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INTEGRATED CIRCUITS

DATA SHEET

84C44X; 84C64X; 84C84X 8-bit microcontrollers with OSD and VST
Product specification Supersedes data of October 1994 File under Integrated Circuits, IC14 1996 Nov 29

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
CONTENTS 1 1.1 1.2 2 2.1 3 4 5 6 7 7.1 8 8.1 9 9.1 9.2 9.3 10 11 12 12.1 12.2 12.3 12.4 12.5 12.6 12.7 12.8 12.9 FEATURES PCF84CXXXA kernel Derivative features PCA84C640 GENERAL DESCRIPTION Important note ORDERING INFORMATION BLOCK DIAGRAM PINNING INFORMATION DIFFERENCES BETWEEN THE TYPES RESET Power-on-reset ANALOG CONTROL 6-bit PWM DACs VST CONTROL 14-bit PWM DAC Coarse adjustment Fine adjustment AFC INPUT INPUT/OUTPUT (I/O) ON SCREEN DISPLAY Features Horizontal display position control Vertical display position control Clock generator Display data registers Display control registers OSD display position OSD character size and colour selection Character ROM 13 14 15 16 17 17.1 18 19 19.1 19.2 19.3 20 21 22

84C44X; 84C64X; 84C84X
EMULATION MODE REGISTER MAP LIMITING VALUES DC CHARACTERISTICS AC CHARACTERISTICS Characteristic curves PACKAGE OUTLINE SOLDERING Introduction Soldering by dipping or by wave Repairing soldered joints DEFINITIONS LIFE SUPPORT APPLICATIONS PURCHASE OF PHILIPS I2C COMPONENTS

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
1 1.1 FEATURES PCF84CXXXA kernel

84C44X; 84C64X; 84C84X

· Four programmable display dot sizes · Half dot character rounding · Seven colours for each character · One 14-bit PWM output for VST · Five 6-bit PWM outputs for analog controls · Eight port lines with 10 mA LED drive capability · 18 general purpose bidirectional I/O lines plus 11 function-combined I/O lines · 2 direct testable lines · Programmable VSYNCN and HSYNCN input polarity · RC oscillator for OSD function. 2 GENERAL DESCRIPTION

· 8-bit CPU, ROM, RAM, I/O in a single 42 leads shrink DIL package · Over 80 instructions all of 1 or 2 cycles · 29 quasi-bidirectional standard I/O port lines · Configuration of I/O lines individually selected by mask · External interrupt INT/T0 · 2 direct testable inputs T0 and T1 · 8-bit programmable timer/event counter · 3 single level vectored interrupts (external, timer/counter, I2C-bus) · Power-on-reset and low voltage detector · Single power supply · 2 power reduction modes: Idle and Stop · Operating temperature range: -20 to +70 °C · Silicon gate CMOS fabrication process (SAC2). 1.2 Derivative features PCA84C640

The 84C44X; 84C64X; 84C84X denotes the types: · PCA84C440; 84C441; 84C443; 84C444 · PCA84C640; 84C641; 84C643; 84C644 · PCA84C840; 84C841; 84C843; 84C844. which are 8-bit microcontrollers with On Screen Display (OSD) and Voltage Synthesized Tuning (VST) functions. All are members of the 84CXXX microcontroller family. There are two oscillator types for the OSD function in the various types, i.e., · RC oscillator: PCA84C440; 84C443; 84C640; 84C643; 84C840; 84C843 · LC oscillator: PCA84C441; 84C444; 84C641; 84C644; 84C841; 84C844. 2.1 Important note

Although the PCA84C640 is specifically referred to throughout this data sheet, the information applies to all the devices. The small differences between the 84C640 and the other devices are specified in the text and also highlighted in Chapter 6. The PCA84C640 comprises: · The PCF84CXXXA processor core · 6 kbytes mask-programmable program ROM · 128 bytes RAM · Multi-master I2C-bus interface · AFC input for Voltage Synthesized Tuning (VST; with 3-bit DAC and comparator) · On Screen Display (OSD) facility for two rows of 16-characters · On Screen Display character set of 64 types 3 ORDERING INFORMATION

This data sheet details the specific properties of the PCA84C44X, PCA84C64X and PCA84C84X. The shared characteristics of the PCA84CXXX family of microcontrollers are described in the PCF84CXXXA Family single-chip 8-bit Microcontroller of "Data Handbook IC14", which should be read in conjunction with this data sheet.

PACKAGE TYPE NUMBER NAME PCA84C440; 84C443; 84C640; 84C643; 84C840; 84C843 PCA84C441; 84C444; 84C641; 84C644; 84C841; 84C844 DESCRIPTION VERSION

TEMPERATURE RANGE (°C)

SDIP42

plastic shrink dual in-line SOT270-1 package; 42 leads (600 mil)

-20 to +70

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
4 BLOCK DIAGRAM

84C44X; 84C64X; 84C84X

handbook, full pagewidth

T1 (6)

INT/T0

VOB

VOW2

DOSC1

VSYNCN

VOW1

VOW3

DOSC2 HSYNCN (3)

XTAL1 (IN) 8-BIT TIMER / EVENT COUNTER ROM (1) RAM (2) ON SCREEN DISPLAY

CPU

XTAL2 (OUT)

8-bit internal bus

RESET PARALLEL I/O PORTS 84CXXX core excluding ROM/RAM 8-BIT I/O PORTS

TEST/EMU

6-BIT DAC

14-BIT DAC

3-BIT DAC + COMPARATOR

I2 C INTERFACE

8

5

8

8

MCD170

P0

P1

DP0 DP1 (5)

1 2 3 4 5 PWM

TDAC

AFC

SDA (4)

SCL

(1) 4 kbytes for the PCA84C440; 84C441; 84C443; 84C444. 6 kbytes for the PCA84C640; 84C641; 84C643; 84C644. 8 kbytes for the PCA84C840; 84C841; 84C843; 84C844. (2) 128 bytes for the PCA84C440; 84C441; 84C443; 84C444; 84C640; 84C641; 84C643; 84C644. 192 bytes for the PCA84C840; 84C841; 84C843; 84C844. (3) For use with an LC oscillator, only available with the: PCA84C441; 84C444; 84C641; 84C644; 84C841; 84C844. (4) I2C-bus interface not available with the: PCA84C443; 84C444; 84C643; 84C644; 84C843; 84C844. (5) DP1.4 only available for PCA84C440; 84C443; 84C640; 84C643; 84C840; 84C843. (6) T1 = pin 29 for PCA84C440; 84C443; 84C640; 84C643; 84C840; 84C843. T1 = pin 34 for PCA84C441; 84C444; 84C641; 84C644; 84C841; 84C844.

Fig.1 Block diagram.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
5 PINNING INFORMATION

84C44X; 84C64X; 84C84X

handbook, halfpage

handbook, halfpage

DP0.0/TDAC DP0.1/PWM1 DP0.2/PWM2 DP0.3/PWM3 DP0.4/PWM4 DP0.5/PWM5 P1.0 P1.1 DP1.7/AFC

1 2 3 4 5 6 7 8 9 PCA84C440 PCA84C443 PCA84C640 PCA84C643 PCA84C840 PCA84C843

42 VDD 41 DP1.0 40 DP0.6/SDA 39 DP0.7/SCL 38 DP1.1 37 DP1.2 36 DP1.3 35 INT/T0 34 DP1.4 33 RESET 32 XTAL2 31 XTAL1 30 TEST/EMU 29 T1 28 DOSC1 27 VSYNCN 26 HSYNCN 25 VOB 24 VOW3 23 VOW2/DP1.5

DP0.0/TDAC

1 2 3 4 5 6 7 8 9 PCA84C441 PCA84C444 PCA84C641 PCA84C644 PCA84C841 PCA84C844

42 VDD 41 DP1.0 40 DP0.6/SDA 39 DP0.7/SCL 38 DP1.1 37 DP1.2 36 DP1.3 35 INT/T0 34 T1 33 RESET 32 XTAL2 31 XTAL1 30 TEST/EMU 29 DOSC2 28 DOSC1 27 VSYNCN 26 HSYNCN 25 VOB 24 VOW3 23 VOW2/DP1.5 22 VOW1/DP1.6
MCD171

DP0.1/PWM1 DP0.2/PWM2 DP0.3/PWM3 DP0.4/PWM4 DP0.5/PWM5 P1.0 P1.1 DP1.7/AFC

P1.2 10 P1.3 11 P1.4 12 P0.0 13 P0.1 14 P0.2 15 P0.3 16 P0.4 17 P0.5 18 P0.6 19 P0.7 20 V SS 21

P1.2 10 P1.3 11 P1.4 12 P0.0 13 P0.1 14 P0.2 15 P0.3 16 P0.4 17 P0.5 18 P0.6 19 P0.7 20

22 VOW1/DP1.6

VSS 21
MCD172

Fig.2 Pinning diagram for PCA84CX40; 84CX43.

Fig.3 Pinning diagram for PCA84CX41; 84CX44.

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Philips Semiconductors

Table 1

Pin description

8-bit microcontrollers with OSD and VST

SYMBOL(1)

PIN(1) DESCRIPTION

84CX40; 84CX43 84CX41; 84CX44 84CX40; 84CX43 84CX41; 84CX44 Deviating pinning DP1.0 to DP1.4 T1 DOSC1 - Mutual pinning DP0.0/TDAC DP0.1 to DP0.5/PWM1 to PWM5 P1.0 to P1.4 P0.0 to P0.7 DP1.7/AFC DP0.6/SDA DP0.7/SCL INT/T0 DP1.5 and DP1.6/VOW2 and VOW1 RESET XTAL2, XTAL1 TEST/EMU VSYNCN HSYNCN VOB VOW3 VSS VDD Note 1. 84CX40; 84CX43 denotes the types: PCA84C440, PCA84C443, PCA84C640, PCA84C643, PCA84C840 and PCA84C843. 84CX41; 84CX44 denotes the types: PCA84C441, PCA84C444, PCA84C641, PCA84C644, PCA84C841 and PCA84C844. 1 2 to 6 7, 8, 10, 11 and 12 13 to 20 9 40 39 35 23, 22 33 32, 31 30 27 26 25 24 21 42 Derivative Port 0: quasi-bidirectional I/O line or 14-bit DAC PWM. Derivative Port 1: quasi-bidirectional I/O lines or 6-bit DAC PWM. Port 1: quasi-bidirectional I/O lines. Port 0: quasi-bidirectional I/O port. Derivative Port 1: quasi-bidirectional I/O line or comparator input with 3-bit DAC. Derivative open drain I/O port or I2C-bus data line. Derivative open drain I/O port or I2C- bus clock line. External interrupt or direct testable line. Derivative Port 1: quasi-bidirectional I/O lines or character video output. Initialize input, active LOW. DP1.0 to DP1.3 T1 - DOSC1/DOSC2 41, 38, 37, 36, 34 41, 38, 37, 36 29 28 - 34 - 28, 29 Derivative Port 1: quasi-bidirectional I/O lines. Direct testable pin and event counter input. Connection to RC oscillator of OSD clock. Connections to LC oscillator of OSD clock.

84C44X; 84C64X; 84C84X

Oscillator output or input terminal for system clock. Control input for testing and emulation mode. Ground for normal operation. Vertical synchronous signal input. Horizontal synchronous signal input. Blanking output. Character video output of OSD. Ground. Power supply.

Product specification

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Table 2 Differences between the types PCA84C44X, PCA84C64X and PCA84C84X In this table: yes = available; no = not available. PCA... FEATURE 84C440 84C441 84C443 84C444 84C640 84C641 84C643 84C644 84C840 84C841 84C843 84C844 OSD oscillator I2C-bus ROM RAM Pin assignment Pin 29 Pin 34 Register DP1 (bit DP1.4) Pin Latch yes yes no no yes yes no no yes yes no no yes yes no no yes yes no no yes yes no no T1 DP1.4 DOSC2 T1 T1 DP1.4 DOSC2 T1 T1 DP1.4 DOSC2 T1 T1 DP1.4 DOSC2 T1 T1 DP1.4 DOSC2 T1 T1 DP1.4 DOSC2 T1 interface RC yes LC 17 yes RC 18 no 4 kbytes 128 bytes LC 17 no RC 18 yes LC 17 yes RC 18 no 6 kbytes 128 bytes LC 17 no RC 18 yes LC 17 yes RC 18 no 8 kbytes 192 bytes LC 17 no General purpose I/O lines 18

8-bit microcontrollers with OSD and VST 84C44X; 84C64X; 84C84X

DIFFERENCES BETWEEN THE TYPES

Product specification

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
7 RESET 7.1

84C44X; 84C64X; 84C84X
Power-on-reset

The RESET pin (active LOW input) is used to initialize the microcontroller to a defined state. The Reset configuration is shown in Fig.5.

The Power-on-reset circuit monitors the voltage level of VDD. If VDD remains below the internal reference voltage level Vref (typically 1.3 V), the oscillator is inhibited. When VDD rises above Vref, the oscillator is released and the internal reset is active for a period of td (typically 50 µs). Considering the VDD rise time, the following measures for a correct Power-on-reset can be taken: · If the VDD rises above the minimum operation voltage before time period td is exceeded, no external components are necessary (see Fig.6). · If VDD has a slow rise time, such that after the time period (tVref + td) has elapsed the supply voltage is still below the minimum operation voltage (Vmin), external components are required (see Figs 4 and 7). To guarantee a correct reset operation, ensure that the time constant RC 8 × tVDD. A definite Power-on-reset can be realized by applying an (external) RESET signal during power-on.

andbook, halfpage

VDD R 100 k RESET

C

MCD174

VSS

Fig.4 External components for RESET pin.

handbook, full pagewidth

oscillator inhibit

VDD

Vref

POWER-ON-RESET RESET

internal reset

V SS
MLA651

Fig.5 Reset configuration.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

handbook, full pagewidth

VDD V ref VSS

VDD

VDD RESET VSS td

OSCILLATOR

oscillator start up time

MCD240

Fig.6 Reset with fast rising VDD.

handbook, full pagewidth

VDD

VDD Vmin Vref VSS t VDD

RESET
without external component

VDD

VSS t Vref td

RESET
with external component

VDD

VSS RC 8 × tVDD

OSCILLATOR

oscillator start up time

MCD241

Fig.7 Reset with slow VDD. 1996 Nov 29 9

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
8 8.1 ANALOG CONTROL 6-bit PWM DACs 8.1.3

84C44X; 84C64X; 84C84X
ANALOG OUTPUT VOLTAGE

Five PWM outputs are available for analog control purposes e.g. volume, balance, brightness, saturation, etc. The block diagram of a typical 6-bit PWM DAC is shown in Fig.8. Each PWM output can generate pulses of programmable length that have a repetition frequency of 1/ × f 1 64 PWM, where fPWM = /3 × fXTAL. 8.1.1 PIN SELECTION FOR PWM OUTPUTS

A DC voltage proportional to the PWM control setting may be obtained by connecting an integrating network to each of the PWM outputs (see Fig.9). The analog value is calculated as follows: t HIGH V A = ------------- × V O tr Where: · t HIGH = t 0 × PWMDL = HIGH time of the PWM pulse · t r = t 0 × 64 = repetition time of the PWM pulse 3 · t 0 = ------------f XTAL · PWMDL is the decimal value of the contents of the PWM data latch. Therefore, the analog output voltage is: PWMDL V A = ----------------------- × V O 64

The PWM outputs PWM1 to PWM5, share the same pins as the Derivative Port lines DP0.1 to DP0.5. Setting the (relevant PWM enable) bit PWMnE to: · Logic 1, selects the relevant PWMx output function · Logic 0, selects the relevant DP0.x Port function. 8.1.2 POLARITY OF THE PWM OUTPUTS

The polarity of all five PWM outputs is selected by the state of the polarity control bit P6LVL. Setting the control bit P6LVL to: · Logic 0, sets the PWMx outputs to the default polarity · Logic 1, inverts all the PWMx outputs.

handbook, full pagewidth

f PWM

6-BIT PWM DATA LATCH

DP0.x data I/O

PWMnE

6-BIT DAC PWM CONTROLLER

Q Q DP0.x/PWMx

P6LVL

polarity control bit
MCD176

Fig.8 Block diagram of the 6-bit PWM DAC.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

handbook, full pagewidth

t0

f PWM 64 1 2 3 m m+1 m+2 63 64 1

00

01

m

63

decimal value PWM data latch

MCD175

Fig.9 PWM output patterns (P6LVL = 0).

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
9 9.1 VST CONTROL 14-bit PWM DAC 9.2

84C44X; 84C64X; 84C84X
Coarse adjustment

The PCA84C640 has one 14-bit PWM DAC output (TDAC) with a resolution of 16384 levels for Voltage Synthesized Tuning. The PWM DAC (see Fig.10) consists of: · 14-bit counter · Two 7-bit DAC interface data latches (VSTH and VSTL) · One 14-bit DAC data latch (VSTREG) · Pulse control. The polarity of output TDAC is selected with bit P14LVL. Setting the bit P14LVL to: · Logic 1, sets the TDAC output to the default polarity · Logic 0, inverts the TDAC output. 9.1.1 14-BIT COUNTER

The coarse adjustment output (OUT1) is reset to LOW (inactive) at the start of each tsub period. It will remain LOW until the time [ t 0 × ( VSTH + 1 ) ] has elapsed and then will go HIGH and remain so until the next tsub period starts. 9.3 Fine adjustment

The counter is continuously running and is clocked by f0. 3 The period of the clock, t 0 = ------------f XTAL The repetition time for one complete cycle of the counter: t r = t 0 × 16 384 The repetition time for one cycle of the lower 7-bits of the counter is: t sub = t 0 × 128 Therefore, the number of tsub periods in a complete cycle tr is: t 0 × 16 384 N = --------------------------- = 128 t 0 × 128 9.1.2 DATA AND INTERFACE LATCHES

Fine adjustment is achieved by generating additional pulses at the start of particular sub-periods (tsubn). These additional pulses have a width of t0. The sub-period in which a pulse is added is determined by the contents of VSTL interface latch. Table 3 gives the numbers of the tsubn, at the start of which an additional pulse is generated, depending on the bit in VSTL being a logic 0. When more than one bit is a logic 0 a combination of additional pulses are generated. For example, if VSTL = 1111010, which is a combination of · VSTL = 1111110: sub-period 64, and · VSTL = 1111011: sub-periods 16, 48, 80 and 112, then additional pulses will be given in sub-periods 16, 48, 64, 80 and 112; this is illustrated in Fig.12. If VSTH = 0011101, VSTL = 1111010 and P14LVL = 0, then the TDAC output is as shown in Fig.13. Table 3 Additional pulse distribution ADDITIONAL PULSE IN SUB-PERIODS tsubn 64 32, 96 16, 48, 80, 112 8, 24, 40, 56, 72, 88, 104, 120 4, 12, 20, 28, 36, 44, 52, 60 .... 116, 124 2, 6, 10, 14, 18, 22, 26, 30, .... 122, 126 1, 3, 5, 7, 9, 11, 13, 15, 17, .... 125, 127

LOWER 7 BITS (VSTL) 1111110 1111101 1111011 1110111 1101111 1011111 0111111

In order to ensure correct operation, interface data latch VSTH is loaded first and then interface data latch VSTL. The contents of: · VSTH are used for coarse adjustment · VSTL are used for fine adjustment. At the beginning of the first tsub period following the loading of VSTL, both data latches are loaded into data latch VSTREG. After the contents of VSTH and VSTL are latched into VSTREG, one tsub period is needed to generate the appropriate pulse pattern. To ensure correct DAC conversion, two (2) tsub periods should be allowed before beginning the next sequence.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

handbook, full pagewidth

'MOV instruction' 'MOV instruction'

DATA LATCH VSTH

DATA LATCH VSTL

7

7

DATA LOAD TIMING PULSE

LOAD

DAC DATA LATCH VSTREG

7

7

COARSE PWM OUT1 OUT2

FINE

polarity control bit

ADD Q Q

TDAC output P14LVL Q14 to Q8 14-BIT COUNTER
MCD177

Q7 to Q1 f0

Fig.10 Block diagram of the 14-bit PWM DAC.

tr
andbook, full pagewidth

t sub0

t sub1

t subn

t sub127

OUT 1
MCD313

t0 × (VSTH + 1)

Fig.11 Coarse adjustment output (OUT1).

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

tr
handbook, full pagewidth

t sub0

t sub16

t sub32

t sub48

t sub64

t sub80

t sub96

t sub112

t sub127

111 1110

111 1101

111 1011

111 1010
MCD314

VSTL

Fig.12 Fine adjustment output (OUT2).

tr
handbook, full pagewidth

t sub0

t

sub16

t

sub32

t

sub48

t

sub64

t

sub80

t

sub96

t

sub112

t

sub127

OUT 1

OUT 2

TDAC
MCD315

Fig.13 TDAC output.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
10 AFC INPUT The AFC input is used to measure the level of the Automatic Frequency Control signal. This is achieved by comparing the AFC input signal with the output of a 3-bit DAC as shown in Fig.14. DAC analog switches select one of 8 resistor taps connected between VDD and VSS. Consequently, eight different voltages may be selected (see Table 4). The compare signal AFCC, can be tested to determine whether the AFC input is higher or lower than the DAC level. The AFC input shares the same pin as the Derivative Port line DP1.7. Setting the enable bit AFCE to: · Logic 1, selects the AFC function · Logic 0, selects the Derivative Port DP1.7 function. Table 4

84C44X; 84C64X; 84C84X
Selection of Vref Vref VDD × 0.125 VDD × 0.250 VDD × 0.375 VDD × 0.500 VDD × 0.625 VDD × 0.750 VDD × 0.875 VDD Vref (for VDD = 5.0 V) 0.625 V 1.250 V 1.875 V 2.500 V 3.125 V 3.750 V 4.375 V 5.000 V

AFC2 AFC1 AFC0 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1

handbook, full pagewidth

DP1.7

internal bus

DP1.7/AFC

COMPARATOR EN

AFCC

3-BIT DAC

EN

AFC2

AFC1

AFC0

AFCE
MCD178

inner latches

Fig.14 AFC circuit.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
11 INPUT/OUTPUT (I/O) Each parallel I/O port line may be individually configured using one of three possible I/O mask options. The three I/O mask options are specified below: Option 1 Standard port with switched pull-up current source, Fig.15. Option 2 Open drain, Fig.16. Option 3 Push-pull (output only), Fig.17.

84C44X; 84C64X; 84C84X

Table 5 specifies the possible port option list. When these devices are used for emulation purposes, in order to match the piggy back device provided it is recommended that the port options listed in Table 6 are used.

WRITE PULSE
handbook, full pagewidth OUTL/ORL/ANL/MOV

TR2 TR3

DATA BUS

D

MQ

D

SQ

constant current source 100 µA typ.

VDD

MASTER

SLAVE SQ TR1 I/O PORT LINE

VSS

ORL/ANL/MOV
MLA696

IN/MOV

Fig.15 Standard output with switched pull-up current source (Option 1).

handbook, full pagewidth

WRITE PULSE OUTL/ORL/ANL DATA BUS D MQ D SQ

VDD

MASTER

SLAVE SQ TR1

I/O PORT LINE

VSS

ORL/ANL
MLA697

IN

Fig.16 Open drain type I/O (Option 2).

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

WRITE PULSE handbook, full pagewidth OUTL/OR /ANL TR2

VDD constant current source 100 µA typ. OUTPUT LINE

DATA BUS

D

MQ

D

SQ

MASTER

SLAVE SQ TR1

VSS

ORL/ANL
MGD864

IN

Fig.17 Push-pull type output (Option 3).

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
Table 5 User mask programmable port option list PORT P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 P1.0 P1.1 P1.2 P1.3 P1.4 DP0.0 DP0.1 DP0.2 DP0.3 DP0.4 DP0.5 DP0.6 DP0.7 DP1.0 DP1.1 DP1.2 DP1.3 DP1.4(2) DP1.5 DP1.6 DP1.7 VOB VOW3 Notes 1. Each pin can be configured to a HIGH (S) or LOW (R) state after power-on-reset. The required state of each pin is therefore specified by R or S. 2. DP1.4 available only with the PCA84C440, PCA84C443, PCA84C640, PCA84C643, PCA84C840 and PCA84C843. PIN 13 14 15 16 17 18 19 20 7 8 10 11 12 1 2 3 4 5 6 40 39 41 38 37 36 34 23 22 9 25 24 3 3 R R OPTION(1) Table 6

84C44X; 84C64X; 84C84X
Port options for the 84C640 in emulation mode PORT P0.0 P0.1 P0.2 P0.3 P0.4 P0.5 P0.6 P0.7 P1.0 P1.1 P1.2 P1.3 P1.4 DP0.0 DP0.1 DP0.2 DP0.3 DP0.4 DP0.5 DP0.6 DP0.7 DP1.0 DP1.1 DP1.2 DP1.3 DP1.4 DP1.5 DP1.6 DP1.7 VOB VOW3 PIN 13 14 15 16 17 18 19 20 7 8 10 11 12 1 2 3 4 5 6 40 39 41 38 37 36 34 23 22 9 25 24 3 3 R R 2 2 S S 1 1 1 1 1 1 1 1 1 1 1 1 1 OPTION S S S S S S S S S S S S S

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12 ON SCREEN DISPLAY 12.1 Features 12.4

84C44X; 84C64X; 84C84X
Clock generator

· Display format: 2 rows × 16 characters · Software controlled vertical and horizontal display position · 64 different (mask programmable) characters in ROM · Black box background · Four programmable display character sizes · Four programmable character dot matrix sizes: ­ 6 × 9 and 6 × 13 ­ 8 × 9 and 8 × 13 · Half-dot rounding for the whole screen · 4 from 7 colours possible on screen · Clock generator for On Screen Display function with: ­ RC oscillator ­ LC oscillator, for the various types of PCA84C44X; 84C64X; 84C84X. 12.2 Horizontal display position control

There are two types of oscillators available for the various types. The oscillator is triggered on the trailing edge of HSYNCN when the OSD logic is enabled and stops on the following leading edge of HSYNCN. The OSD oscillator must be externally adjusted to the desired frequency (decreasing the OSD frequency gives broader characters). Before the oscillation frequency can be adjusted HSYNCN must be HIGH (if HLVL = 1). Oscillation stops by setting the HSYNCN pin LOW when HLVL = 1. 12.4.1 RC OSCILLATOR

The RC oscillator is available in the types: PCA84C440; 84C443; 84C640; 84C643; 84C840; 84C843. The external RC network is connected between pin 28 and VSS (see Fig.19). 12.4.2 LC OSCILLATOR

The horizontal position counter is incremented every OSD cycle after the programmed level of HSYNCN occurs at the HSYNCN pin. The counter is reset when the opposite polarity of the HSYNCN pulse is reached. 12.3 Vertical display position control

The LC oscillator is available in the types: PCA84C441; 84C444; 84C641; 84C644; 84C841; 84C844. The external LC network is connected between pins 28 and 29 (see Fig.20).

The vertical position counter is incremented every HSYNCN cycle and is reset by the VSYNCN signal.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

handbook, full pagewidth

VSYNCN

VERTICAL DISPLAY POSITION CONTROL

DISPLAY CONTROL MEMORY

DISPLAY CHARACTER DATA MEMORY

HSYNCN HORIZONTAL DISPLAY POSITION CONTROL CHARACTER ROM

CLOCK GENERATOR (1)

CONTROL TIMING GENERATOR

DISPLAY CONTROL

VOB VOW1 VOW2 VOW3 (1) See Figs 19 and 20 for connection of external components.
MCD179

Fig.18 OSD block diagram.

handbook, halfpage

VDD R
handbook, halfpage

C1 DOSC1

DOSC1 C2 C

L1 DOSC2
MCD247 MCD173

VSS

Fig.19 RC oscillator.

Fig.20 LC oscillator.

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20

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.5 Display data registers

84C44X; 84C64X; 84C84X

The display data registers consists of a group of 32 derivative registers located at addresses 20H to 3FH inclusive (see Table 7). At power-up the contents of the display data registers are undefined. The format of each display data register is shown in Table 8, and their functions described in Table 9. Table 7 Display data registers addresses DISPLAY DATA FOR Row 0 = the first display row Row 1 = the second display row BIT 7 CC1 BIT 6 CC0 BIT 5 MD5 BIT 4 MD4 BIT 3 MD3 BIT 2 MD2 BIT 1 MD1 BIT 0 MD0

ADDRESS 20H to 2FH 30H to 3FH Table 8 7 CC1 Table 9 BIT 7 6 5 4 3 2 1 0 12.6

Display data register (address 20H to 3FH) 6 CC0 5 MD5 4 MD4 3 MD3 2 MD2 1 MD1 0 MD0

Description of display data register bits SYMBOL CC1 CC0 MD5 MD4 MD3 MD2 MD1 MD0 DESCRIPTION Colour code. The state of these two bits enable individual characters to be displayed in one of four colours. See Tables 24, 25 and 26. Character code. The character set is stored in ROM and consists of 64 different characters. The selection of each character is dependent on the state of the 6 bits, MD0 to MD5.

Display control registers

The display control registers consists of a group of 6 derivative registers located at addresses 40H to 45H inclusive (see Table 10). Each register may be read from or written to. After a reset operation the contents of the display control registers are zero. Table 10 Display control registers addresses ADDRESS 40H 41H 42H 43H 44H 45H REGISTER OSDCA LINE 0A LINE 0B OSDCB LINE 1A LINE 1B BIT 7 CC34 SZ01 BLK0 CDTW SZ11 BLK1 BIT 6 CC24 SZ00 VB0 CDTH SZ10 VB1 BIT 5 CC14 VP05 HP05 CC33 VP15 HP15 BIT 4 RBLK VP04 HP04 CC23 VP14 HP14 BIT 3 ROUND VP03 HP03 CC32 VP13 HP13 BIT 2 STBY VP02 HP02 CC12 VP12 HP12 BIT 1 VLVL VP01 HP01 CC21 VP11 HP11 BIT 0 HLVL VP00 HP00 CC11 VP10 HP10

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.6.1 DERIVATIVE REGISTER OSDCA

84C44X; 84C64X; 84C84X

Table 11 Derivative register OSDCA (address 40H) 7 CC34 6 CC24 5 CC14 4 RBLK 3 ROUND 2 STBY 1 VLVL 0 HLVL

Table 12 Description of OSCDA bits BIT SYMBOL 7 6 5 4 CC34 CC24 CC14 RBLK Raster blanking control (see Fig.24). When the RBLK bit is: Logic 1, the VOB output is driven HIGH to display the OSD characters on a blank screen. Logic 0, the VOB output returns to its normal output state on the trailing edge of VSYNCN. 3 ROUND Character rounding control (see Figs 22 and 23). The rounding function generates half dots where the corners of two dots meet. The rounding function also works with multiple cell characters. When the ROUND bit is: Logic 1, the rounding function is enabled. Logic 0, the rounding function is disabled. 2 STBY Stand-by. This bit is used to enable or disable the OSD facility. When the STBY bit is: Logic 1, the OSD oscillator is disabled. Logic 0, the OSD oscillator is enabled and the OSD facility is available. 1 VLVL Vertical synchronous signal level (see Fig.21). This bit selects the active level of the VSYNCN input signal. When the VLVL bit is: Logic 1, VSYNCN is active HIGH. Logic 0, VSYNCN is active LOW. 0 HLVL Horizontal synchronous signal level (see Fig.21). This bit selects the active level of the HSYNCN input signal. When the HLVL bit is: Logic 1, HSYNCN is active HIGH. Logic 0, HSYNCN is active LOW. DESCRIPTION Character colour code bits. These bits are used for colour selection purposes. See Table 24.

handbook, full pagewidth

HSYNCN (VSYNCN)

(HLVL = VLVL = 1)

HSYNCN (VSYNCN) characters can be displayed

(HLVL = VLVL = 0)

MCD180

Fig.21 VSYNCN and HSYNCN active level.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

ROUND = 0 H H

ROUND = 1
handbook, halfpage

H

H

H T T T

H
MCD181

T

T

T
MCD246

Fig.22 Rounding function.

Fig.23 Rounding effect.

handbook, full pagewidth

RBLK

VSYNCN

VOB

VOW1, 2, 3
MCD316

= normal output

Fig.24 Raster blanking timing RLBK.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.6.2 DERIVATIVE REGISTERS LINE 0A AND LINE 0B FUNCTION

84C44X; 84C64X; 84C84X

REGISTER LINE 0A LINE 0B

Determine the character size and vertical position of Row 0 (the first display row). Determine the horizontal position of Row 0 and the selection of background and blanking functions.

Table 13 Derivative register LINE 0A (address 41H) 7 SZ01 6 SZ00 5 VP05 4 VP04 3 VP03 2 VP02 1 VP01 0 VP00

Table 14 Description of LINE 0A bits BIT SYMBOL 7 6 5 4 3 2 1 0 SZ01 SZ00 VP05 VP04 VP03 VP02 VP01 VP00 DESCRIPTION Character size. The state of these two bits enable one of four possible character sizes to be selected for Row 0. Character sizes include background. See Table 23. Vertical position control. The vertical position of Row 0 is selected by the state of the 6 bits, VP00 to VP05. For details see Section 12.7.1 "Vertical position".

Table 15 Derivative register LINE 0B (address 42H) 7 BLK0 6 VB0 5 HP05 4 HP04 3 HP03 2 HP02 1 HP01 0 HP00

Table 16 Description of LINE 0B bits BIT SYMBOL 7 BLK0 DESCRIPTION Blanking. This bit enables or disables the character display. When BLK0 is set to: Logic 1, the outputs VOW1, VOW2, VOW3 and VOB are enabled; characters are displayed. Logic 0, the outputs VOW1, VOW2, VOW3 and VOB are disabled; no characters are displayed. 6 VB0 Background. This bit determines whether the background display is selected or not. The visual effect of background versus no background is shown in Fig.26. When VB0 is set to: Logic 1, the characters in this row are displayed with background. Logic 0, the background is disabled and only the characters are displayed. 5 4 3 2 1 0 HP05 HP04 HP03 HP02 HP01 HP00 Horizontal position control. These 6 bits determine the start position of Row 0. The horizontal position control is only active during OSDC clock cycles. For details Section 12.7.2 "Horizontal position" and Fig.25.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.6.3 DERIVATIVE REGISTERS LINE 1A AND LINE 1B FUNCTION

84C44X; 84C64X; 84C84X

REGISTER LINE 1A LINE 1B

Determine the character size and vertical position of Row 1 (the second display row). Determine the horizontal position of Row 1 and the selection of background and blanking functions.

Table 17 Derivative register LINE 1A (address 44H) 7 SZ11 6 SZ10 5 VP15 4 VP14 3 VP13 2 VP12 1 VP11 0 VP10

Table 18 Description of LINE 1A bits BIT SYMBOL 7 6 5 4 3 2 1 0 SZ11 SZ10 VP15 VP14 VP13 VP12 VP11 VP10 DESCRIPTION Character size. The state of these two bits enable one of four possible character sizes to be selected for Row 1. Character sizes include background. See Table 23. Vertical position control. The vertical position of Row 1 is selected by the state of the 6 bits, VP10 to VP15. For details see Section 12.7.1 "Vertical position".

Table 19 Derivative register LINE 1B (address 45H) 7 BLK1 6 VB1 5 HP15 4 HP14 3 HP13 2 HP12 1 HP11 0 HP10

Table 20 Description of LINE 1B bits BIT SYMBOL 7 BLK1 DESCRIPTION Blanking. This bit enables or disables the character display. When BLK1 is: Logic 0, the outputs VOW1, VOW2, VOW3 and VOB are disabled; no characters are displayed. Logic 1, the outputs VOW1, VOW2, VOW3 and VOB are enabled; characters are displayed. 6 VB1 Background. This bit determines whether the background display is selected or not. The visual effect of background versus no background is shown in Fig.26. When VB1 is set to: Logic 1, the characters in this line are displayed with background. Logic 0, the background is disabled and only the character is displayed. 5 4 3 2 1 0 HP15 HP14 HP13 HP12 HP11 HP10 Horizontal position control. These 6 bits determine the start position of Row 1. The horizontal position control is only active during OSDC clock cycles. For details Section 12.7.2 "Horizontal position" and Fig.25.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.6.4 DERIVATIVE REGISTER OSDCB FUNCTION Determine the selection of: · The size of the dot matrix grid · Four colours from a possible seven for the display. Table 21 Derivative register OSDCB (address 43H) 7 CDTW 6 CDTH 5 CC33 4 CC23 3 CC32

84C44X; 84C64X; 84C84X

REGISTER OSDCB

2 CC12

1 CC21

0 CC11

Table 22 Description of OSDCB bits BIT SYMBOL 7 CDTW DESCRIPTION Character dot width control.The state of this bit determines the dot width of the character. When the CDTW bit is set to: Logic 1, the character width is 6 dots. Logic 0, the character width is 8 dots. 6 CDTH Character dot height control. The state of this bit determines the dot height of the character. When the CDTH bit is set to: Logic 1, the character height is 13 dots. Logic 0, the character height is 9 dots. 5 4 3 2 1 0 CC33 CC23 CC32 CC12 CC21 CC11 Colour control bits. In every VSYNCN cycle one screen can select any 4 colours from 7 and in addition a blank or black screen. Combinations of CC1X, CC2X and CC3X control the character outputs VOW1, VOW2 and VOW3 as shown in Table 24.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.7 12.7.1 OSD display position VERTICAL POSITION 12.7.2

84C44X; 84C64X; 84C84X
HORIZONTAL POSITION

The horizontal start position (HP) of, · Row 0: HP0 = 4 × (HP00 HP05) + 5 × tOSCD · Row 1: HP1 = 4 × (HP10 HP15) + 5 × tOSCD Where: · (HP00 HP05) = the decimal value of HP00 HP05 and (HP00 HP05) > 10 · (HP10 HP15) = the decimal value of HP10 HP15 and (HP10 HP15) > 10 · tOSCD = one OSCD clock period. Therefore for both Row 0 and Row 1, HP0, HP1 45 × tOSCD.

The line number of the vertical start position for: · Row 0 is 4 × (VP00 VP05) · Row 1 is 4 × (VP10 VP15). Where: · (VP00 VP05) = the decimal value of VP00 VP05 · (VP10 VP15) = the decimal value of VP10 VP15. The character height in: · Row 0 is H0 and is a function of the number of dots per character and the state of the size control bits SZ00 and SZ01 · Row 1 is H1 and is a function of the number of dots per character and the state of the size control bits SZ10 and SZ11. Row 0 and Row 1 must not overlap each other and therefore: VP1 (VP0 + H0); see Fig.25. The four possible character heights are shown in Table 23.

VP0 HP0 ROW 0 CHARACTERS H0 VP1
handbook, halfpage

HP1 ROW 1 CHARACTERS with background

MCD182

without background

MCD183

Fig.25 Display position.

Fig.26 Background versus no background.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.8 12.8.1 OSD character size and colour selection CHARACTER SIZE

84C44X; 84C64X; 84C84X

The character sizes are selected by bits SZn1 and SZn0, which denotes: · SZ01 and SZ00 for Row 0 · SZ11 and SZ10 for Row 1.

The character sizes are determined by the bits: · CDTW, for the width · CDTH, for the height.

Table 23 Character sizes selection H denotes one horizontal line, T denotes one OSDC clock period and D denotes dots per character width/height. SIZE BITS SZn1 0 0 1 1 12.8.2 SZn0 9D 0 1 0 1 COLOUR SELECTION 18H 36H 54H 72H 13D 26H 52H 78H 104H 6D 12T 24T 36T 48T 8D 16T 32T 48T 64T 2H 4H 6H 8H 2T 4T 6T 8T CHARACTER SIZE VERTICAL HORIZONTAL VERTICAL HORIZONTAL DOT MATRIX POINT

Colour selection is achieved using bits in the, · OSDCA register: CC34, CC24 and CC14 · OSDCB register: CC33, CC23, CC32, CC12, CC21, and CC11 · Display data registers: CC1 and CC0.

In this way every combination of four colours can be made (black and white can not be displayed at the same time). The user may choose one colour out of each block. Table 24 shows the selection of the output combinations. Tables 25 and 26 show the possible colour combinations.

handbook, full pagewidth

CHARACTER ROM

dot

VOW1

CC1 DISPLAY DATA MEMORY CC0

OUTPUT CONTROL LOGIC

VOW2

DISPLAY CIRCUIT CONTROL REGISTERS

CCxx

VOW3

background control
MCD184

OR

VOB

Fig.27 Colour control.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
Table 24 Character colour control COLOUR CODE CC1 0 0 1 1 CC0 0 1 0 1 VOW1 (Red) CC11 CC12 CC23 + CC33 CC14

84C44X; 84C64X; 84C84X

CHARACTER OUTPUT PINS VOW2 (Green) CC21 CC12 + CC32 CC23 CC24 VOW3 (Blue) CC11 + CC21 CC32 CC33 CC34

Table 25 Possible colour combinations (CC1, CC0) = (0, 0) COLOUR VOW1 CC11 Blue Green Red Yellow Magenta Cyan 0 0 1 1 - - VOW2 CC21 0 1 0 1 - - VOW3 CC11 + CC21 1 0 0 0 - - (CC1, CC0) = (0, 1) VOW1 CC12 0 0 1 - 1 - VOW2 CC12 + CC32 0 1 0 - 0 - VOW3 CC32 1 0 0 - 1 - (CC1, CC0) = (1, 0) VOW1 CC12 0 0 1 - - 0 VOW2 CC12 + CC32 0 1 0 - - 1 VOW3 CC32 1 0 0 - - 1

Table 26 Possible colour combinations (continued) (CC1, CC0) = (1, 1) COLOUR VOW1 CC14 Blue Green Red Yellow Magenta Cyan White Black 0 0 1 1 1 0 1 0 VOW2 CC24 0 1 0 1 0 1 1 0 VOW3 CC34 1 0 0 0 1 1 1 0

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
12.9 Character ROM

84C44X; 84C64X; 84C84X

13 EMULATION MODE The emulation mode configuration is shown in Fig.29. In the emulation mode configuration the PCA84C640's CPU is disabled and only its derivative logic is active. The device is controlled by the PCF84C00 bond-out chip. The PCA84C640's two derivative ports act as additional ports for the PCF84C00. The interaction between the two devices is as follows: 1. During the first machine cycle the PCF84C00 fetches an instruction from EPROM and then decodes that instruction. 2. During the second machine cycle the PCF84C00 executes the decoded instruction. If the instruction is related to the derivative ports then DXALE, DXRDN and/or DXWRN become active and the PCA84C640 operates as a peripheral of the PCF84C00. 3. Depending on the type of instruction executed during the second machine cycle the following data transfer happens: a) During TS1 data from the EPROM is available on P0.0 to P0.7 which is then available on IB0.0 of the PCF84C00. b) During TS4 data from the PCA84C640 can be transferred to the PCF84C00. c) During TS6 data from the PCF84C00 can be transferred to the PCA84C640.
MCD185

Character ROM contains the dot character fonts. 13 × 8 dots are reserved for each character, regardless of the dot matrix size actually selected. The dot matrix grid is shown in Fig.28. Philips provides a software under MS DOS environment (IBM/PC or compatible) to help customer to design the character font on the screen and to generate the bit pattern HEX decimal file automatically. Contact your local Philips Sales Organization for details.

1
handbook, halfpage

2

3

4

5

6

7

8

1 2 3 4 5 6 7 8 9 10 11 12 13

Fig.28 Character ROM.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

handbook, full pagewidth

P0.0 to P0.7 P1.0 to P1.7 P2.0 to P2.7

PSEN address bus A0 to A12 data bus D0 to D7

CE A0 to A12 D0 to D7

PCF84C00
STFF XTAL1 RESET XTAL2 DXALE DXRD DXWR

EPROM

MCD317

XTAL1 RESET

P1.0 P1.1 P1.2 P1.3

PCA84C640
DP0.0 to DP0.7 P0.0 to P0.7 DP1.0 to DP1.7 TEST/EMU +5 V

Fig.29 Emulation mode configuration.

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

14 REGISTER MAP The number within parentheses denotes the initial state; `X' denotes don't care. R = Read, W = Write, R/W = Read/Write. ADDR 00H 01H 02H 03H 10H 11H 12H 13H 14H 15H 16H 17H 18H 19H 1AH 20H to 3FH REG DP0 (pin) DP1 (pin) DP0R (latch) DP1R (latch) PWM1 PWM2 PWM3 PWM4 PWM5 VSTL VSTH AFCO AFCC DP0E/ PWME DP1E/ PWMLVL BIT 7 DP0.7 (X) DP1.7 (X) DP0.7 (1) DP1.7 (1) - - - - - - - - - SCLE (0) - BIT 6 DP0.6 (X) DP1.6 (X) DP0.6 (1) DP1.6 (1) - - - - - VST06 (0) VST13 (0) - - SDAE (0) - CC0 (X) BIT 5 DP0.5 (X) DP1.5 (X) DP0.5 (1) DP1.5 (1) PWM15 (0) PWM25 (0) PWM35 (0) PWM45 (0) PWM55 (0) VST05 (0) VST12 (0) - - PWM5E (0) - MD5 (X) BIT 4 DP0.4 (X) DP1.4(1) (X) DP0.4 (1) DP1.4(1) (1) PWM14 (0) PWM24 (0) PWM34 (0) PWM44 (0) PWM54 (0) VST04 (0) VST11 (0) - - PWM4E (0) AFCE (0) MD4 (X) BIT 3 DP0.3 (X) DP1.3 (X) DP0.3 (1) DP1.3 (1) PWM13 (0) PWM23 (0) PWM33 (0) PWM43 (0) PWM53 (0) VST03 (0) VST10 (0) - - PWM3E (0) P14LVL (0) MD3 (X) BIT 2 DP0.2 (X) DP1.2 (X) DP0.2 (1) DP1.2 (1) PWM12 (0) PWM22 (0) PWM32 (0) PWM42 (0) PWM52 (0) VST02 (0) VST09 (0) AFC2 (0) - PWM2E (0) P6LVL (0) MD2 (X) BIT 1 DP0.1 (X) DP1.1 (X) DP0.1 (1) DP1.1 (1) PWM11 (0) PWM21 (0) PWM31 (0) PWM41 (0) PWM51 (0) VST01 (0) VST08 (0) AFC1 (0) - PWM1E (0) VOW2E (0) MD1 (X) BIT 0 DP0.0 (X) DP1.0 (X) DP0.0 (1) DP1.0 (1) PWM10 (0) PWM20 (0) PWM30 (0) PWM40 (0) PWM50 (0) VST00 (0) VST07 (0) AFC0 (0) AFCC (X) TDACE (0) VOW1E (0) MD0 (X) R/W R R R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W W

DATA CC1 DISPLAY (X) MEMORY

1996 Nov 29

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

ADDR 40H 41H 42H 43H 44H 45H Note

REG OSDCA LINE0A LINE0B OSDCB LINE1A LINE1B

BIT 7 CC34 (0) SZ01 (0) BLK0 (0) CDTV (0) SZ11 (0) BLK1 (0)

BIT 6 CC24 (0) SZ00 (0) VB0 (0) CDTH (0) SZ10 (0) VB1 (0)

BIT 5 CC14 (0) VP05 (0) HP05 (0) CC33 (0) VP15 (0) HP15 (0)

BIT 4 RBLK (0) VP04 (0) HP04 (0) CC23 (0) VP14 (0) HP14 (0)

BIT 3 ROUND (0) VP03 (0) HP03 (0) CC32 (0) VP13 (0) HP13 (0)

BIT 2 STBY (1) VP02 (0) HP02 (1) CC12 (1) VP12 (1) HP12 (1)

BIT 1 VLVL (0) VP01 (0) HP01 (0) CC21 (0) VP11 (0) HP11 (0)

BIT 0 HLVL (0) VP00 (0) HP00 (0) CCV11 (0) VP10 (0) HP10 (0)

R/W R/W R/W R/W R/W R/W R/W

1. These bits are not available in the PCA84C441, PCA84C444, PCA84C641, PCA84C644, PCA84C841 and PCA84C844. 15 LIMITING VALUES In accordance with the Absolute Maximum Rating System (IEC 134). SYMBOL VDD VI IOH IOL Ptot Tstg Tamb supply voltage input voltage (all inputs) maximum source current for all port lines maximum sink current for all port lines total power dissipation storage temperature operating ambient temperature (for all devices) PARAMETER MIN. -0.3 -0.3 - - - -55 -20 MAX. +7.0 -10 -30 900 +125 +70 V mA mA mW °C °C VDD + 0.3 V UNIT

1996 Nov 29

33

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

16 DC CHARACTERISTICS VDD = 4.5 to 5.5 V; VSS = 0 V; Tamb = -20 to +70 °C; all voltages with respect to VSS unless otherwise specified. SYMBOL Supply VDD IDD operating supply voltage operating supply current fOSDCRC = fOSDCLC = fXTAL; VDD = 5 V; see note 1; fXTAL = 10 MHz fXTAL = 6 MHz - - 5 3.5 10 8 mA mA 4.5 5.0 5.5 V PARAMETER CONDITIONS MIN. TYP. MAX. UNIT

fOSDCRC = fOSDCLC = STOP; - VDD = 5 V; see note 1; fXTAL = 10 MHz fXTAL = 6 MHz IDD(ID) supply current Idle mode VDD = 5 V; fXTAL = 10 MHz IDD(ST) Inputs IIH VIL VIH ILl HIGH level input current (pin RESET) VI = 0.5 V 20 - - - µA supply current Stop mode VDD = 5.5 V; see notes 1 and 2 - - 1.3 0.8 5 3 1.5 10 mA mA µA fXTAL = 6 MHz; see note 1 - - - 3 1.5 7 3.5 mA mA

PORTS P0, P1, DP0, DP1, HSYNCN AND VSYNCN LOW level input voltage HIGH level input voltage VSS < VI < VDD - ±0.01 - ±0.2 ±10 ±10 µA µA 0 0.3VDD V VDD V 0.7VDD -

PORTS P0, P1, DP0, DP1, INTN/T0 AND T1 input leakage current Ports P0, P1, DP0 and DP1 Ports INTN/T0 and T1 Outputs: Ports P0, P1, DP0, DP1; VOB and VOW3 (see Figs 30, 31 and 31) IOL LOW level output sink current Port P0 Ports P1, DP0 and DP1 Ports VOB and VOW3 PORTS P0, P1, DP0 AND DP1 (see Figs 33 and 33) IOH HIGH level pull-up output source current VO = VSS VO = 0.7VDD HIGH level push-pull output source current VO = VDD - 0.4 V OUTPUTS VOB AND VOW3 (see Fig.33) IOH HIGH level push-pull output source current VO = VDD - 0.4 V 1.2 3 - mA - 40 3 140 100 7 400 - - µA µA mA VO = 1.2 V VO = 0.4 V VO = 0.4 V 10 5 1.2 - 10 3 - - - mA mA mA

1996 Nov 29

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Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

SYMBOL

PARAMETER

CONDITIONS

MIN.

TYP. - -

MAX.

UNIT

AFC characteristics; Port DP1.7/AFC VAI VAE Notes 1. VIL = VSS; VIH = VDD; all outputs and sense input lines unloaded. All open drain ports connected to VSS. 2. Crystal is connected between XTAL1 and XTAL2; T1 = VSS; INT/T0 = VDD. 17 AC CHARACTERISTICS VDD = 5 V; Tamb = -20 to +70 °C; all voltages with respect to VSS; unless otherwise specified. SYMBOL Oscillator fXTAL fOSC-XTAL fOSC-PXE fOSC-XTAL fOSC-PXE fOSC-XTAL fOSC-PXE CXTAL1 crystal frequency; note 1 oscillator frequency; option 1 oscillator frequency; option 2 oscillator frequency; option 3 external capacitance at XTAL1 with XTAL resonator with PXE resonator CXTAL2 external capacitance at XTAL2 with XTAL resonator with PXE resonator fDOSC Note 1. Oscillator with three (3) options for optimum use. On Screen Display clock frequency - 4.0 not required 30 8.0 100 10.0 pF pF MHz - not required 30 100 pF pF gm = 0.4 mS (typ.) gm = 1.6 mS (typ.) gm = 4.5 mS (typ.) 1 1 4.0 1.0 3.0 - - - - - 10.0 6.0 10.0 6.0 10.0 MHz MHz MHz MHz MHz MHz MHz PARAMETER CONDITIONS MIN. TYP. MAX. UNIT comparator analog input voltage conversion error range VSS - VDD ± 0.5 V LSB

not allowed

not allowed

1996 Nov 29

35

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
17.1 Characteristic curves
MLC004

84C44X; 84C64X; 84C84X

handbook, halfpage

40 I OL (mA) 34

handbook, halfpage

10

MLB999

I OL (mA)

(1) (2)

8 (1) 6 (2) (3) 4

28

22

(3)

16 2

10

4 0 Port P0; VO = 1.2 V. (1) Tamb = -20 °C. (2) Tamb = 25 °C. (3) Tamb = 80 °C. 2 4 V DD (V) 6

0 0 2 4 V DD (V) 6

Ports P1, DP0 and DP1; VO = 0.4 V. (1) Tamb = -20 °C. (2) Tamb = 25 °C. (3) Tamb = 80 °C.

Fig.30 Typical LOW level output sink current as a function of the supply voltage.

Fig.31 Typical LOW level output sink current as a function of the supply voltage.

handbook, halfpage

10

MLC002

I OL (mA)

handbook, halfpage

200

MLC001

I OH (mA)

8 (1) 6 (2) (3) 4

160 (1) (2) 120 (3)

80

2

40

0 0 2 4 V DD (V) 6

0 0 2 4 V DD (V) 6

Outputs VOW1, VOW2, VOW3 and VOB; VO = 0.4 V. (1) Tamb = -20 °C. (2) Tamb = 25 °C. (3) Tamb = 80 °C.

Ports P0, P1, DP0 and DP1; VO = VSS. (1) Tamb = -20 °C. (2) Tamb = 25 °C. (3) Tamb = 80 °C.

Fig.32 Typical LOW level output sink current as a function of the supply voltage.

Fig.33 Typical HIGH level pull-up output source current as a function of the supply voltage.

1996 Nov 29

36

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST

84C44X; 84C64X; 84C84X

handbook, halfpage

200

MLC005

MLC003

I OH (mA)

handbook, halfpage

5

I OH (mA)

160 (1) 120 (2) (3) 80

4

(1) (2)

3

(3)

2

40

1

0 0 2 4 V DD (V) 6

0

0

2

4

V DD (V)

6

Ports P0, P1, DP0 and DP1; VO = 0.7VDD. (1) Tamb = -20 °C. (2) Tamb = 25 °C. (3) Tamb = 80 °C.

Outputs VOW1, VOW2, VOW3 and VOB; VO = VDD - 0.4 V. (1) Tamb = -20 °C. (2) Tamb = 25 °C. (3) Tamb = 80 °C.

Fig.34 Typical HIGH level pull-up output source current as a function of the supply voltage.

Fig.35 Typical HIGH level pull-up output source current as a function of the supply voltage.

1996 Nov 29

37

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
18 PACKAGE OUTLINE SDIP42: plastic shrink dual in-line package; 42 leads (600 mil)

84C44X; 84C64X; 84C84X

SOT270-1

seating plane

D

ME

A2

A

L

A1 c Z e b1 w M (e 1) MH b 42 22

pin 1 index E

1

21

0

5 scale

10 mm

DIMENSIONS (mm are the original dimensions) UNIT mm A max. 5.08 A1 min. 0.51 A2 max. 4.0 b 1.3 0.8 b1 0.53 0.40 c 0.32 0.23 D (1) 38.9 38.4 E (1) 14.0 13.7 e 1.778 e1 15.24 L 3.2 2.9 ME 15.80 15.24 MH 17.15 15.90 w 0.18 Z (1) max. 1.73

Note 1. Plastic or metal protrusions of 0.25 mm maximum per side are not included. OUTLINE VERSION SOT270-1 REFERENCES IEC JEDEC EIAJ EUROPEAN PROJECTION

ISSUE DATE 90-02-13 95-02-04

1996 Nov 29

38

Philips Semiconductors

Product specification

8-bit microcontrollers with OSD and VST
19 SOLDERING 19.1 Introduction

84C44X; 84C64X; 84C84X

The total contact time of successive solder waves must not exceed 5 seconds. The device may be mounted up to the seating plane, but the temperature of the plastic body must not exceed the specified maximum storage temperature (Tstg max). If the printed-circuit board has been pre-heated, forced cooling may be necessary immediately after soldering to keep the temperature within the permissible limit. 19.3 Repairing soldered joints

There is no soldering method that is ideal for all IC packages. Wave soldering is often preferred when through-hole and surface mounted components are mixed on one printed-circuit board. However, wave soldering is not always suitable for surface mounted ICs, or for printed-circuits with high population densities. In these situations reflow soldering is often used. This text gives a very brief insight to a complex technology. A more in-depth account of soldering ICs can be found in our "IC Package Databook" (order code 9398 652 90011). 19.2 Soldering by dipping or by wave

The maximum permissible temperature of the solder is 260 °C; solder at this temperature must not be in contact with the joint for more than 5 seconds. 20 DEFINITIONS Data sheet status Objective specification Preliminary specification Product specification Limiting values

Apply a low voltage soldering iron (less than 24 V) to the lead(s) of the package, below the seating plane or not more than 2 mm above it. If the temperature of the soldering iron bit is less than 300 °C it may remain in contact for up to 10 seconds. If the bit temperature is between 300 and 400 °C, contact may be up to 5 seconds.

This data sheet contains target or goal specifications for product development. This data sheet contains preliminary data; supplementary data may be published later. This data sheet contains final product specifications.

Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability. Application information Where application information is given, it is advisory and does not form part of the specification. 21 LIFE SUPPORT APPLICATIONS These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. Philips customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such improper use or sale. 22 PURCHASE OF PHILIPS I2C COMPONENTS

Purchase of Philips I2C components conveys a license under the Philips' I2C patent to use the components in the I2C system provided the system conforms to the I2C specification defined by Philips. This specification can be ordered using the code 9398 393 40011.

1996 Nov 29

39

Philips Semiconductors ­ a worldwide company
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For all other countries apply to: Philips Semiconductors, Marketing & Sales Communications, Building BE-p, P.O. Box 218, 5600 MD EINDHOVEN, The Netherlands, Fax. +31 40 27 24825 © Philips Electronics N.V. 1996

Internet: http://www.semiconductors.philips.com

SCA52

All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights.

Printed in The Netherlands

457021/1200/03/pp40

Date of release: 1996 Nov 29

Document order number:

9397 750 01542