DS87C520-QNL+T&R Maxim Integrated Products, DS87C520-QNL+T&R Datasheet - Page 20

DS87C520-QNL+T&R

Manufacturer Part Number

DS87C520-QNL+T&R

Description

IC MCU EPROM/ROM 33MH IND 44PLCC

Manufacturer

Maxim Integrated Products

Series

87Cr

Datasheet

1.DS87C520-QCL.pdf (43 pages)

Specifications of DS87C520-QNL+T&R

Core Processor

8051

Core Size

8-Bit

Speed

33MHz

Connectivity

EBI/EMI, SIO, UART/USART

Peripherals

Power-Fail Reset, WDT

Number Of I /o

Program Memory Size

16KB (16K x 8)

Program Memory Type

OTP

Ram Size

1K x 8

Voltage - Supply (vcc/vdd)

4.5 V ~ 5.5 V

Oscillator Type

External

Operating Temperature

-40°C ~ 85°C

Package / Case

44-LCC, 44-PLCC

Processor Series

DS87C520

Core

8051

Data Bus Width

8 bit

Data Ram Size

1 KB

Interface Type

UART

Maximum Clock Frequency

33 MHz

Number Of Programmable I/os

Number Of Timers

Operating Supply Voltage

4.5 V to 5.5 V

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

3rd Party Development Tools

PK51, CA51, A51, ULINK2

Minimum Operating Temperature

- 40 C

Package

44PLCC

Device Core

8051

Family Name

87C

Maximum Speed

33 MHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Eeprom Size

Data Converters

Lead Free Status / Rohs Status

Details

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DS87C520/DS83C520 EPROM/ROM High-Speed Microcontrollers

IDLE MODE

Setting the lsb of the Power Control register (PCON;87h) invokes the Idle mode. Idle will leave internal

clocks, serial ports and timers running. Power consumption drops because the CPU is not active. Since

clocks are running, the Idle power consumption is a function of crystal frequency. It should be

approximately one-half the operational power at a given frequency. The CPU can exit the Idle state with

any interrupt or a reset. Idle is available for backward software compatibility. The system can now reduce

power consumption to below Idle levels by using PMM1 or PMM2 and running NOPs.

STOP MODE ENHANCEMENTS

Setting Bit 1 of the Power Control register (PCON; 87h) invokes the Stop mode. Stop mode is the lowest

power state since it turns off all internal clocking. The I

f a standard Stop mode is approximately 1A

(but is specified in the Electrical Specifications). The CPU will exit Stop mode from an eternal interrupt

or a reset condition. Internally generated interrupts (timer, serial port, Watchdog) are not useful since they

require clocking activity.

The DS87C520/DS83C520 provide two enhancements to the Stop mode. As documented below, the

device provides a bandgap reference to determine Power-Fail Interrupt and Reset thresholds. The default

state is that the bandgap reference is off while in Stop mode. This allows the extremely low-power state

mentioned above. A user can optionally choose to have the bandgap enabled during Stop mode. With the

bandgap reference enabled, PFI and Power-fail Reset are functional and are a valid means for leaving

Stop mode. This allows software to detect and compensate for a brownout or power supply sag, even

when in Stop mode. In Stop mode with the bandgap enabled, I

will be approximately 50A compared

with 1A with the bandgap off. If a user does not require a Power-fail Reset or Interrupt while in Stop

mode, the bandgap can remain disabled. Only the most power-sensitive applications should turn off the

bandgap, as this results in an uncontrolled power-down condition.

The control of the bandgap reference is located in the Extended Interrupt Flag register (EXIF; 91h).

Setting BGS (EXIF.0) to a 1 will keep the bandgap reference enabled during Stop mode. The default or

reset condition is with the bit at a logic 0. This results in the bandgap being off during Stop mode. Note

that this bit has no control of the reference during full power, PMM, or Idle modes.

The second feature allows an additional power saving option while also making Stop easier to use. This is

the ability to start instantly when exiting Stop mode. It is the internal ring oscillator that provides this

feature. This ring can be a clock source when exiting Stop mode in response to an interrupt. The benefit

of the ring oscillator is as follows.

Using Stop mode turns off the crystal oscillator and all internal clocks to save power. This requires that

the oscillator be restarted when exiting Stop mode. Actual startup time is crystal-dependent, but is

normally at least 4ms. A common recommendation is 10 ms. In an application that will wake up, perform

a short operation, then return to sleep, the crystal startup can be longer than the real transaction. However,

the ring oscillator will start instantly. Running from the ring, the user can perform a simple operation and

return to sleep before the crystal has even started. If a user selects the ring to provide the startup clock and

the processor remains running, hardware will automatically switch to the crystal once a power-on reset

interval (65,536 clocks) has expired. Hardware uses this value to assure proper crystal start even though

power is not being cycled.

The ring oscillator runs at approximately 2MHz to 4MHz but will not be a precise value. Do not conduct

real-time precision operations (including serial communication) during this ring period. Figure 3 shows

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DS87C520-QNL+T&R Maxim Integrated Products, DS87C520-QNL+T&R Datasheet - Page 20

DS87C520-QNL+T&R

Specifications of DS87C520-QNL+T&R

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