MTV212A32_技术文档

MTV212A32

(Rev. 1.2)

MYSON

TECHNOLOGY

8051 Embedded Monitor Controller

Mask ROM Type

FEATURES

·

8051 core, 12MHz operating frequency.

512-byte RAM, 32K-byte program Mask-ROM.

Maximum 14 channels of 5V open-drain PWM DAC.

Maximum 31 bi-directional I/O pins.

SYNC processor for composite separation/insertion, H/V polarity/frequency check, polarity adjustment

and programmable clamp pulse output.

·

Built-in self-test pattern generator with four free-running timings.

Built-in low power reset circuit.

Compliant with VESA DDC1/2B/2Bi/2B+ standard.

Dual slave IIC addresses.

Single master IIC interface for internal device communication.

3-channel 6-bit ADC.

Watchdog timer with programmable interval.

40-pin DIP, 42-pin SDIP or 44-pin PLCC package.

GENERAL DESCRIPTIONS

The MTV212A32 micro-controller is an 8051 CPU core embedded device specially tailored to Monitor

applications. It includes an 8051 CPU core, 512-byte SRAM, SYNC processor, 14 built-in PWM DACs,

VESA DDC interface, 3-channel A/D converter and a 32K-byte internal program Mask-ROM.

BLOCK DIAGRAM

P0.0-7

RD

WR

ALE

INT1

P0.0-7

RD

WR

ALE

INT1

STOUT

HBLANK

VBLANK

HSYNC

VSYNC

HCLAMP

HALFV

HALFH

P1.0-7

XFR

ADC

P2.0-2,P2.4-7

P3.0-2

H/VSYNC

CONTROL

8051

CORE

P3.4-5

RST

X1

X2

AD0-2

14 CHANNEL

PWM DAC

ISCL

ISDA

HSCL

HSDA

DDC & IIC

INTERFACE

This datasheet contains new product information. Myson Technology reserves the rights to modify the product specification without

notice. No liability is assumed as a result of the use of this product. No rights under any patent accompany the sale of the product.

Revision 1.2

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MTV212A32

(Rev. 1.2)

MYSON

TECHNOLOGY

DEVICE SUMMARY

The MTV212A32 is one of the MTV212 family device. For other family devices information, please see the

table below:

Part Number

MTV212A16

MTV212A24

MTV212A32

MTV212A32U

MTV212A48U

MTV212A64U

USB

No

ROM

16K

24K

32K

48K

64K

RAM

256

512

768

1024

Package

PDIP40, SDIP42, PLCC44

No

Yes

The usage of Auxiliary RAM (AUXRAM) is limited for targeted mask ROM, the allowable XBANK (35h) bank

selection is defined as the table below:

Part Number

MTV212A16

MTV212A24

RAM

256

512

Xbnk2

Xbnk1

Xbnk0

-

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

MTV212A32

512

768

MTV212A32U

MTV212A48U

MTV212A64U

768

1024

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(Rev. 1.2)

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TECHNOLOGY

PIN CONNECTION

DA2/P5.2

DA1/P5.1

DA0/P5.0

RST

1

2

3

4

5

6

7

8

9

40 VSYNC

39 HSYNC

38 DA3/P5.3

37 DA4/P5.4

36 DA5/P5.5

35 DA8/HALFH

34 DA9/HALFV

33 HBLANK/P4.1

32 VBLANK/P4.0

31 DA7/HCLAMP

30 DA6/P5.6

29 P2.7/DA13

28 P2.6/DA12

27 P2.5/DA11

26 P2.4/DA10

25 HSCL/P3.0/Rxd

24 HSDA/P3.1/Txd

23 P2.0/AD0

22 P2.1/AD1

21 P1.7

VDD

VSS

X2

X1

MTV212A32

40 Pin

ISDA/P3.4/T0

ISCL/P3.5/T1 10

STOUT/P4.2 11

P2.2/AD2 12

P1.0 13

PDIP

P1.1 14

P3.2/INT0 15

P1.2 16

P1.3 17

P1.4 18

P1.5 19

P1.6 20

DA2/P5.2

DA1/P5.1

DA0/P5.0

NC

1

2

3

4

5

6

7

8

9

42 VSYNC

41 HSYNC

40 DA3/P5.3

39 DA4/P5.4

38 DA5/P5.5

37 DA8/HALFH

36 DA9/HALFV

35 HBLANK/P4.1

34 VBLANK/P4.0

33 DA7/HCLAMP

32 DA6/P5.6

31 P2.6/DA12

30 P2.5/DA11

29 P2.4/DA10

28 HSCL/P3.0/Rxd

27 HSDA/P3.1/Txd

26 P2.0/AD0

25 P2.1/AD1

24 P1.7

NC

RST

VDD

NC

7

8

9

39 DA8/HALFH

NC

38 DA9/HALFV

37 HBLANK/P4.1

36 VBLANK/P4.0

35 DA7/HCLAMP

34 DA6/P5.6

RST

MTV212A32

44 Pin

VDD

VSS 10

X2 11

MTV212A32

42 Pin

VSS

PLCC

X2 10

X1 11

X1 12

SDIP

ISDA/P3.4/T0 13

ISCL/P3.5/T1 14

STOUT/P4.2 15

P2.2/AD2 16

P1.0 17

33 P2.7/DA13

32 P2.6/DA12

31 P2.5/DA11

30 P2.4/DA10

29 HSCL/P3.0/Rxd

ISDA/P3.4/T0 12

ISCL/P3.5/T1 13

STOUT/P4.2 14

P2.2/AD2 15

P1.0 16

P1.1 17

P3.2/INT0 18

P1.2 19

P1.3 20

23 P1.6

P1.4 21

22 P1.5

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(Rev. 1.2)

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TECHNOLOGY

PIN DESCRIPTION

Name

DA2/P5.2

DA1/P5.1

DA0/P5.0

RST

VDD

VSS

X2

X1

Type

#

1

2

3

4

5

6

7

8

9

Description

PWM DAC output (5V open drain) / General purpose I/O (5V open drain).

I/O

I

-

O

I

I/O

Active high reset.

Positive Power Supply.

Ground.

Oscillator output.

Oscillator input.

Master IIC data (5V open drain) / General purpose I/O (8051 standard) / T0 (8051

ISDA/P3.4/T0

standard).

Master IIC clock (5V open drain) / General purpose I/O (8051 standard) / T1 (8051

standard).

ISCL/P3.5/T1

I/O

10

Self-test video output (CMOS) / General purpose Output (CMOS).

STOUT/P4.2

P2.2/AD2

P1.0

P1.1

P3.2/INT0

P1.2

P1.3

P1.4

P1.5

P1.6

O

11

12

13

14

15

16

17

18

19

20

21

22

23

24

General purpose I/O (Mask option as CMOS output or 8051 standard) / ADC Input.

General purpose I/O (Mask option as CMOS output or 8051 standard).

General purpose Input / INT0.

I/O

I

I/O

General purpose I/O (Mask option as CMOS output or 8051 standard).

General purpose I/O (Mask option as CMOS output or 8051 standard) / ADC Input.

P1.7

P2.1/AD1

P2.0/AD0

HSDA/P3.1/Txd

Slave IIC data (5V open drain) / General purpose I/O (8051 standard) / Txd (8051

standard).

Slave IIC clock (5V open drain) / General purpose I/O (8051 standard) / Rxd (8051

standard).

General purpose I/O (Mask option as CMOS output or 8051 standard) / PWM DAC

output (CMOS).

General purpose I/O (Mask option as CMOS output or 8051 standard) / PWM DAC

output (CMOS).

General purpose I/O (Mask option as CMOS output or 8051 standard) / PWM DAC

output (CMOS).

General purpose I/O (Mask option as CMOS output or 8051 standard) / PWM DAC

output (CMOS).

PWM DAC output (CMOS) / General purpose I/O (Mask option as CMOS output or

open drain I/O).

HSCL/P3.0/Rxd

P2.4/DA10

P2.5/DA11

P2.6/DA12

P2.7/DA13

DA6/P5.6

I/O

25

26

27

28

29

30

PWM DAC output (CMOS) / Hsync clamp pulse output (CMOS).

DA7/HCLAMP

VBLANK/P4.0

HBLANK/P4.1

DA9/HALFV

DA8/HALFH

DA5/P5.5

O

31

32

33

34

35

36

Vertical blank (CMOS) / General purpose Output (CMOS).

Horizontal blank (CMOS) / General purpose Output (CMOS).

PWM DAC output (5V open drain) / vsync half freq. output (5V open drain).

PWM DAC output (5V open drain) / hsync half freq. output (5V open drain).

PWM DAC output (CMOS) / General purpose I/O (Mask option as CMOS output or

open drain I/O).

I/O

PWM DAC output (CMOS) / General purpose I/O (Mask option as CMOS output or

open drain I/O).

PWM DAC output (CMOS) / General purpose I/O (Mask option as CMOS output or

open drain I/O).

DA4/P5.4

DA3/P5.3

I/O

37

38

Horizontal SYNC or Composite SYNC Input.

Vertical SYNC input.

HSYNC

VSYNC

I

39

40

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MTV212A32

(Rev. 1.2)

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TECHNOLOGY

PIN CONFIGURATION

A “CMOS output pin” means it can sink and drive at least 4mA current. It’s not recommended to use such pin

as input fuction.

A “5V open drain pin” means it can sink at least 4mA current but only drive 10~20uA to VDD. It can be used

as input or output function and need an external pull up resistor.

A “8051 standard pin” is a pseudo open drain pin. It can sink at least 4mA current when output low level, and

drive at least 4mA current for 160nS when output transit from low to high, then keep drive 100uA to maintain

the pin at high level. It can be used as input or output function. It need an external pull up resistor when drive

heavy load device.

FUNCTIONAL DESCRIPTIONS

1. 8051 CPU Core

MTV212A32 includes all 8051 functions with the following exceptions:

1.1 PSEN, ALE, RD and WR pins are disabled. The external RAM access is restricted to XFRs within the

MTV212A32.

1.2 Port0, port3.3, port3.6 and port3.7 are not general-purpose I/O ports. They are dedicated to monitor

special application.

1.3 INT1 input pin is not provided, it is connected to special interrupt sources.

1.4 Port2 are shared with special function pins.

In addition, there are 2 timers, 5 interrupt sources and serial interface compatible with the standard 8051.

Note: All registers listed in this document reside in external RAM area (XFR). For internal RAM memory map

please refer to 8051 spec.

2. Memory Allocation

2.1 Internal Special Function Registers (SFR)

The SFR is a group of registers that are the same as standard 8051.

2.2 Internal RAM

There are total 256 bytes internal RAM in MTV212A32, same as standard 8052.

2.3 External Special Function Registers (XFR)

The XFR is a group of registers allocated in the 8051 external RAM area 00h - 7Fh. Most of the registers are

used for monitor control or PWM DAC. Program can initialize Ri value and use "MOVX" instruction to access

these registers.

2.4 Auxiliary RAM (AUXRAM)

There are total 256 bytes auxiliary RAM allocated in the 8051 external RAM area 80h - FFh. The AUXRAM is

divided into two banks, selected by XBANK register. Program can initialize Ri value and use "MOVX"

instruction to access the AUXRAM.

Revision 1.2

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(Rev. 1.2)

MYSON

TECHNOLOGY

FFh

Internal RAM

SFR

AUXRAM

Accessible by

indirect

Accessible by

direct addressing

Accessible by

indirect external

Accessible by

indirect external

addressing only

(Using

RAM addressing

(XBANK=0)(Using (XBANK=1)(Using

RAM addressing

MOV A,@Ri

instruction)

MOVX A,@Ri

instruction)

MOVX A,@Ri

instruction)

80h

7Fh

80h

7Fh

Internal RAM

XFR

Accessible by

direct and indirect

addressing

Accessible by

indirect external

RAM addressing

(Using

MOVX A,@Ri

instruction

00h

3. Chip Configuration

The Chip Configuration registers define the chip pins function, as well as the functional blocks' connection,

configuration and frequency.

Reg name

PADMOD

OPTION

XBANK

addr

bit7

bit6

bit5

bit4

bit3

AD3E

P53E

bit2

AD2E

P52E

P42E

Msel

bit1

bit0

30h (w) DA13E DA12E DA11E DA10E

AD1E

P51E

P41E

MIICF1 MIICF0

SlvAbs1 SlvAbs0

AD0E

P50E

P40E

31h (w)

32h (w)

33h (w)

34h (w)

35h (r/w)

P56E

IIICE

P55E

P54E

HIICE

PWMF DIV253

HLFVE HLFHE HCLPE

FclkE IICpass ENSCL

Xbnk2

Xbnk1

Xbnk0

PADMOD (w) : Pad mode control registers. (All are "0" in Chip Reset)

DA13E = 1

= 0

DA12E = 1

= 0

DA11E = 1

= 0

DA10E = 1

= 0

® pin “P2.7/DA13” is DA13.

® pin “P2.7/DA13” is P2.7.

® pin “P2.6/DA12” is DA12.

® pin “P2.6/DA12” is P2.6.

® pin “P2.5/DA11” is DA11.

® pin “P2.5/DA11” is P2.5.

® pin “P2.4/DA10” is DA10.

® pin “P2.4/DA10” is P2.4.

® no action

AD3E = 1

= 0

® no action

AD2E = 1

= 0

AD1E = 1

= 0

AD0E = 1

= 0

P56E = 1

= 0

® pin “P2.2/AD2” is AD2.

® pin “P2.2/AD2” is P2.2.

® pin “P2.1/AD1” is AD1.

® pin “P2.1/AD1” is P2.1.

® pin “P2.0/AD0” is AD0.

® pin “P2.0/AD0” is P2.0.

® pin “DA6/P5.6” is P5.6.

® pin “DA6/P5.6” is DA6.

® pin “DA5/P5.5” is P5.5.

® pin “DA5/P5.5” is DA5.

P55E = 1

= 0

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TECHNOLOGY

P54E = 1

= 0

P53E = 1

= 0

P52E = 1

= 0

P51E = 1

= 0

P50E = 1

= 0

HIICE = 1

= 0

IIICE = 1

= 0

® pin “DA4/P5.4” is P5.4.

® pin “DA4/P5.4” is DA4.

® pin “DA3/P5.3” is P5.3.

® pin “DA3/P5.3” is DA3.

® pin “DA2/P5.2” is P5.2.

® pin “DA2/P5.2” is DA2.

® pin “DA1/P5.1” is P5.1.

® pin “DA1/P5.1” is DA1.

® pin “DA0/P5.0” is P5.0.

® pin “DA0/P5.0” is DA0.

® pin “HSCL/P3.0/Rxd” is HSCL;

® pin “HSCL/P3.0/Rxd” is P3.0/Rxd;

® pin “ISDA/P3.4/T0” is ISDA;

® pin “ISDA/P3.4/T0” is P3.4/T0;

pin “HSDA/P3.1/Txd” is HSDA.

pin “HSDA/P3.1/Txd” is P3.1/Txd.

pin “ISCL/P3.5/T1” is ISCL.

pin “ISCL/P3.5/T1” is P3.5/T1.

HLFVE = 1

= 0

® pin “DA9/HALFV” is VSYNC half frequency output.

® pin “DA9/HALFV” is DA9.

HLFHE = 1

= 0

® pin “DA8/HALFH” is HSYNC half frequency output.

® pin “DA8/HALFH” is DA8.

HCLPE = 1

= 0

® pin “DA7/HCLAMP” is HSYNC clamp pulse output.

® pin “DA7/HCLAMP” is DA7.

P42E = 1

= 0

® pin “STOUT/P4.2” is P4.2.

® pin “STOUT/P4.2” is STOUT.

P41E = 1

= 0

P40E = 1

= 0

® pin “HBLANK/P4.1” is P4.1.

® pin “HBLANK/P4.1” is HBLANK.

® pin “VBLANK/P4.0” is P4.0.

® pin “VBLANK/P4.0” is VBLANK.

OPTION (w) : Chip option configuration (All are "0" in Chip Reset).

PWMF = 1

= 0

® select 94KHz PWM frequency.

® select 47KHz PWM frequency.

DIV253 = 1

= 0

FclkE = 1

IICpass = 1

= 0

® PWM pulse width is 253 step resolution.

® PWM pulse width is 256 step resolution.

® Double CPU clock Freq.

® HSCL/HSDA pin bypass to ISCL/ISDA pin in DDC2 mode.

® Separate Master and Slave IIC block.

ENSCL = 1

® Enable slave IIC block to hold HSCL pin low while MTV212A32 can't catch-up

the external master's speed.

Msel

= 1

= 0

® Master IIC block connect to HSCL/HSDA pins.

® Master IIC block connect to ISCL/ISDA pins.

MIICF1,MIICF0 = 1,1 ® select 400KHz Master IIC frequency.

= 1,0 ® select 200KHz Master IIC frequency.

= 0,1 ® select 50KHz Master IIC frequency.

= 0,0 ® select 100KHz Master IIC frequency.

SlvAbs1,SlvAbs0 : Slave IIC block A's slave address length.

= 1,0 ® 5-bits slave address.

= 0,1 ® 6-bits slave address.

= 0,0 ® 7-bits slave address.

XBANK (r/w) : Auxiliary RAM bank switch.

Xbnk[2:0]

= 0

= 1

= 2

= 3

® Select AUXRAM bank 0.

® Select AUXRAM bank 1.

® Select AUXRAM bank 0.

® Select AUXRAM bank 1.

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= 4

= 5

® Select AUXRAM bank 0.

® Select AUXRAM bank 1.

4. Extra I/O

The extra I/O is a group of I/O pins located in XFR area. Port4 is output mode only. Port5 can be used as

both output and input, because Port5's pin is open drain type, user must write Port5's corresponding bit to

"1" in input mode.

Reg name

PORT4

PORT5

addr

38h (w)

39h (r/w)

bit7

bit6

bit5

bit4

bit3

bit2

P42

P52

bit1

P41

P51

bit0

P40

P50

P56

P55

P54

P53

PORT4 (w) :

Port 4 data output value.

PORT5 (r/w) : Port 5 data input/output value.

5. PWM DAC

Each PWM DAC converter's output pulse width is controlled by an 8-bit register in XFR. The frequency of

PWM clk is 47KHz or 94KHz, selected by PWMF. And the total duty cycle step of these DAC outputs is 253

or 256, selected by DIV253. If DIV253=1, writing FDH/FEH/FFH to DAC register generates stable high

output. If DIV253=0, the output will pulse low at least once even if the DAC register's content is FFH. Writing

00H to DAC register generates stable low output.

Reg name

DA0

addr

bit7

bit6

bit5

bit4

bit3

bit2

bit1

bit0

20h (r/w)

21h (r/w)

22h (r/w)

23h (r/w)

24h (r/w)

25h (r/w)

26h (r/w)

27h (r/w)

28h (r/w)

29h (r/w)

2Ah (r/w)

2Bh (r/w)

2Ch (r/w)

2Dh (r/w)

Pulse width of PWM DAC 0

Pulse width of PWM DAC 1

Pulse width of PWM DAC 2

Pulse width of PWM DAC 3

Pulse width of PWM DAC 4

Pulse width of PWM DAC 5

Pulse width of PWM DAC 6

Pulse width of PWM DAC 7

Pulse width of PWM DAC 8

Pulse width of PWM DAC 9

Pulse width of PWM DAC 10

Pulse width of PWM DAC 11

Pulse width of PWM DAC 12

Pulse width of PWM DAC 13

DA1

DA2

DA3

DA4

DA5

DA6

DA7

DA8

DA9

DA10

DA11

DA12

DA13

DA0-13 (r/w) : The output pulse width control for DA0-13.

* All of PWM DAC converters are centered with value 80h after power on.

6. H/V SYNC Processing

The H/V SYNC processing block performs the functions of composite signal separation/insertion, SYNC

inputs presence check, frequency counting, polarity detection and control, as well as the protection of

VBLANK output while VSYNC speed up in high DDC communication clock rate. The present and frequency

function block treat any pulse shorter than one OSC period as noise.

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Present

Digital Filter

Vpre

Check

Vfreq

Vpol

Polarity Check &

Freq. Count

Vbpl

VSYNC

XOR

CVSYNC

XOR

VBLANK

Vself

CVpre

Present

Check

Polarity Check &

Sync Seperator

Hpol

Digital Filter

Hpre

Present Check &

Freq. Count

Hfreq

Hbpl

Composite

Pulse Insert

XOR

Hself

HSYNC

XOR

HBLANK

H/V SYNC Processor Block Diagram

6.1 Composite SYNC separation/insertion

The MTV212A32 continuously monitors the input HSYNC, if the vertical SYNC pulse can be extracted from

the input, a CVpre flag is set and user can select the extracted "CVSYNC" for the source of polarity check,

frequency count, and VBLANK output. The CVSYNC will have 8us delay compared to the original signal.

The MTV212A32 can also insert pulse to HBLANK output during composite VSYNC’s active time. The insert

pulse’s width is 1/8 HSYNC period and the insertion frequency can adapt to original HSYNC.

6.2 H/V Frequency Counter

MTV212A32 can discriminate HSYNC/VSYNC frequency and saves the information in XFRs. The 14 bits

Hcounter counts the time of 64xHSYNC period, then load the result into the HCNTH/HCNTL latch. The

output value will be [(128000000/H-Freq) - 1], updated once per VSYNC/CVSYNC period when

VSYNC/CVSYNC is present or continuously updated when VSYNC/CVSYNC is non-present. The 12 bits

Vcounter counts the time between two VSYNC pulses, then load the result into the VCNTH/VCNTL latch.

The output value will be (62500/V-Freq), updated every VSYNC/CVSYNC period. An extra overflow bit

indicates the condition of H/V counter overflow. The VFchg/HFchg interrupt is set when VCNT/HCNT value

changes or overflow. Table 4.2.1 and table 4.2.2 shows the HCNT/VCNT value under the operations of

12MHz.

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6.2.1 H-Freq Table

H-Freq(KHZ)

Output Value (14 bits)

12MHz OSC (hex / dec)

0FDEh / 4062

0D54h / 3412

0B8Bh / 2955

0AA8h / 2728

094Fh / 2383

0854h / 2132

0746h / 1862

06AAh / 1706

063Fh / 1599

05D1h / 1489

0554h / 1364

04B3h / 1203

1

31.5

37.5

43.3

46.9

53.7

60.0

68.7

75.0

80.0

85.9

93.8

106.3

2

3

4

5

6

7

8

9

10

11

12

6.2.2 V-Freq Table

Output value (12bits)

12MHz OSC (hex / dec)

45Ch / 1116

V-Freq(Hz)

1

2

3

4

5

6

56

60

70

72

75

85

411h / 1041

37Ch / 892

364h / 868

341h / 833

2DFh / 735

6.3 H/V Present Check

The Hpresent function checks the input HSYNC pulse, Hpre flag is set when HSYNC is over 10KHz or

cleared when HSYNC is under 10Hz. The Vpresent function checks the input VSYNC pulse, the Vpre flag is

set when VSYNC is over 40Hz or cleared when VSYNC is under 10Hz. The HPRchg interrupt is set when

the Hpre value changes. The VPRchg interrupt is set when the Vpre/CVpre value change. However, the

CVpre flag interrupt may be disabled when S/W disable the composite function.

6.4 H/V Polarity Detect

The polarity functions detect the input HSYNC/VSYNC high and low pulse duty cycle. If the high pulse

duration is longer than that of low pulse, the negative polarity is asserted; otherwise, positive polarity is

asserted. The HPLchg interrupt is set when the Hpol value changes. The VPLchg interrupt is set when the

Vpol value changes.

6.5 Output HBLANK/VBLANK Control and Polarity Adjust

The HBLANK is the mux output of HSYNC, composite Hpulse and self-test horizontal pattern. The VBLANK

is the mux output of VSYNC, CVSYNC and self-test vertical pattern. The mux selection and output polarity

are S/W controllable. The VBLANK output is cut off when VSYNC frequency is over 200Hz. The

HBLANK/VBLANK shares the output pin with P4.1/ P4.0.

6.6 Self Test Pattern Generator

This generator can generate 4 display patterns for testing purpose, which are positive cross-hatch, negative

cross-hatch, full white, and full black (showed as following figure). The HBLANK output frequency of the

pattern can be chosen to 95.2KHz, 63.5KHz, 47.6KHz and 31.75KHz. The VBLANK output frequency of the

pattern is 72Hz or 60Hz. It is originally designed to support monitor manufacturer to do burn-in test, or offer

end-user a reference to check the monitor. The generator's output STOUT shares the output pin with P4.2.

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Display Region

Positive cross-hatch

Negative cross-hatch

Full white

Full black

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MTV212A32 Self-Test pattern timing

63.5KHz, 60Hz 47.6KHz, 60Hz 31.7KHz, 60Hz

95.2KHz, 72Hz

time

H dots

1280

979.3

16.25

122

time

21.0us

16.07us

0.28us

2us

H dots

1024

783.2

12

time

31.5us

24.05us

0.45us

3us

H dots

640

488.6

9

time

H dots

1600

1224

21

Hor. Total time (A)

Hor. Active time (D)

Hor. F. P. (E)

15.75us

12.05us

0.2us

10.5us

8.03us

0.14us

1.0us

SYNC pulse width (B) 1.5us

90

61

152

Hor. B. P. (C)

2us

162.54

2.67us

110

4us

81.27

1.33us

203

time

16.66ms

Vert. Active time (R) 15.65ms

Vert. F. P. (S) 0.063ms

SYNC pulse width (P) 0.063ms

Vert. B. P. (Q) 0.882ms

V lines

1024

962

3.87

54.2

time

V lines

768

721.5

2.9

40.5

time

V lines

480

451

1.82

25.4

time

V lines

1200

1126

4.5

65

Vert. Total time (O)

16.66ms

15.65ms

0.063ms

0.882ms

16.66ms

15.65ms

0.063ms

0.882ms

13.89ms

13.03ms

0.052ms

0.756ms

* 8 x 8 blocks of cross hatch pattern in display region.

6.7 HSYNC Clamp Pulse Output

The HCLAMP output is active by setting “HCLPE” control bit. The HCLAMP’s leading edge position, pulse

width and polarity is S/W controllable.

6.8 VSYNC Interrupt

The MTV212A32 check the VSYNC input pulse and generate an interrupt at its leading edge. The VSYNC

flag is set each time when MTV212A32 detects a VSYNC pulse. The flag is cleared by S/W writing a "0".

6.9 H/V SYNC Processor Register

Reg name

HVSTUS

HCNTH

HCNTL

addr

bit7

CVpre

Hovf

HF7

bit6

bit5

Hpol

HF13

HF5

bit4

Vpol

HF12

HF4

bit3

Hpre

HF11

HF3

bit2

Vpre

HF10

HF2

bit1

Hoff

HF9

HF1

VF9

bit0

Voff

HF8

HF0

VF8

40h (r)

41h (r)

42h (r)

43h (r)

HF6

VCNTH

Vovf

VF11

VF10

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VCNTL

HVCTR0

HVCTR2

HVCTR3

INTFLG

INTEN

44h (r)

40h (w)

42h (w)

43h (w)

VF7

C1

VF6

C0

VF5

NoHins

Selft

VF4

VF3

VF2

Rt1

VF1

HBpl

Rt0

VF0

VBpl

STE

STF1

STF0

CLPEG CLPPO CLPW2 CLPW1 CLPW0

48h (r/w) HPRchg VPRchg HPLchg VPLchg HFchg

49h (w) EHPR EVPR EHPL EVPL EHF

VFchg

EVF

Vsync

EVsync

HVSTUS (r) : The status of polarity, present and static level for HSYNC and VSYNC.

CVpre = 1

= 0

® The extracted CVSYNC is present.

® The extracted CVSYNC is not present.

® HSYNC input is positive polarity.

® HSYNC input is negative polarity.

® VSYNC (CVSYNC) is positive polarity.

® VSYNC (CVSYNC) is negative polarity.

® HSYNC input is present.

® HSYNC input is not present.

® VSYNC input is present.

® VSYNC input is not present.

H

= 1

= 0

= 1

= 0

= 1

= 0

= 1

= 0

= 1

= 0

= 1

= 0

pol

V

pol

H

pre

V

pre

H

® HSYNC input's off level is high.

® HSYNC input's off level is low.

® VSYNC input's off level is high.

® VSYNC input's off level is low.

off*

V

off*

*H and V are valid when H

or V

off off pre=0

pre=0.

HCNTH (r) :

Hovf

HF13 - HF8 : 6 high bits of H-Freq counter.

H-Freq counter's high bits.

= 1 ® H-Freq counter is overflow, this bit is clear by H/W when condition removed.

HCNTL (r) :

H-Freq counter's low byte.

VCNTH (r) :

V-Freq counter's high bits.

Vovf

VF11 - 8 :

= 1

® V-Freq counter is overflow, this bit is clear by H/W when condition removed.

4 high bits of V-Freq counter.

VCNTL (r) :

V-Freq counter's low byte.

HVCTR0 (w) : H/V SYNC processor control register 0.

C1, C0 = 1,1 ® Select CVSYNC as the polarity, freq and VBLANK source.

= 1,0 ® Select VSYNC as the polarity, freq and VBLANK source.

= 0,0 ® Disable composite function.

= 0,1 ® H/W auto switch to CVSYNC when CVpre=1 and VSpre=0.

NoHins = 1

= 0

® HBLANK has no insert pulse in composite mode.

® HBLANK has insert pulse in composite mode.

® negative polarity HBLANK output.

® positive polarity HBLANK output.

® negative polarity VBLANK output.

HB

= 1

= 0

= 1

= 0

pl

VB

pl

® positive polarity VBLANK output.

HVCTR2 (w) : Self-test pattern generator control.

S

elft

= 1

= 0

® enable generator.

® disable generator.

STF1,STF0

= 1,1 ® 95.2KHz(horizontal)/72Hz(vertical) output selected.

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= 1,0 ® 63.5KHz(horizontal)/60Hz(vertical) output selected.

= 0,1 ® 47.6KHz(horizontal) /60Hz(vertical) output selected.

= 0,0 ® 31.75KHz(horizontal) /60Hz(vertical) output selected.

Rt1, Rt0= 0,0 ® positive cross-hatch pattern output.

= 0,1 ® negative cross-hatch pattern output.

= 1,0 ® full white pattern output.

= 1,1 ® full black pattern output.

STE

= 1

= 0

® enable STOUT output.

® disable STOUT output.

HVCTR3 (w) : HSYNC clamp pulse control register.

CLPEG = 1

= 0

CLPPO = 1

= 0

® Clamp pulse follows HSYNC leading edge.

® Clamp pulse follows HSYNC trailing edge.

® Positive polarity clamp pulse output.

® Negative polarity clamp pulse output.

CLPW2 : CLPW0 : Pulse width of clamp pulse is

[(CLPW2:CLPW0) + 1] x 0.167 ms for 12MHz X’tal selection.

INTFLG (w) : Interrupt flag. An interrupt event will set its individual flag, and, if the corresponding interrupt

enable bit is set, the 8051 core's INT1 source will be driven by a zero level. Software MUST

clear this register while serve the interrupt routine.

HPRchg= 1

= 0

VPRchg= 1

= 0

HPLchg= 1

= 0

VPLchg= 1

= 0

HFchg = 1

= 0

VFchg = 1

= 0

Vsync = 1

= 0

® No action.

® Clear HSYNC presence change flag.

® No action.

® Clear VSYNC presence change flag.

® No action.

® Clear HSYNC polarity change flag.

® No action.

® Clear VSYNC polarity change flag.

® No action.

® Clear HSYNC frequency change flag.

® No action.

® Clear VSYNC frequency change flag.

® No action.

® Clear VSYNC interrupt flag.

INTFLG (r) :

Interrupt flag.

HPRchg= 1

VPRchg= 1

HPLchg= 1

VPLchg= 1

HFchg = 1

VFchg = 1

Vsync = 1

® Indicates a HSYNC presence change.

® Indicates a VSYNC presence change.

® Indicates a HSYNC polarity change.

® Indicates a VSYNC polarity change.

® Indicates a HSYNC frequency change or counter overflow.

® Indicates a VSYNC frequency change or counter overflow.

® Indicates a VSYNC interrupt.

INTEN (w) :

Interrupt enable.

EHPR = 1

EVPR = 1

EHPL = 1

EVPL = 1

® Enable HSYNC presence change interrupt.

® Enable VSYNC presence change interrupt.

® Enable HSYNC polarity change interrupt.

® Enable VSYNC polarity change interrupt.

EHF

EVF

EVsync = 1

= 1

® Enable HSYNC frequency change / counter overflow interrupt.

® Enable VSYNC frequency change / counter overflow interrupt.

® Enable VSYNC interrupt.

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7. DDC & IIC Interface

7.1 DDC1 Mode

The MTV212A32 enters DDC1 mode after Reset. In this mode, VSYNC is used as data clock. The HSCL pin

should remain at high. The data output to the HSDA pin is taken from a shift register in MTV212A32. The

shift register fetch data byte from the DDC1 data buffer (DBUF) then send it in 9 bits packet formats which

includes a null bit (=1) as packet separator. The DBUF set the DbufI interrupt flag when the shift register

read out the data byte from DBUF. Software needs to write EDID data to DBUF as soon as the DbufI is set.

The DbufI interrupt is automatically cleared when Software writes a new data byte to DBUF. The DbufI

interrupt can be mask or enable by EDbufI control bit.

7.2 DDC2B Mode

The MTV212A32 switches to DDC2B mode when it detects a high to low transition on the HSCL pin. Once

MTV212A32 enters DDC2B mode, S/W can set IICpass control bit to allow HOST access EEPROM directly.

Under such condition, the HSDA and HSCL are directly bypassed to ISDA and ISCL pins. The other way to

perform DDC2 function is to clear IICpass and config the Slave A IIC block to act as EEPROM behavior. The

Slave A block's slave address can be chosen by S/W as 5-bits, 6-bits or 7-bits. For example, if S/W choose

5-bits slave address as 10100b, the slave IIC block A will respond to slave address 10100xxb and save the 2

LSB "xx" in XFR. This feature enables MTV212A32 to meet PC99 requirement.

The MTV212A32 will return to DDC1 mode if HSCL is kept high for 128 VSYNC clock period. However, it will

lock in DDC2B mode if a valid IIC address (1010xxxb) has been detected on HSCL/HSDA bus. The DDC2

flag reflects the current DDC status, S/W may clear it by writing a "0" to it.

7.3 Slave Mode IIC function Block

The slave mode IIC block is connected to HSDA and HSCL pins. This block can receive/transmit data using

IIC protocol. There are 2 slave addresses MTV212A32 can respond to. S/W may write the

SLVAADR/SLVBADR register to determine the slave addresses. The SlaveA address can be configured to

5-bits, 6-bits or 7-bits by S/W setting the SlvAbs1 and SlvAbs0 control bits.

In receive mode, the block first detects IIC slave address match condition then issues a SlvAMI/SlvBMI

interrupt. If the matched address is slave A, MTV212A32 will save the matched address's 2 LSB bits to

SlvAlsb1 and SlvAlsb0 register. The data from HSDA is shifted into shift register then written to

RCABUF/RCBBUF register when a data byte is received. The first byte loaded is word address (slave

address is dropped). This block also generates a RCAI/RCBI (receive buffer full interrupt) every time when

the RCABUF/RCBBUF is loaded. If S/W can't read out the RCABUF/RCBBUF in time, the next byte in shift

register will not be written to RCABUF/RCBBUF and the slave block return NACK to the master. This feature

guarantees the data integrity of communication. The WadrA/WadrB flag can tell S/W that if the data in

RCABUF/RCBBUF is a word address.

In transmit mode, the block first detects IIC slave address match condition then issues a SlvAMI/SlvBMI

interrupt. In the mean time, the SlvAlsb1/SlvAlsb0 is also updated if the matched address is slave A, and the

data pre-stored in the TXABUF/TXBBUF is loaded into shift register, result in TXABUF/TXBBUF empty and

generates a TXAI/TXBI (transmit buffer empty interrupt). S/W should write the TXABUF/TXBBUF a new byte

for next transfer before shift register empty. Fail to do this will cause data corrupt. The TXAI/TXBI occurs

every time when shift register reads out the data from TXABUF/TXBBUF.

The SlvAMI/SlvBMI is cleared by writing "0" to corresponding bit in INTFLG register. The RCAI/RCBI is

cleared by reading RCABUF/RCBBUF. The TXAI/TXBI is cleared by writing TXABUF/TXBBUF. If the control

bit ENSCL is set, the block will hold HSCL low until the RCAI/RCBI/TXAI/TXBI is cleared.

*Please see the attachments about "Slave IIC Block Timing".

7.4 Master Mode IIC Function Block

The master mode IIC block can be connected to the ISDA /ISCL pins or the HSDA/HSCL pins, select by

Msel control bit. Its speed can be selected to 50KHz-400KHz by S/W setting the MIICF1/MIICF0 control bit.

The software program can access the external IIC device through this interface. Since the EDID/VDIF data

and the display information share the common EEPROM, precaution must be taken to avoid bus conflicting

while Msel=0. In DDC1 mode or IICpass=0, the ISCL/ISDA is controlled by MTV212A32 only. In DDC2 mode

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and IICpass flag is set, the host may access the EEPROM directly. Software can test the HSCL condition by

reading the Hbusy flag, which is set in case of HSCL=0, and keeps high for 100uS after the HSCL's rising

edge. S/W can launch the master IIC transmit/receive by clearing the P bit. Once P=0, MTV212A32 will hold

HSCL low to isolate the host's access to EEPROM. A summary of master IIC access is illustrated as follows.

7.4.1. To write IIC Device

1. Write MBUF the Slave Address.

2. Set S bit to Start.

3. After the MTV212A32 transmit this byte, a MbufI interrupt will be triggered.

4. Program can write MBUF to transfer next byte or set P bit to stop.

* Please see the attachments about "Master IIC Transmit Timing".

7.4.2. To read IIC Device

1. Write MBUF the Slave Address.

2. Set S bit to Start.

3. After the MTV212A32 transmit this byte, a MbufI interrupt will be triggered.

4. Set or reset the MAckO flag according to the IIC protocol.

5. Read out MBUF the useless byte to continue the data transfer.

6. After the MTV212A32 receives a new byte, the MbufI interrupt is triggered again.

7. Read MBUF also trigger the next receive operation, but set P bit before read can terminate the operation.

* Please see the attachments about "Master IIC Receive Timing".

Reg name

IICCTR

addr

00h (r/w) DDC2

01h (r)

02h (r)

03h (r)

03h (w)

04h (w)

05h (r/w)

06h (r)

06h (w)

07h (w) ENSlvA

08h (r)

bit7

bit6

bit5

bit4

bit3

SLVS

RCAI

bit2

MAckO

bit1

P

bit0

S

IICSTUS

INTFLG

INTEN

WadrB WadrA SlvRWB SAckIn

MAckIn Hifreq

TXBI RCBI

SlvAlsb1 SlvAlsb0

Hbusy

SlvBMI

TXAI

SlvAMI

DbufI

MbufI

ETXBI ERCBI ESlvBMI ETXAI ERCAI ESlvAMI EDbufI EMbufI

Master IIC receive/transmit data buffer

Slave A IIC receive buffer

MBUF

RCABUF

TXABUF

SLVAADR

RCBBUF

TXBBUF

SLVBADR

DBUF

Slave A IIC transmit buffer

Slave A IIC address

Slave B IIC receive buffer

Slave B IIC transmit buffer

Slave B IIC address

08h (w)

09h (w) ENSlvB

0Ah (w)

DDC1 transmit data buffer

IICCTR (r/w) : IIC interface control register.

DDC2 = 1

= 0

® MTV212A32 is in DDC2 mode, write "0" can clear it.

® MTV212A32 is in DDC1 mode.

MAckO = 1

= 0

® In master receive mode, NACK is returned by MTV212A32.

® In master receive mode, ACK is returned by MTV212A32.

S, P

= • , 0 ® Start condition when Master IIC is not during transfer.

= X, • ® Stop condition when Master IIC is not during transfer.

= 1, X ® Will resume transfer after a read/write MBUF operation.

= X, 0 ® Force HSCL low and occupy the master IIC bus.

* A write/read MBUF operation can be recognized only after 10us of the MbufI flag's rising edge.

IICSTUS (r) : IIC interface status register.

WadrB = 1

WadrA = 1

SlvRWB = 1

® The data in RCBBUF is word address.

® The data in RCABUF is word address.

® Current transfer is slave transmit

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= 0

SAckIn = 1

SLVS = 1

® Current transfer is slave receive

® The external IIC host respond NACK.

® The slave block has detected a START, cleared when STOP detected.

SlvAlsb1,SlvAlsb0 : The 2 LSB which host send to Slave A block.

MAckIn = 1

= 0

® Master IIC bus error, no ACK received from the slave IIC device.

® ACK received from the slave IIC device.

Hifreq = 1

Hbusy = 1

® MTV212A32 has detected a higher than 200Hz clock on the VSYNC pin.

® Host drives the HSCL pin to low.

INTFLG (w) : Interrupt flag. A interrupt event will set its individual flag, and, if the corresponding interrupt

enable bit is set, the 8051 INT1 source will be driven by a zero level. Software MUST clear

this register while serve the interrupt routine.

SlvBMI = 1

= 0

SlvAMI = 1

= 0

MbufI = 1

= 0

® No action.

® Clear SlvBMI flag.

® No action.

® Clear SlvAMI flag.

® No action.

® Clear Master IIC bus interrupt flag (MbufI).

INTFLG (r) :

Interrupt flag.

TXBI = 1

RCBI = 1

SlvBMI = 1

TXAI = 1

RCAI = 1

SlvAMI = 1

DbufI = 1

MbufI = 1

® Indicates the TXBBUF need a new data byte, clear by writing TXBBUF.

® Indicates the RCBBUF has received a new data byte, clear by reading RCBBUF.

® Indicates the slave IIC address B match condition.

® Indicates the TXABUF need a new data byte, clear by writing TXABUF.

® Indicates the RCABUF has received a new data byte, clear by reading RCABUF.

® Indicates the slave IIC address A match condition.

® Indicates the DDC1 data buffer need a new data byte, clear by writing DBUF.

® Indicates a byte is sent/received to/from the master IIC bus.

INTEN (w) :

Interrupt enable.

ETXBI = 1

ERCBI = 1

ESlvBMI = 1

ETXAI = 1

ERCAI = 1

ESlvAMI = 1

EDbufI = 1

EMbufI = 1

® Enable TXBBUF interrupt.

® Enable RCBBUF interrupt.

® Enable slave address B match interrupt.

® Enable TXABUF interrupt.

® Enable RCABUF interrupt.

® Enable slave address A match interrupt.

® Enable DDC1 data buffer interrupt.

® Enable Master IIC bus interrupt.

Mbuf (w) :

Mbuf (r) :

Master IIC data shift register, after START and before STOP condition, write this register will

resume MTV212A32's transmission to the IIC bus.

Master IIC data shift register, after START and before STOP condition, read this register will

resume MTV212A32's receiving from the IIC bus.

RCABUF (r) : Slave IIC block A receive data buffer.

TXABUF (w) : Slave IIC block A transmit data buffer.

SLVAADR (w) :Slave IIC block A's enable and address.

ENslvA = 1

= 0

® Enable slave IIC block A.

® Disable slave IIC block A.

bit6-0 :

Slave IIC address A to which the slave block should respond.

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RCBBUF (r) : Slave IIC block B receive data buffer.

TXBBUF (w) : Slave IIC block B transmit data buffer.

SLVBADR (w) :Slave IIC block B's enable and address.

ENslvB = 1

= 0

® Enable slave IIC block B.

® Disable slave IIC block B.

bit6-0 :

Slave IIC address B to which the slave block should respond.

8. Low Power Reset (LVR) & Watchdog Timer

When the voltage level of power supply is below 4.0V for a specific time, the LVR will generate a chip reset

signal. After the power supply is above 4.0V, LVR maintain in reset state for 144 Xtal cycle to guarantee the

chip exit reset condition with a stable X'tal oscillation.

The WatchDog Timer automatically generates a device reset when it is overflow. The interval of overflow is

0.25 sec x N, where N is a number from 1 to 8, and can be programmed via register WDT(2:0). The timer

function is disabled after power on reset, user can activate this function by setting WEN, and clear the timer

by set WCLR.

9. A/D converter

The MTV212A32 is equipped with three 6-bit A/D converters, S/W can select the current convert channel

by setting the SADC1/SADC0 bit. The refresh rate for the ADC is OSC freq./12288. The ADC compare the

input pin voltage with internal VDD*N/64 voltage (where N = 0 - 63). The ADC output value is N when pin

voltage is greater than VDD*N/64 and smaller than VDD*(N+1)/64.

Reg name

ADC

addr

10h (w) ENADC

10h (r)

bit7

bit6

bit5

bit4

bit3

bit2

bit1

bit0

SADC3 SADC2 SADC1 SADC0

ADC convert Result

ADC

WDT

18h (w)

WEN

WCLR

WDT2

WDT1

WDT0

WDT (w) :

WEN

Watchdog Timer control register.

= 1

® Enable WatchDog Timer.

® Clear WatchDog Timer.

WCLR

WDT2: WDT0 = 0

® overflow interval = 8 x 0.25 sec.

® overflow interval = 1 x 0.25 sec.

® overflow interval = 2 x 0.25 sec.

® overflow interval = 3 x 0.25 sec.

® overflow interval = 4 x 0.25 sec.

® overflow interval = 5 x 0.25 sec.

® overflow interval = 6 x 0.25 sec.

® overflow interval = 7 x 0.25 sec.

= 1

= 2

= 3

= 4

= 5

= 6

= 7

ADC (w) :

ADC control.

ENADC

SADC0

SADC1

SADC2

SADC3

= 1

® Enable ADC.

® Select ADC0 pin input.

® Select ADC1 pin input.

® Select ADC2 pin input.

® no action.

ADC (r) :

ADC convert result.

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Memory Map of XFR

Reg name

IICCTR

IICSTUS

INTFLG

INTEN

MBUF

RCABUF

TXABUF

SLVAADR

RCBBUF

TXBBUF

SLVBADR

DBUF

addr

00h (r/w) DDC2

01h (r)

02h (r)

03h (r)

03h (w)

04h (w)

05h (r/w)

06h (r)

06h (w)

07h (w) ENSlvA

08h (r)

bit7

bit6

bit5

bit4

bit3

SLVS

RCAI

bit2

MAckO

bit1

P

bit0

S

WadrB WadrA SlvRWB SAckIn

MAckIn Hifreq

TXBI RCBI

SlvAlsb1 SlvAlsb0

Hbusy

SlvBMI

TXAI

SlvAMI

DbufI

MbufI

ETXBI ERCBI ESlvBMI ETXAI ERCAI ESlvAMI EDbufI EMbufI

Master IIC receive/transmit data buffer

Slave A IIC receive buffer

Slave A IIC transmit buffer

Slave A IIC address

Slave B IIC receive buffer

Slave B IIC transmit buffer

Slave B IIC address

08h (w)

09h (w) ENSlvB

0Ah (w)

DDC1 transmit data buffer

ADC

WDT

DA0

DA1

DA2

DA3

DA4

DA5

DA6

DA7

DA8

DA9

DA10

DA11

DA12

10h (w) ENADC

10h (r)

SADC3 SADC2 SADC1 SADC0

ADC convert Result

WDT2

18h (w)

20h (r/w)

21h (r/w)

22h (r/w)

23h (r/w)

24h (r/w)

25h (r/w)

26h (r/w)

27h (r/w)

28h (r/w)

29h (r/w)

2Ah (r/w)

2Bh (r/w)

2Ch (r/w)

2Dh (r/w)

WEN

WCLR

WDT1

WDT0

Pulse width of PWM DAC 0

Pulse width of PWM DAC 1

Pulse width of PWM DAC 2

Pulse width of PWM DAC 3

Pulse width of PWM DAC 4

Pulse width of PWM DAC 5

Pulse width of PWM DAC 6

Pulse width of PWM DAC 7

Pulse width of PWM DAC 8

Pulse width of PWM DAC 9

Pulse width of PWM DAC 10

Pulse width of PWM DAC 11

Pulse width of PWM DAC 12

Pulse width of PWM DAC 13

DA13

PADMOD

OPTION

XBANK

PORT4

PORT5

HVSTUS

HCNTH

HCNTL

VCNTH

VCNTL

HVCTR0

HVCTR2

HVCTR3

INTFLG

INTEN

30h (w) DA13E DA12E DA11E DA10E

AD3E

P53E

AD2E

P52E

P42E

Msel

AD1E

P51E

P41E

MIICF1 MIICF0

SlvAbs1 SlvAbs0

Xbnk1

P41

P51

Hoff

HF9

HF1

VF9

VF1

HBpl

Rt0

AD0E

P50E

P40E

31h (w)

32h (w)

33h (w)

34h (w)

35h (r/w)

38h (w)

39h (r/w)

40h (r)

41h (r)

42h (r)

43h (r)

44h (r)

P56E

IIICE

PWMF DIV253

P55E

P54E

HIICE

HLFVE HLFHE HCLPE

FclkE IICpass ENSCL

Xbnk2

P42

P52

Vpre

HF10

HF2

VF10

VF2

Xbnk0

P40

P50

P56

CVpre

P55

Hpol

HF13

HF5

P54

Vpol

HF12

HF4

P53

Hpre

HF11

HF3

VF11

VF3

Voff

Hovf

HF8

HF0

VF8

VF0

VBpl

STE

HF7

Vovf

VF7

C1

HF6

VF6

C0

VF5

NoHins

Selft

VF4

40h (w)

42h (w)

43h (w)

STF1

STF0

Rt1

CLPEG CLPPO CLPW2 CLPW1 CLPW0

48h (r/w) HPRchg VPRchg HPLchg VPLchg HFchg

49h (w) EHPR EVPR EHPL EVPL EHF

VFchg

EVF

Vsync

EVsync

Revision 1.2

- 19 -

2000/07/04

MTV212A32

(Rev. 1.2)

MYSON

TECHNOLOGY

ELECTRICAL PARAMETERS

1. Absolute Maximum Ratings

o

at: Ta= 0 to 70 C, VSS=0V

Name

Symbol

VDD

Vin

Vout

Topg

Range

-0.3 to +6.0

-0.3 to VDD+0.3

0 to +70

Unit

V

Maximum Supply Voltage

Maximum Input Voltage

Maximum Output Voltage

Maximum Operating Temperature

V

o

C

Maximum Storage Temperature

Tstg

-25 to +125

o

C

2. Allowable Operating Conditions

o

at: Ta= 0 to 70 C, VSS=0V

Name

Supply Voltage

Input "H" Voltage

Input "L" Voltage

Operating Freq.

Symbol

VDD

Vih1

Vil1

Fopg

Min.

4.5

0.4 x VDD

Max.

Unit

V

MHz

5.5

VDD +0.3

0.2 x VDD

15

-0.3

-

3. DC Characteristics

o

at: Ta=0 to 70 C, VDD=5.0V, VSS=0V

Name

Symbol

Voh1 Ioh=0uA

Voh2 Ioh=-50uA

Voh3 Ioh=-4mA

Vol

Condition

Min.

Typ.

Max.

Unit

V

mA

uA

Kohm

pF

Output "H" Voltage, open drain pin

Output "H" Voltage, 8051 I/O port pin

Output "H" Voltage, CMOS output

Output "L" Voltage

4

Iol=5mA

Active

0.45

24

4.0

80

250

15

18

1.3

50

Power Supply Current

Idd

Idle

Power-Down

RST Pull-Down Resistor

Pin Capacitance

Rrst VDD=5V

Cio

150

4. AC Characteristics

o

at: Ta=0 to 70 C, VDD=5.0V, VSS=0V

Name

Crystal Frequency

PWM DAC Frequency

HS input pulse Width

Symbol

fXtal

fDA

tHIPW fXtal=12MHz

tVIPW fXtal=12MHz

tHHBJ

tVVBD fXtal=12MHz

tVCPW FXtal=12MHz

tDCSU

Condition

fXtal=12MHz

Min.

Typ.

12

Max.

Unit

MHz

KHz

uS

nS

uS

ns

46.875

0.3

94.86

8

VS input pulse Width

3

HSYNC to Hblank output jitter

H+V to Vblank output delay

VS pulse width in H+V signal

SDA to SCL set up time

SAD to SCL hold time

5

8

20

200

100

-

tDCH

Revision 1.2

- 20 -

2000/07/04

MTV212A32

(Rev. 1.2)

MYSON

TECHNOLOGY

SCL high time

SCL low time

START condition setup time

START condition hold time

STOP condition setup time

STOP condition hold time

tSCLH

tSCLL

tSU:STA

tHD:STA

tSU:STO

tHD:STO

500

-

ns

t

SCKH

t

HD:STO

SCKL

t

SU:STA

t

SU:STO

HD:STA

DCSU

DCH

2

Data interface timing (I C)

Test Mode Condition

In normal application, users should avoid the MTV212A32 entering its test mode, outlined as follow:

Test Mode A: RESET=1 & DA9=1 & DA8=0 & STO=0

Test Mode B: RESET's falling edge & DA9=1 & DA8=0 & STO=1

PACKAGE DIMENSION

1. 40-pin PDIP 600 mil

52.197mm +/-0.127

1.981mm

+/-0.254

1.270mm +/-0.254

0.457mm +/-0.127

2.540mm

15.494mm +/-0.254

13.868mm +/-0.102

0.254mm

+/-0.102

1.778mm

+/-0.127

3.81mm

+/-0.127

0.254mm

(min.)

5^o~7⁰

3.302mm

+/-0.254

6^o+/-3^o

16.256mm +/-0.508

Revision 1.2

- 21 -

2000/07/04

MTV212A32

(Rev. 1.2)

MYSON

TECHNOLOGY

2. 42 pin SDIP Unit: mm

Dimension in mm

Symbol

Min

Nom

Max

4.2

A

3.937 4.064

1.78 1.842

0.914 1.270

36.78 36.83

A1

B1

D

1.88

1.118

36.88

E1

F

eB

13.945 13.970 13.995

15.19 15.240 15.29

15.24 16.510 17.78

0°

7.5°

15°

15.494mm +/-0.254

13.868mm +/-0.102

0.254mm

+/-0.102

5^o~7⁰

6^o+/-3^o

16.256mm +/-0.508

3. 44 pin PLCC Unit:

PIN #1 HOLE

0.045*45⁰

0.180 MAX.

0.020 MIN.

0.013~0.021 TYP.

0.690 +/-0.005

0.610 +/-0.02

0.653 +/-0.003

0.500

7⁰TYP.

0.070

0.010

0.050 TYP.

0.026~0.032 TYP.

0.070

0.653 +/-0.003

0.690 +/-0.005

Revision 1.2

- 22 -

2000/07/04

MTV212A32

(Rev. 1.2)

MYSON

TECHNOLOGY

Ordering Information

Standard configurations:

Prefix

Part Type

Package Type

N: PDIP

ROM Size (K)

MTV

212A

S: SDIP

32

V: PLCC

Part Numbers:

Part Type

Package Type

ROM Size (K)

Prefix

MTV

212A

N

S

V

32

MTV

Revision 1.2

- 23 -

2000/07/04


型号：	MTV212A32
厂家：	ETC
描述：	8051 Embedded Monitor Controller Mask ROM Type 8051嵌入式控制器监视器掩膜ROM类型监视器控制器
文件：	总23页 (文件大小：166K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

MTV212A32 [ETC]

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