maxq1004 Maxim Integrated Products, Inc., maxq1004 Datasheet - Page 15

maxq1004

Manufacturer Part Number

maxq1004

Description

1-wire And Spi Authentication Microcontroller

Manufacturer

Maxim Integrated Products, Inc.

Datasheet

1.MAXQ1004.pdf (18 pages)

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Figure 2. In-Circuit Debugger

Embedded debugging capability is available through

the JTAG-compatible test access port (TAP). Embedded

debug hardware and embedded ROM firmware provide

in-circuit debugging capability to the user application,

eliminating the need for an expensive in-circuit emulator.

See Figure 2. The in-circuit debug features include the

following:

• Hardware debug engine

• Set of debug service routines stored in the utility ROM

The embedded hardware debug engine is an indepen-

dent hardware block in the microcontroller. The debug

engine can monitor internal activities and interact with

selected internal registers while the CPU is executing

user code. Collectively, the hardware and software fea-

tures allow two basic modes of in-circuit debugging:

• Background mode allows the host to configure and set

• Debug mode allows the debug engine to take control

TMS

TDO

TCK

TDI

up the in-circuit debugger while the CPU continues to

execute the application software at full speed. Debug

mode can be invoked from background mode.

of the CPU, providing read/write access to internal

registers and memory and single-step trace operation.

1-Wire and SPI Authentication Microcontroller

CONTROLLER

MAXQ1004

TAP

(UTILITY ROM)

In-Circuit Debug

ROUTINES

BREAKPOINT

SERVICE

ENGINE

DEBUG

CONTROL

ADDRESS

DATA

CPU

Careful PCB layout significantly minimizes crosstalk

among the high-speed external address/data bus sig-

nals and with digital I/O that could cause improper

operation. The use of multilayer boards is essential to

allow the use of dedicated power planes. Bypass V

on each microcontroller with a 0.1FF capacitor located

as close as possible to the pin.

CMOS design guidelines for any semiconductor require

that no pin be taken above V

Violation of this guideline can result in a hard failure

(damage to the silicon inside the device) or a soft failure

(unintentional modification of memory contents). Voltage

spikes above or below the device’s absolute maximum

ratings can cause a temporary brownout of the internal

power rail, possibly corrupting memory.

Microcontrollers commonly experience negative volt-

age spikes through either their power pins or general-

purpose I/O pins. Negative voltage spikes on power pins

are especially problematic as they directly couple to the

internal power buses. Devices such as keypads can

conduct electrostatic discharges directly into the micro-

controller and seriously damage the device. System

designers must protect components against these tran-

sients that can corrupt system memory.

In a practical application, it is difficult to remove all volt-

ages above V

can be tolerated by the microcontroller, and 5V tolerant

pins can accept up to 5.5V. Figure 3 demonstrates a

diode protection scheme that can be used to protect the

I/O pins of a microcontroller. The scheme relies on the

use of a Schottky diode and current limiting resistor to

reduce the effect of current spikes on the device. When

the voltage approaching the device pin exceeds V

or GND by more than 0.1V to 0.2V, the Schottky diodes

become forward biased, conducting the excess voltage

away from the device pins. The current limiting resistors

also help dampen the effect of the voltage spike on the

microcontroller.

Design Guidelines for ESD Protection

Applications Information

or below ground. Undershoots of 0.3V

Grounds and Bypassing

or below ground.

maxq1004 Maxim Integrated Products, Inc., maxq1004 Datasheet - Page 15

maxq1004

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