The AT91FR4042 features an External Bus Interface (EBI), which enables connection of
external memories and application-specific peripherals. The EBI supports 8- or 16-bit
devices and can use two 8-bit devices to emulate a single 16-bit device. The EBI implements the early read protocol, enabling faster memory accesses than standard memory
interfaces.
The AT91FR4042 encapsulates a Flash memory organized as 256K 16-bit words,
accessed via the EBI. A 16-bit Thumb instruction can be loaded from Flash memory in a
single access. Separate MCU and Flash memory reset inputs (NRST and NRSTF) are
provided for maximum flexibility. The user is thus free to tailor the reset operation to the
application.
The AT91FR4042 integrates resident boot software called AT91 Flash Uploader software in the encapsulated Flash. The AT91 Flash Uploader software is able to upload
program application software into its Flash memory.
Peripherals
The AT91FR4042 integrates several peripherals, which are classified as system or user
peripherals.
All on-chip peripherals are 32-bit accessible by the AMBA Bridge, and can be programmed with a minimum number of instructions. The peripheral register set is
composed of control, mode, data, status and enable/disable/status registers.
An on-chip Peripheral Data Controller (PDC) transfers data between the on-chip
USARTs and on- and off-chip memory address space without processor intervention.
Most importantly, the PDC removes the processor interrupt handling overhead, making
it possible to transfer up to 64K contiguous bytes without reprogramming the start
address, thus increasing the performance of the microcontroller, and reducing the power
consumption.
System Peripherals
6
The External Bus Interface (EBI) controls the external memory or peripheral devices via
an 8- or 16-bit databus and is programmed through the APB. Each chip select line has
its own programming register.
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
The Power-saving (PS) module implements the Idle Mode (ARM7TDMI core clock
stopped until the next interrupt) and enables the user to adapt the power consumption of
the microcontroller to application requirements (independent peripheral clock control).
The Advanced Interrupt Controller (AIC) controls the internal interrupt sources from the
internal peripherals and the four external interrupt lines (including the FIQ) to provide an
interrupt and/or fast interrupt request to the ARM7TDMI. It integrates an 8-level priority
controller, and, using the Auto-vectoring feature, reduces the interrupt latency time.
The Parallel Input/Output Controller (PIO) controls up to 32 I/O lines. It enables the user
to select specific pins for on-chip peripheral input/output functions, and general-purpose
input/output signal pins. The PIO controller can be programmed to detect an interrupt on
a signal change from each line.
The Watchdog (WD) can be used to prevent system lock-up if the software becomes
trapped in a deadlock.
The Special Function (SF) module integrates the Chip ID, the Reset Status and the Protect registers.
User Peripherals
Two USARTs, independently configurable, enable communication at a high baud rate in
synchronous or asynchronous mode. The format includes start, stop and parity bits and
up to 8 data bits. Each USART also features a Timeout and a Time Guard register, facilitating the use of the two dedicated Peripheral Data Controller (PDC) channels.
The 3-channel, 16-bit Timer Counter (TC) is highly programmable and supports capture
or waveform modes. Each TC channel can be programmed to measure or generate different kinds of waves, and can detect and control two input/output signals. The TC has
also 3 external clock signals.
Preliminary
2648B–ATARM–12/02
7
Preliminary
Associated Documentation
Table 2. Associated Documentation
Product
AT91FR4042
Information
Document Title
Internal architecture of processor
ARM/Thumb instruction sets
Embedded in-circuit emulator
ARM7TDMI (Thumb) Datasheet
External memory interface mapping
Peripheral operations
Peripheral user interfaces
AT91x40 Series Datasheet
DC characteristics
Power consumption
Thermal and reliability
considerations
AC characteristics
MCU
AT91R40008 Electrical Characteristics Datasheet
Flash
Memory
AT49BV/LV4096A 4 megabit (256K x 16/512K x 8) Single
2.7 Volt Flash Memory Datasheet
Product overview
Ordering information
Packaging information
Soldering profile
Detailed description of Flash memory
8
AT91FR4042 Datasheet (this document)
AT49BV/LV4096A 4 megabit (256K x 16/512K x 8) Single
2.7 Volt Flash Memory Datasheet
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
Product Overview
Power Supply
The AT91FR4042 device has two types of power supply pins:
•
VDDCORE pins that power the chip core (i.e., the AT91R40008 with its embedded
SRAM and peripherals)
•
VDDIO pins that power the AT91R40008 I/O lines and the Flash memory
An independent I/O supply allows a flexible adaptation to external component signal
levels.
Input/Output
Considerations
The AT91FR4042 I/O pads accept voltage levels up to the VDDIO power supply limit.
After the reset, the microcontroller peripheral I/Os are initialized as inputs to provide the
user with maximum flexibility. It is recommended that in any application phase, the
inputs to the microcontroller be held at valid logic levels to minimize the power
consumption.
Master Clock
The AT91FR4042 has a fully static design and works on the Master Clock (MCK), provided on the MCKI pin from an external source.
The Master Clock is also provided as an output of the device on the pin MCKO, which is
multiplexed with a general purpose I/O line. While NRST is active, and after the reset,
the MCKO is valid and outputs an image of the MCK signal. The PIO Controller must be
programmed to use this pin as standard I/O line.
Reset
Reset restores the default states of the user interface registers (defined in the user interface of each peripheral), and forces the ARM7TDMI to perform the next instruction fetch
from address zero. Except for the program counter the ARM7TDMI registers do not
have defined reset states.
NRST Pin
NRST is active low-level input. It is asserted asynchronously, but exit from reset is synchronized internally to the MCK. The signal presented on MCKI must be active within
the specification for a minimum of 10 clock cycles up to the rising edge of NRST to
ensure correct operation. The first processor fetch occurs 80 clock cycles after the rising
edge of NRST.
Watchdog Reset
The watchdog can be programmed to generate an internal reset. In this case, the reset
has the same effect as the NRST pin assertion, but the pins BMS and NTRI are not
sampled. Boot Mode and Tri-state Mode are not updated. If the NRST pin is asserted
and the watchdog triggers the internal reset, the NRST pin has priority.
Emulation Functions
Tri-state Mode
The AT91FR4042 microcontroller provides a tri-state mode, which is used for debug
purposes. This enables the connection of an emulator probe to an application board
without having to desolder the device from the target board. In tri-state mode, all the output pin drivers of the AT91R40008 microcontroller are disabled.
In tri-state mode, direct access to the Flash via external pins is provided. This enables
production Flash programming using classical Flash programmers prior to board
mounting.
Preliminary
2648B–ATARM–12/02
9
Preliminary
To enter tri-state mode, the NTRI pin must be held low during the last 10 clock cycles
before the rising edge of NRST. For normal operation, the NTRI pin must be held high
during reset by a resistor of up to 400 kΩ.
NTRI is multiplexed with I/O line P21 and USART1 serial data transmit line TXD1.
JTAG/ICE Debug
ARM-standard embedded In-circuit Emulation is supported via the JTAG/ICE port. The
pins TDI, TDO, TCK and TMS are dedicated to this debug function and can be connected to a host computer via the external ICE interface. In ICE Debug Mode, the
ARM7TDMI core responds with a non-JTAG chip ID that identifies the microcontroller.
This is not fully IEEE1149.1 compliant.
Memory Controller
The ARM7TDMI processor address space is 4G bytes. The memory controller decodes
the internal 32-bit address bus and defines three address spaces:
•
Internal memories in the four lowest megabytes
•
Middle space reserved for the external devices (memory or peripherals) controlled
by the EBI
•
Internal peripherals in the four highest megabytes
In any of these address spaces, the ARM7TDMI operates in little-endian mode only.
Internal Memories
The AT91FR4042 microcontroller integrates 256K bytes of internal SRAM. It is 32 bits
wide and single-clock cycle accessible. Byte (8-bit), half-word (16-bit) and word (32-bit)
accesses are supported and are executed within one cycle. Fetching either Thumb or
ARM instructions is supported, and internal memory can store two times as many
Thumb instructions as ARM instructions.
The SRAM is mapped at address 0x0 (after the Remap command), allowing
ARM7TDMI exception vectors between 0x0 and 0x20 to be modified by the software.
Placing the SRAM on-chip and using the 32-bit data bus bandwidth maximizes the
microcontroller performance and minimizes system power consumption. The 32-bit bus
increases the effectiveness of the use of the ARM instruction set and the processing of
data that is wider than 16 bits, thus making optimal use of the ARM7TDMI advanced
performance.
Being able to dynamically update application software in the 256-Kbyte SRAM adds an
extra dimension to the AT91FR4042.
The AT91FR4042 also integrates a 4-Mbit Flash memory that is accessed via the External Bus Interface. All data, address and control lines, except for the Chip Select signal,
are connected within the device.
Boot Mode Select
The ARM reset vector is at address 0x0. After the NRST line is released, the
ARM7TDMI executes the instruction stored at this address. This means that this
address must be mapped in nonvolatile memory after the reset. The input level on the
BMS pin during the last 10 clock cycles before the rising edge of the NRST selects the
type of boot memory (see Table 1).
If the embedded Flash memory is to be used as boot memory, the BMS input must be
pulled down externally and NCS0 must be connected to NCSF externally.
10
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
The pin BMS is multiplexed with the I/O line P24 that can be programmed after reset like
any standard PIO line.
Table 3. Boot Mode Select
BMS
Boot Memory
1
External 8-bit memory on NCS0
0
External 16-bit memory on NCS0
Remap Command
The ARM vectors (Reset, Abort, Data Abort, Prefetch Abort, Undefined Instruction,
Interrupt, Fast Interrupt) are mapped from address 0x0 to address 0x20. In order to
allow these vectors to be redefined dynamically by the software, the AT91FR4042 uses
a remap command that enables switching between the boot memory and the internal
primary SRAM bank addresses. The remap command is accessible through the EBI
User Interface by writing one in RCB of EBI_RCR (Remap Control Register). Performing
a remap command is mandatory if access to the other external devices (connected to
chip selects 1 to 7) is required. The remap operation can only be changed back by an
internal reset or an NRST assertion.
Abort Control
The abort signal providing a Data Abort or a Prefetch Abort exception to the ARM7TDMI
is asserted when accessing an undefined address in the EBI address space.
No abort is generated when reading the internal memory or by accessing the internal
peripherals, whether the address is defined or not.
External Bus Interface
The External Bus Interface handles the accesses between addresses 0x0040 0000 and
0xFFC0 0000. It generates the signals that control access to the external devices, and
can be configured from eight 1-Mbyte banks up to four 16-Mbyte banks. It supports byte,
half-word and word aligned accesses.
For each of these banks, the user can program:
•
Number of wait states
•
Number of data float times (wait time after the access is finished to prevent any bus
contention in case the device is too long in releasing the bus)
•
Data bus width (8-bit or 16-bit)
•
With a 16-bit wide data bus, the user can program the EBI to control one 16-bit
device (Byte Access Select Mode) or two 8-bit devices in parallel that emulate a 16bit memory (Byte Write Access Mode).
The External Bus Interface features also the Early Read Protocol, configurable for all the
devices, that significantly reduces access time requirements on an external device in
the case of single-clock cycle access.
In the AT91FR4042, the External Bus Interface connects internally to the Flash memory.
Flash Memory
The 4-Mbit Flash memory is organized as 262144 words of 16 bits each. The Flash
memory is addressed as 16-bit words via the EBI. It uses address lines A1 - A18.
The address, data and control signals, except the Flash memory enable, are internally
interconnected. The user should connect the Flash memory enable (NCSF) to one of
the active-low chip selects on the EBI; NCS0 must be used if the Flash memory is to be
the boot memory. In addition, if the Flash memory is to be used as boot memory, the
BMS input must be pulled down externally in order for the processor to perform correct
16-bit fetches after reset.
Preliminary
2648B–ATARM–12/02
11
Preliminary
During boot, the EBI must be configured with correct number of standard wait states. As
an example, five standard wait states are required when the microcontroller is running at
66 MHz.
The user must ensure that all VDDIO, VDDCORE and all GND pins are connected to
their respective supplies by the shortest route. The Flash memory powers-on in read
mode. Command sequences are used to place the device in other operating modes,
such as program and erase.
A separate Flash memory reset input pin (NRSTF) is provided for maximum flexibility,
enabling the reset operation to adapt to the application. When this input is at a logic high
level, the memory is in its standard operating mode; a low level on this input halts the
current memory operation and puts its outputs in a high impedance state.
The Flash memory features data polling to detect the end of a program cycle. While a
program cycle is in progress, an attempted read of the last word written will return the
complement of the written data on I/O7. An open-drain NBUSY output pin provides
another method of detecting the end of a program or erase cycle. This pin is pulled low
while program and erase cycles are in progress and is released at the completion of the
cycle. A toggle bit feature provides a third means of detecting the end of a program or
erase cycle.
The Flash memory is divided into 4 sectors for erase operations.
The device has the capability to protect data stored in the 8K words boot block sector.
Once the data protection for this sector is enabled, the data in the sector cannot be
changed while input levels lie between ground and VDDIO. The address range of the
boot block is 00000h to 01FFFh
The user can override the boot block programing lockout by applying a 12V input signal
to the RESET pin while performing a chip erase, sector erase or word programing
operation.
A 4-byte command sequence (Enter Single Pulse Program Mode) allows the device to
be written to directly, using single pulses on the write control lines. This mode (Singlepulse Programming) is exited by powering down the device or by pulsing the NRSTF pin
low for a minimum of 50 ns and then bringing it back to VDDIO.
The following hardware features protect against inadvertent programming of the Flash
memory:
•
VDDIO Sense – if VDDIO is below 1.8V (typical), the program function is inhibited.
•
VDDIO Power-on Delay – once VDDIO has reached the VDDIO sense level, the
device will automatically time out 10 ms (typically) before programming.
•
Program Inhibit – holding any one of OE low, CE high or WE high inhibits program
cycles.
•
Noise Filter – pulses of less than 15 ns (typical) on the WE or CE inputs will not
initiate a program cycle.
See the AT49BV4096A 4-megabit (256K x 16/512K x 8) Single 2.7 volt Flash Memory
Datasheet for further details on Flash operation and electrical characteristics.
12
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
AT91 Flash Uploader
Software
All Flash-based AT91 devices are delivered with a pre-programmed software called the
AT91 Flash Uploader, which resides in the first sector of the embedded Flash. The
Flash Uploader allows programming to the embedded flash through a serial port. Either
of the on-chip USARTs can be used by the Flash Uploader.
Figure 3. Flash Uploader
Target System
AT91FR4042
AT49BV4096A
Flash Memory
NCSF
AT91R40008
NCS0
USART0
Programming System
RXD0
Serial
Port
RS232
Driver
USART1
Flash Uploader Operations
RXD1
The Flash Uploader requires the encapsulated Flash to be used as the AT91FR4042
boot memory and a valid clock to be applied to MCKI. After reset, the Flash Uploader
immediately recopies itself into the internal SRAM and jumps to it. The following operation requires this memory resource only. External accesses are performed only to
program the encapsulated Flash.
When starting, PIO input change interrupts are initialized on the RXD lines of both
USARTs. When an interrupt occurs, a Timer Counter channel is started. When the next
input change is detected on the RXD line, the Timer Counter channel is stopped. This is
how the first character length is measured and the USART can be initiated by taking into
account the ratio between the device master clock speed and the actual communication
baud rate speed.
The Programming System, then, can send commands and data following a proprietary
protocol for the Flash device to be programmed. It is up to the Programming System to
erase and program the first sector of the Flash as the last step of the operation, in order
to reduce, to a minimum, the risk that the Flash Uploader is erased and the power supply shuts down.
Note that in the event that the Flash Uploader is erased from the first sector while the
new final application is not yet programmed, and while the target system power supply
is switched off, it leads to a non-recoverable error and the AT91FR4042 cannot be reprogrammed by using the Flash Uploader.
Preliminary
2648B–ATARM–12/02
13
Preliminary
Programming System
Atmel provides a free Host Loader that runs on an IBM® compatible PC under Windows®95 or Windows®98 operating system. It can be downloaded from the Atmel Web
site and requires only a serial cable to connect the Host to the Target.
Communications can be selected on either COM1 or COM2 and the serial link speed is
limited to 115200 bauds. Because the serial link is the bottleneck in this configuration,
the Flash programming lasts 110 seconds per Mbyte.
Reduced programming time can be achieved by using a faster programming system. An
AT91 Evaluation Board is capable of running a serial link at up to 500 Kbits/sec and can
match the fastest programming allowed by the Flash, for example, about 40 seconds
per Mbyte when the word programming becomes the bottleneck.
Peripherals
The AT91FR4042 peripherals are connected to the 32-bit wide Advanced Peripheral
Bus.
Peripheral registers are only word accessible. Byte and half-word accesses are not supported. If a byte or a half-word access is attempted, the memory controller automatically
masks the lowest address bits and generates a word access.
Each peripheral has a 16-Kbyte address space allocated (the AIC only has a 4-Kbyte
address space).
Peripheral Registers
The following registers are common to all peripherals:
•
Control Register – write only register that triggers a command when a one is written
to the corresponding position at the appropriate address. Writing a zero has no
effect.
•
Mode Register – read/write register that defines the configuration of the peripheral.
Usually has a value of 0x0 after a reset.
•
Data Registers – read and/or write register that enables the exchange of data
between the processor and the peripheral.
•
Status Register – read only register that returns the status of the peripheral.
•
Enable/Disable/Status Registers are shadow command registers. Writing a one in
the Enable Register sets the corresponding bit in the Status Register. Writing a one
in the Disable Register resets the corresponding bit and the result can be read in the
Status Register. Writing a bit to zero has no effect. This register access method
maximizes the efficiency of bit manipulation, and enables modification of a register
with a single non-interruptible instruction, replacing the costly read-modify-write
operation.
Unused bits in the peripheral registers must be written at 0 for upward compatibility.
These bits read 0.
Peripheral Interrupt Control
The Interrupt Control of each peripheral is controlled from the status register using the
interrupt mask. The status register bits are ANDed to their corresponding interrupt mask
bits and the result is then ORed to generate the Interrupt Source signal to the Advanced
Interrupt Controller.
The interrupt mask is read in the Interrupt Mask Register and is modified with the Interrupt Enable Register and the Interrupt Disable Register. The enable/disable/status (or
mask) makes it possible to enable or disable peripheral interrupt sources with a noninterruptible single instruction. This eliminates the need for interrupt masking at the AIC
or Core level in real-time and multi-tasking systems.
14
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
Peripheral Data Controller
The AT91FR4042 has a 4-channel PDC dedicated to the two on-chip USARTs. One
PDC channel is dedicated to the receiver and one to the transmitter of each USART.
The user interface of a PDC channel is integrated in the memory space of each USART.
It contains a 32-bit Address Pointer Register (RPR or TPR) and a 16-bit Transfer
Counter Register (RCR or TCR). When the programmed number of transfers are performed, a status bit indicating the end of transfer is set in the USART Status Register
and an interrupt can be generated.
Preliminary
2648B–ATARM–12/02
15
Preliminary
System Peripherals
PS: Power-saving
The power-saving feature optimizes power consumption, enabling the software to stop
the ARM7TDMI clock (idle mode), restarting it when the module receives an interrupt (or
reset). It also enables on-chip peripheral clocks to be enabled and disabled individually,
matching power consumption and application needs.
AIC: Advanced Interrupt
Controller
The Advanced Interrupt Controller has an 8-level priority, individually maskable, vectored interrupt controller, and drives the NIRQ and NFIQ pins of the ARM7TDMI from:
•
The external fast interrupt line (FIQ)
•
The three external interrupt request lines (IRQ0 - IRQ2)
•
The interrupt signals from the on-chip peripherals
The AIC is extensively programmable offering maximum flexibility, and its vectoring features reduce the real-time overhead in handling interrupts.
The AIC also features a spurious vector detection feature, which reduces spurious interrupt handling to a minimum, and a protect mode that facilitates the debug capabilities.
PIO: Parallel I/O Controller
The AT91FR4042 has 32 programmable I/O lines. Six pins are dedicated as generalpurpose I/O pins. Other I/O lines are multiplexed with an external signal of a peripheral
to optimize the use of available package pins. The PIO controller enables generation of
an interrupt on input change and insertion of a simple input glitch filter on any of the PIO
pins.
WD: Watchdog
The Watchdog is built around a 16-bit counter and is used to prevent system lock-up if
the software becomes trapped in a deadlock. It can generate an internal reset or interrupt, or assert an active level on the dedicated pin NWDOVF. All programming registers
are password-protected to prevent unintentional programming.
SF: Special Function
The AT91FR4042 provides registers that implement the following special functions.
16
•
Chip Identification
•
RESET Status
•
Protect Mode
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
User Peripherals
USART: Universal
Synchronous/
Asynchronous Receiver
Transmitter
The AT91FR4042 provides two identical, full-duplex, universal synchronous/asynchronous receiver/transmitters.
Each USART has its own baud rate generator, and two dedicated Peripheral Data Controller channels. The data format includes a start bit, up to 8 data bits, an optional
programmable parity bit and up to 2 stop bits.
The USART also features a Receiver Timeout register, facilitating variable length frame
support when it is working with the PDC, and a Time-guard register, used when interfacing with slow remote equipment.
TC: Timer Counter
The AT91FR4042 features a Timer Counter block that includes three identical 16-bit
timer counter channels. Each channel can be independently programmed to perform a
wide range of functions including frequency measurement, event counting, interval measurement, pulse generation, delay timing and pulse width modulation.
The Timer Counter can be used in Capture or Waveform mode, and all three counter
channels can be started simultaneously and chained together.
Preliminary
2648B–ATARM–12/02
17
Preliminary
Ordering Information
Table 4. Ordering Information
18
Ordering Code
Package
AT91FR4042-CI
BGA 121
Temperature
Operating Range
Industrial
(-40°C to 85°C)
AT91FR4042
2648B–ATARM–12/02
AT91FR4042
Packaging Information
Figure 4. AT91FR4042 Package
Table 5. Thermal Resistance Data
Symbol
Parameter
Condition
θJA
Junction-toambient thermal
resistance
Still Air
θJC
Junction-to-case
thermal resistance
Package
Typ
121-BGA
TBD
121-BGA
TBD
Units
°C/W
Table 6. Device and 121-ball BGA Package Maximum Weight
TBD
mg
Preliminary
2648B–ATARM–12/02
19
Preliminary
Soldering Profile
Table 7 gives the recommended soldering profile from J-STD-20.
Table 7. Soldering Profile
Convection or
IR/Convection
VPR
Average Ramp-up Rate (183°C to Peak)
3°C/sec. max.
10°C/sec.
Preheat Temperature 125°C ±25°C
120 sec. max
Temperature Maintained Above 183°C
60 sec. to 150 sec.
Time within 5°C of Actual Peak
Temperature
10 sec. to 20 sec.
60 sec.
Peak Temperature Range
220 +5/-0°C or
235 +5/-0°C
215 to 219°C or
235 +5/-0°C
Ramp-down Rate
6°C/sec.
10°C/sec.
Time 25°C to Peak Temperature
6 min. max
Small packages may be subject to higher temperatures if they are reflowed in boards
with larger components. In this case, small packages may have to withstand temperatures of up to 235°C, not 220°C (IR reflow).
Recommended package reflow conditions depend on package thickness and volume.
See Table 8.
Table 8. Recommended Package Reflow Conditions (1, 2, 3)
Parameter
Temperature
Convection
220 +5/-0°C
VPR
215 to 219°C
IR/Convection
220 +5/-0°C
Notes:
1. The packages are qualified by Atmel by using IR reflow conditions, not convection or
VPR.
2. By default, the package level 1 is qualified at 220°C (unless 235°C is stipulated).
3. The body temperature is the most important parameter but other profile parameters
such as total exposure time to hot temperature or heating rate may also influence
component reliability.
A maximum of three reflow passes is allowed per component.
20
AT91FR4042
2648B–ATARM–12/02
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