22897HA (OT) No. 5486-1/26

Preliminary

LC66E2316

SANYO Electric Co.,Ltd. Semiconductor Bussiness Headquarters

TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110 JAPAN

Four-Bit Single-Chip Microcontroller

with 16 KB of On-Chip EPROM

CMOS LSI

Overview

The LC66E2316 is an on-chip EPROM version of the
LC6623XX Series CMOS 4-bit single-chip micro-
controllers. The LC66E2316 provides the same functions
as the LC662316A, and is pin compatible with that
product. Since the LC66E2316 is provided in a window
package, it can be reprogrammed repeatedly and is thus
optimal for program development.

Features and Functions

· On-chip EPROM capacity of 16 kilobytes, and an on-

chip RAM capacity of 512

4 bits.

· Fully supports the LC66000 Series common instruction

set (128 instructions).

· I/O ports: 36 pins
· DTMF generator

This microcontroller incorporates a circuit that can
generate two sine wave outputs, DTMF output, or a
melody output for software applications.

· 8-bit serial interface: one circuit
· Instruction cycle time: 0.95 to 10 µs (at 4.5 to 5.5 V)
· Powerful timer functions and prescalers

-- Time limit timer, event counter, pulse width

measurement, and square wave output using a 12-bit
timer.

-- Time limit timer, event counter, PWM output, and

square wave output using an 8-bit timer.

-- Time base function using a 12-bit prescaler.

· Powerful interrupt system with 10 interrupt factors and

7 interrupt vector locations.
-- External interrupts: 3 factors/3 vector locations
-- Internal interrupts: 4 factors/4 vector locations

(Waveform output internal interrupts: 3 factors and
1 vector; shared with external expansion interrupts)

· Flexible I/O functions

Selectable options include 20-mA drive outputs, inverter
circuits, pull-up and open-drain circuits.

· Optional runaway detection function (watchdog timer)
· 8-bit I/O functions
· Power saving functions using halt and hold modes.
· Packages: DIC42S (window), QFC48 (window)
· Evaluation LSIs: LC66599 (evaluation chip) +

EVA800/850 - TB662YXX2

Package Dimensions

unit: mm

3127-DIC42S

0.46

37.32

0.8

1.778

1.27

3.4min

6.5max

14.99

0.25

15.24

SANYO: DIC42S

[LC66E2316]

unit: mm

3157-QFC48

20.0

14.0

3.0

0.35

1.0

1.5

20.0

14.0

3.0

0.35

1.0

1.5

0.15

2.2

4.2

4.77max

SANYO: QFC48

[LC66E2316]

No. 5486

Series Organization

Note:

Under development

No. 5486-2/26

LC66E2316

Type No.

No. of

ROM capacity

RAM

Package

Features

pins

capacity

LC66304A/306A/308A

4 K/6 K/8 KB

512 W

DIP42S

QFP48E

LC66404A/406A/408A

4 K/6 K/8 KB

512 W

DIP42S

QFP48E

LC66506B/508B/512B/516B

6 K/8 K/12 K/16 KB

512 W

DIP64S

QFP64A

LC66354A/356A/358A

4 K/6 K/8 KB

512 W

DIP42S

QFP48E

LC66354S/356S/358S

4 K/6 K/8 KB

512 W

QFP44M

LC66556A/558A/562A/566A

6 K/8 K/12 K/16 KB

512 W

DIP64S

QFP64E

LC66354B/356B/358B

4 K/6 K/8 KB

512 W

DIP42S

QFP48E

Low-voltage high-speed versions

LC66556B/558B/562B/566B

6 K/8 K/12 K/16 KB

512 W

DIP64S

QFP64E

3.0 to 5.5 V/0.92 µs

LC66354C/356C/358C

4 K/6 K/8 KB

512 W

DIP42S

QFP48E

2.5 to 5.5 V/0.92 µs

LC662104A/06A/08A

4 K/6 K/8 KB

384 W

DIP30SD

MFP30S

LC662304A/06A/08A/12A/16A

4 K/6 K/8 K/12 K/16 KB 512 W

DIP42S

QFP48E

LC662508A/12A/16A

8 K/12 K/16 KB

512 W

DIP64S

QFP64E

LC665304A/06A/08A/12A/16A

4 K/6 K/8 K/12 K/16 KB 512 W

DIP48S

QFP48E

Dual oscillator support
3.0 to 5.5 V/0.95 µs

LC66E308

EPROM 8 KB

512 W

DIC42S

QFC48

with window

LC66P308

OTPROM 8 KB

512 W

DIP42S

QFP48E

LC66E408

EPROM 8 KB

512 W

DIC42S

QFC48

with window

LC66P408

OTPROM 8 KB

512 W

DIP42S

QFP48E

LC66E516

EPROM 16 KB

512 W

DIC64S

QFC64

with window

LC66P516

OTPROM 16 KB

512 W

DIP64S

QFP64E

LC66E2108

EPROM 8 KB

384 W

LC66E2316

EPROM 16 KB

512 W

DIC42S

QFC48

with window

LC66E2516

EPROM 16 KB

512 W

DIC64S

QFC64

with window

LC66E5316

52/48

EPROM 16 KB

512 W

DIC52S

QFC48

with window

LC66P2108

OTPROM 8 KB

384 W

DIP30SD

MFP30S

LC66P2316

OTPROM 16 KB

512 W

DIP42S

QFP48E

LC66P2516

OTPROM 16 KB

512 W

DIP64S

QFP64E

LC66P5316

OTPROM 16 KB

512 W

DIP48S

QFP48E

OTP
4.0 to 5.5 V/0.95 µs

Window evaluation versions
4.5 to 5.5 V/0.92 µs

Window and OTP evaluation versions
4.5 to 5.5 V/0.92 µs

On-chip DTMF generator versions
3.0 to 5.5 V/0.95 µs

Low-voltage versions
2.2 to 5.5 V/3.92 µs

Normal versions
4.0 to 6.0 V/0.92 µs

Pin Assignments

No. 5486-3/26

LC66E2316

DIC42S

P20/SI0/A0

P21/SO0/A1

P22/SCK0/A2

P23/INT0/A3

P30/INT1/A4

P31/POUT0/A5

P32/POUT1/A6

VSS

OSC1

OSC2

VDD

RES/VPP/OE

PE0

PE1

TEST/EPMOD

P33/HOLD

P40/INV0I/A7

P41/INV0O/A8

P42/INV1I/A9

P43/INV1O/A10

P50/A11

P13/D7

P12/D6

P11/D5

P10/D4

P03/D3

P02/D2

P01/D1

P00/D0

PD3/INV3O

LC66E2316

PD2/INV3I

PD1/INV2O

PD0/INV2I

PC3/DASEC

PC2/CE

P63/PIN1

P62/DT

P61

P60/ML

P53/TA

P52/A13

P51/A12

QFC48

LC66E2316

P03/D3

P02/D2

P31/POUT0/A5

P01/D1

P32/POUT1/A6

P00/D0

PD3/INV3O

OSC1

PD2/INV3I

OSC2

PD1/INV2O

PD0/INV2I

RES/V

/OE

PC3/DASEC

PE0

PC2/CE

PE1

P63/PIN

TEST/EPMOD

P62/DT

P33/HOLD

P61

P10/D4

P60/ML

P11/D5

P53/INT2/TA

P12/D6

P52/A13

P13/D7

P51/A12

P20/SI0/A0

P50/A11

P21/SO0/A1

P43/INV1O/A10

P22/SCK0/A2

P42/INV1I/A9

P23/INT0/A3

P41/INV0O/A8

P30/INT1/A4

P40/INV0I/A7

Top view

Usage Notes

The LC66E2316 was created for program development, product evaluation, and prototype development for products
based on the LC6623XX Series microcontrollers. Keep the following points in mind when using this product.
1. After a reset

The RES pin must be held low for an additional 3 instruction cycles after the oscillator stabilization period has
elapsed. Also, the port output circuit types are set up during the 9 instruction cycles immediately after RES is set
high. Only then is the program counter set to 0 and program execution started from that location. (The port output
circuits all revert to the open-drain type during periods when RES is low.)

2. Notes on LC6623XX evaluation

The high end of the EPROM area (locations 3FF0H to 3FFFH) are the option specification area. Option specification
data must be programmed for and loaded into this area. The Sanyo specified cross assembler for this product is the
program LC66S.EXE. Also, insert JMP instructions so that user programs do not attempt to execute addresses that
exceed the capacity of the mask ROM, and write zeros (00H) to areas (other than 3FF0H to 3FFFH) that exceed the
actual capacity of the mask ROM.

3. Always apply an opaque seal to the window on the LC66E2316 package when actually using the device.

Main differences between the LC66E2316, LC66P2316, and LC6623XX Series

Note:

Although the microcontroller will remain in hold mode if the RES pin is set low while it is in hold mode, always use the reset start sequence (after
switching HOLD from low to high, switch RES from low to high) when clearing hold mode. Also not that a current of about 100 µA flows from the
RES pin when it is low. This increases the hold mode current drain by about 100 µA.

See the data sheets for the individual products for details on other differences.

No. 5486-4/26

LC66E2316

Item

LC6623XX Series (mask version)

LC66E2316

LC66P2316

Differences in the main
characteristics

30 to +70°C

+10 to +40°C

30 to +70°C

· Operating temperature range

· Operating supply voltage/operating

3.5 to 5.5 V/0.95 to 10 µs

4.5 to 5.5 V/0.95 to 10 µs

4.0 to 5.5 V/0.95 to 10 µs

frequency (cycle time)

Typical: 10 µA

· Input high-level current (RES)

Maximum: 1 µA

(normal operation and halt mode)

Hold mode: 1 µA maximum

· Input low-level current (RES)

Maximum: 1 µA

Typical: 100 µA

· Current drain

(Operating at 4 MHz)

Typical: 10 nA, maximum: 10 µA

Larger than that for the mask versions

(Halt mode at 4 MHz)

Typical: 10 nA, maximum: 10 µA

(Hold mode)

Port output types at reset

The output type specified in

Open-drain outputs

the options

Package

· DIP42S

· DIC42S window package

· DIP42S

· QFP48E

· QFC48 window package

· QFP48E

At least 10 ms

VDD

min

Location

VDD

OSC

RES

Program execution (PC)

Port output type

At least 3
instruction

Oscillator
stabilization

Open drain

Option switching
period

9 instruction
cycles

Option specification

System Block Diagram

Pin Function Overview

No. 5486-5/26

LC66E2316

I/O

Overview

Output driver type

Options

State after a Standby mode

reset

operation

P00/D0
P01/D1
P02/D2
P03/D3

P10/D4
P11/D5
P12/D6
P13/D7

P20/SI0/A0

P21/SO0/A1

P22/SCK0/

P23/INT0/A3

I/O ports P00 to P03
· Input or output in 4-bit or 1-bit units
· P00 to P03 support the halt mode

control function (This function can be
specified in bit units.)

· Used as data pins in EPROM mode

I/O ports P10 to P13
· Input or output in 4-bit or 1-bit units
· Used as data pins in EPROM mode

I/O ports P20 to P23
· Input or output in 4-bit or 1-bit units
· P20 is also used as the serial input SI0

pin.

· P21 is also used as the serial output

SO0 pin.

· P22 is also used as the serial clock

SCK0 pin.

· P23 is also used as the INT0 interrupt

request pin, and also as the timer 0
event counting and pulse width
measurement input.

· Used as address pins in EPROM mode

I/O

· Pch: Pull-up MOS type
· Nch: Intermediate sink current

type

· Pch: Pull-up MOS type
· Nch: Intermediate sink current

type

· Pch: CMOS type
· Nch: Intermediate sink current

type

· Pull-up MOS or

Nch OD output

· Output level on

reset

· Pull-up MOS or

Nch OD output

· Output level on

reset

CMOS or Nch OD
output

High or low
(option)

Hold mode:
Output off

Halt mode:
Output
retained

Continued on next page.

SYSTEM

CONTROL

RAM STACK

(512W)

EPROM

16KB

POUT0
SI0
SO0
SCK0
INT0

INT1. INT2

PIN1. POUT1

INV

(x=0 to 3)

FLAG

DTMF

GEN.

PRESCALER

INTERRUPT

CONTROL

MPX

TIMER1

MPX

TIMER0

SERIAL I/O 0

ALU

RES

TEST

OSC1

OSC2

HOLD

EPROM

control

A0 to A13

D0 to D7

DASEC
Vpp/OE
EPMOD
TA

Continued from preceding page.

No. 5486-6/26

LC66E2316

Continued on next page.

I/O

Overview

Output driver type

Options

State after a Standby mode

reset

operation

P30/INT1/A4
P31/POUT0/

P32/POUT1/

P33/HOLD

P40/INV0I/

P41/INV0O/

P42/INV1I/

P43/INV1O/

A10

P50/A11
P51/A12
P52/A13

P53/INT2/TA

P60/ML

P61

P62/DT

P63/PIN1

I/O ports P30 to P32
· Input or output in 3-bit or 1-bit units
· P30 is also used as the INT1 interrupt

request.

· P31 is also used for the square wave

output from timer 0.

· P32 is also used for the square wave

and PWM output from timer 1.

· P31 and P32 also support 3-state

outputs.

· Used as address pins in EPROM mode

Hold mode control input
· Hold mode is set up by the HOLD

instruction when HOLD is low.

· In hold mode, the CPU is restarted by

setting HOLD to the high level.

· This pin can be used as input port P33

along with P30 to P32.

· When the P33/HOLD pin is at the low

level, the CPU will not be reset by a
low level on the RES pin. Therefore,
applications must not set P33/HOLD
low when power is first applied.

I/O ports P40 to P43
· Input or output in 4-bit or 1-bit units
· Input or output in 8-bit units when used

in conjunction with P50 to P53.

· Can be used for output of 8-bit ROM

data when used in conjunction with
P50 to P53.

· Dedicated inverter circuit (option)
· Used as address pins in EPROM mode

I/O ports P50 to P53
· Input or output in 4-bit or 1-bit units
· Input or output in 8-bit units when used

in conjunction with P40 to P43.

· Can be used for output of 8-bit ROM

data when used in conjunction with
P40 to P43.

· P53 is also used as the INT2 interrupt

request.

· Used as address pins in EPROM mode

I/O ports P60 to P63
· Input or output in 4-bit or 1-bit units
· P60 is also used as the melody output

ML pin.

· P62 is also used as the tone output DT

pin.

· P63 is also used for the event count

input to timer 1.

I/O

· Pch: CMOS type
· Nch: Intermediate sink current

type

· Pch: Pull-up MOS type
· CMOS type when the inverter

circuit option is selected

· Nch: Intermediate sink current

type

· Pch: Pull-up MOS type
· Nch: Intermediate sink current

type

· Pch: CMOS type
· Nch: Intermediate sink current

type

CMOS or Nch OD
output

· Pull-up MOS or

Nch OD output

· Output level on

reset

· Inverter circuit

· Pull-up MOS or

Nch OD output

· Output level on

reset

CMOS or Nch OD
output

· High or

low
(option)

· Inverter

I/O is set
to the
output off
state.

High or low
(option)

Hold mode:
Output off

Hold mode:
Port output
off, inverter
output off

Hold mode:
Output off

Halt mode:
Output
retained

Halt mode:
Port output
retained,
inverter
output
continues

Halt mode:
Output
retained

Continued from preceding page.

Note: Pull-up MOS type: The output circuit includes a MOS transistor that pulls the pin up to V

CMOS output: Complementary output.
OD output: Open-drain output.

No. 5486-7/26

LC66E2316

I/O

Overview

Output driver type

Options

State after a Standby mode

reset

operation

PC2/CE

PC3/DASEC

PD0/INV2I

PD1/INV2O

PD2/INV3I

PD3/INV3O

PE0
PE1

OSC1

OSC2

RES/V

TEST/

EPMOD

I/O ports PC2 to PC3
· Output in 2-bit or 1-bit units
· PC3 is also used as the control CE and

DASEC pin in EPROM mode.

Dedicated input ports PD0 to PD3
Dedicated inverter circuits (option)

Dedicated input ports

System clock oscillator connections

When an external clock is used, leave
OSC2 open and connect the clock signal
to OSC1.

System reset input
· When the P33/HOLD pin is at the high

level, a low level input to the RES pin
will initialize the CPU.

· This pin is also used as the V

/OE

pin in EPROM mode.

CPU test pin
This pin must be connected to V

during normal operation. Setting this pin
to +12 V switches the LC66E2316 to
EPROM mode.

Power supply pins

· Pch: CMOS type
· Nch: Intermediate sink current

type

· When the inverter circuit

option is selected.

· Pch: CMOS type
· Nch: Intermediate sink current

type

CMOS or Nch OD
output

Inverter circuits

Ceramic oscillator
or external clock
selection

Normal
input
Inverter I/O
goes to the
output off
state.

Option
selection

Hold mode:
Port output
off

Hold mode:
Inverter
Output off

Halt mode:
Inverter
output
continues

Hold mode:
input
disabled

Hold mode:
oscillator
stops

Halt mode:
inputs
accepted

Halt mode:
oscillator
continues

Halt mode:
Port output
retained

User Options

1. Port 0, 1, 4, and 5 output level at reset option

The output levels at reset for I/O ports 0, 1, 4, and 5, in independent 4-bit groups, can be selected from the following
two options.

2. Oscillator circuit options

· Main clock

Note: There is no RC oscillator option.

3. Watchdog timer option

A runaway detection function (watchdog timer) can be selected as an option.

4. Port output type options

· The output type of each bit (pin) in ports P0, P1, P2, P3 (except for the P33/HOLD pin), P4, P5, P6, and PC can be

selected individually from the following two options.

No. 5486-8/26

LC66E2316

Option

Circuit

Conditions and notes

1. External clock

2. Ceramic oscillator

The input has Schmitt characteristics

Option

Conditions and notes

1. Output high at reset

The four bits of ports 0, 1, 4, or 5 are set in a group

2. Output low at reset

The four bits of ports 0, 1, 4, or 5 are set in a group

Option

Circuit

Conditions and notes

1. Open-drain output

2. Output with built-in pull-up

resistor

The port P2, P3, P5, and P6 inputs have Schmitt
characteristics.

The CMOS outputs (ports P2, P3, P6, and PC)
and the pull-up MOS outputs (P0, P1, P4, and
P5) are distinguished by the drive capacity of the
p-channel transistor.

OSC1

OSC2

Ceramic oscillator

DSB

Output data

Input data

DSB

Output data

Input data

LC662316 Series Option Data Area and Definitions

LC66E2316

Continued on next page.

ROM area

Bit

Option specified

Option/data relationship

Output level at reset

0 = high level, 1 = low level

Unused

This bit must be set to 0.

3FF0H

Oscillator option

0 = external clock, 1 = ceramic oscillator

Unused

This bit must be set to 0.

Output level at reset

0 = low level, 1 = high level

Watchdog timer option

0 = none, 1 = yes (present)

P13

P12

Output type

0 = OD, 1 = PU

P11

3FF1H

P10

P03

P02

Output type

0 = OD, 1 = PU

P01

P00

Unused

This bit must be set to 0.

P32

P31

Output type

0 = OD, 1 = PU

3FF2H

P30

P23

P22

Output type

0 = OD, 1 = PU

P21

P20

P53

P52

Output type

0 = OD, 1 = PU

P51

3FF3H

P50

P43

P42

Output type

0 = OD, 1 = PU

P41

P40

Unused

This bit must be set to 0.

3FF4H

P63

P62

Output type

0 = OD, 1 = PU

P61

P60

Unused

This bit must be set to 0.

3FF5H

Unused

This bit must be set to 0.

Unused

This bit must be set to 0.

3FF6H

Unused

This bit must be set to 0.

Continued from preceding page.

No. 5486-11/26

LC66E2316

Continued on next page.

ROM area

Bit

Option specified

Option/data relationship

Unused

This bit must be set to 0.

3FF7H

PC3

Output type

0 = OD, 1 = PU

PC2

Unused

This bit must be set to 0.

ML disabled option

0 = disabled, 1 = enabled

Unused

This bit must be set to 1.

Unused

This bit must be set to 1.

3FF8H

PD3

Inverter output

0 = inverter output, 1 = none

PD1

Unused

This bit must be set to 1.

P43

Inverter output

0 = inverter output, 1 = none

P41

Unused

This bit must be set to 0.

3FF9H

Unused

This bit must be set to 0.

Unused

This bit must be set to 0.

3FFAH

Unused

This bit must be set to 0.

Unused

This bit must be set to 0.

3FFBH

Unused

This bit must be set to 0.

Unused

This bit must be set to 0.

3FFCH

Unused

This bit must be set to 0.

3FFDH

Reserved. Must be set to predefined data values.

This data is generated by the assembler.

If the assembler is not used, set this data to `00'.

Continued from preceding page.

Usage Notes

1. Option specification

When using a Sanyo cross assembler with the LC66E2316, use the version called "LC66S.EXE" and specify the
actual microcontroller to be evaluated with the CPU pseudo instruction in the source file. The port options must be
specified in the source file. The cross assembler will create an option code list in the option specification area
(locations 3FF0H to 3FFFH). It is also possible to directly set up data in the option specification area. If this is done,
the options must be specified according to the option code creation table shown on the following page.

2. Writing the EPROM

Use a special-purpose writing conversion board (the W66EP5316D for the DIP package, and the W66EP2316Q for
the QFP package) to allow the EPROM programmers listed below to be used when writing the data created by the
cross assembler to the LC66E2316.
· The EPROM programmers listed below can be used.

· The "27512 (V

12.5 V) Intel high-speed write" technique must be used to write the EPROM. Set the address

range to location 0 to 3FFFH. The DASEC jumper must be off.

3. Using the data security function

The data security function sets up the microcontroller in advance so that data that was written to the microcontroller
EPROM cannot be read out.
Use the following procedure to enable the LC66E2316 data security function.
· Set the write conversion board DASEC jumper to the on position.
· Write the data to the EPROM once again.
At this time, since this function will operate, the EPROM programmer will issue an error. However, this error does
not indicate that there was a problem in either the programmer or the LSI.
Notes: 1. If the data at all addresses was "FF" at step 2, the data security function will not be activated.

Notes:

2. The data security function will not be activated at step 2 if the "blank

program

verify" operation

sequence is used.

Notes:

3. Always return the jumper to the off position after the data security function has been activated.

No. 5486-12/26

LC66E2316

ROM area

Bit

Option specified

Option/data relationship

3FFEH

Reserved. Must be set to predefined data values.

This data is generated by the assembler.

If the assembler is not used, set this data to `00'.

3FFFH

Reserved. Must be set to predefined data values.

This data is generated by the assembler.

If the assembler is not used, set this data to `00'.

Manufacturer

Models that can be used

Advantest

R4945, R4944A, R4943, or equivalent products

Ando

AF9704

AVAL

Minato Electronics

MODEL1890A

4. Erase procedure

Use a general-purpose EPROM eraser to erase data written to the EPROM.

Specifications

Absolute Maximum Ratings

at Ta = 25°C, V

= 0 V

Note: 1. Applies to pins with open-drain output specifications. For pins with other than open-drain output specifications, the ratings in the pin column for that

pin apply.

2. For the oscillator input and output pins, levels up to the free-running oscillation level are allowed.
3. Sink current (Applies to PD when the inverter array specifications have been selected.)
4. Source current (Applies to all pins except PD for which the pull-up output specifications, the CMOS output specifications, or the inverter array

specifications have been selected. Applies to P8 pins for which the inverter array specifications have been selected.) Contact your Sanyo
representative for the electrical characteristics when the inverter array or buffer array options are specified.

No. 5486-13/26

LC66E2316

Parameter

Symbol

Conditions

Ratings

Unit

Note

Maximum supply voltage

max

0.3 to +7.0

P2, P3 (except for the P33/HOLD pin),

0.3 to +12.0

Input voltage

P61, and P63

All other inputs

0.3 to V

+ 0.3

OUT

P2, P3 (except for the P33/HOLD pin),

0.3 to +12.0

Output voltage

P61, and P63

OUT

All other inputs

0.3 to V

+ 0.3

P0, P1, P2, P3 (except for the P33/HOLD pin),

P4, P5, P6, PC

Output current per pin

P41, P43, PC3, PD1, PD3

P0, P1, P4, P5

P2, P3 (except for the P33/HOLD pin), P6,and PC

P0, P1, P2, P3 (except for the P33/HOLD pin), PD

Total pin current

P4, P5, P6, PC

P0, P1, P2, P3 (except for the P33/HOLD pin), PD

P4, P5, P6, PC

Allowable power dissipation

Pd max

Ta = +10 to +40°C: DIC42S (QFC48)

600 (430)

Operating temperature

Topr

30 to +70

°C

Storage temperature

Tstg

55 to +125

°C

SW DASEC

Pin 1
Aligned to the top

SW
DASEC

Cut corner

Pin 1

LC66E2316 (DIC)

LC66E2316 (QFC)

Write board (W66EP5316D)

Write board (W66EP2316Q)

Allowable Operating Ranges

at Ta = +10 to +40°C, V

= 0 V, V

= 4.5 to 5.5 V, unless otherwise specified.

Note: 1. Applies to pins with open-drain specifications. However, V

2 applies to the P33/HOLD pin.

When ports P2, P3, and P6 have CMOS output specifications they cannot be used as input pins.

2. PC port pins with CMOS output specifications cannot be used as input pins.

Contact your Sanyo representative for the allowable operating ranges for P4 and PD when the inverter array is used.

No. 5486-14/26

LC66E2316

Parameter

Symbol

Conditions

min

typ

max

Unit

Note

Operating supply voltage

4.5

5.5

Memory retention supply voltage

: During hold mode

1.8

5.5

P2, P3 (except for the P33/HOLD pin),

0.8 V

10.0

P61, and P63: N-channel output transistor off

Input high-level voltage

P33/HOLD, RES, OSC1:

0.8 V

N-channel output transistor off

P0, P1, P4, P5, PC, PD, PE:

0.8 V

N-channel output transistor off

P2, P3 (except for the P33/HOLD pin), P6,

0.2 V

RES, and OSC1: N-channel output transistor off

Input low-level voltage

P33/HOLD: V

= 1.8 to 5.5 V

0.2 V

P0, P1, P4, P5, PC, PD, PE, TEST:

0.2 V

N-channel output transistor off

Operating frequency

fop

0.4

4.20

MHz

(instruction cycle time)

(Tcyc)

(10)

(0.95)

(µs)

[External clock input conditions]

OSC1: Defined by Figure 1. Input the clock

Frequency

ext

signal to OSC1 and leave OSC2 open.

0.4

4.20

MHz

(External clock input must be selected as the
oscillator circuit option.)

OSC1: Defined by Figure 1. Input the clock

Pulse width

extH

, t

extL

signal to OSC1 and leave OSC2 open.

100

(External clock input must be selected as the
oscillator circuit option.)

OSC1: Defined by Figure 1. Input the clock

Rise and fall times

extR

, t

extF

signal to OSC1 and leave OSC2 open.

(External clock input must be selected as the
oscillator circuit option.)

Electrical Characteristics

at Ta = +10 to +40°C, V

= 0 V, V

= 4.5 to 5.5 V unless otherwise specified.

No. 5486-15/26

LC66E2316

Parameter

Symbol

Conditions

min

typ

max

Unit

Note

P2, P3 (except for the P33/HOLD pin),

P61, and P63: V

= 10.0 V, with the output

5.0

µA

Nch transistor off

P0, P1, P4, P5, PC, OSC1, and P33/HOLD

Input high-level current

(Does not apply to PD, PE, PC2, and PC3):

1.0

µA

= V

, with the output Nch transistor off

PD, PE, PC2, PC3: V

= V

1.0

µA

with the output Nch transistor off

RES: V

= V

, operating, halt mode

µA

RES: V

= V

, hold mode

1.0

µA

Input ports other than PD, PE, PC2, and PC3:

1.0

µA

Input low-level current

= V

, with the output Nch transistor off

PC2, PC3, PD, PE: V

= V

1.0

µA

with the output Nch transistor off

RES: V

= V

100

µA

P2, P3 (except for the P33/HOLD pin),

1.0

Output high-level voltage

P6, and PC: I

= 1 mA

P2, P3 (except for the P33/HOLD pin),

0.5

P6, and PC: I

= 0.1 mA

Value of the output pull-up resistor

P0, P1, P4, P5

100

150

P0, P1, P2, P3, P4, P5, P6, and PC

0.4

Output low-level voltage

(except for the P33/HOLD pin): I

= 1.6 mA

P0, P1, P2, P3, P4, P5, P6, and PC

1.5

(except for the P33/HOLD pin): I

= 10 mA

OFF

P2, P3, P61, P63: V

= V

5.0

µA

Output off leakage current

OFF

Does not apply to P2, P3, P61, and P63:

1.0

µA

= V

[Schmitt characteristics]

Hysteresis voltage

HYS

0.1 V

High-level threshold voltage

P2, P3, P5, P6, OSC1 (EXT), RES

0.5 V

0.8 V

Low-level threshold voltage

0.2 V

0.5 V

[Ceramic oscillator]

Oscillator frequency

OSC1, OSC2: Figure 2, 4 MHz

4.0

MHz

Oscillator stabilization time

CFS

Figure 3, 4 MHz

10.0

[Serial clock]

Cycle time

Input

CKCY

0.9

µs

Output

2.0

Tcyc

Low-level and high-level Input

CKL

0.4

µs

pulse widths

Output

CKH

1.0

Tcyc

Rise an fall times

Output

CKR

, t

CKF

0.1

µs

[Serial input]

Data setup time

ICK

0.3

µs

Data hold time

CKI

0.3

µs

[Serial output]

SO0: With the timing of Figure 4 and

Output delay time

CKO

the test load of Figure 5. Stipulated with respect

0.3

µs

to the falling edge (

) of SCK0.

SI0: With the timing of Figure 4.
Stipulated with respect to the rising edge (

) of

SCK0.

SCK0: With the timing of Figure 4 and the test
load of Figure 5.

Continued on next page.

Continued from preceding page.

Note: 1. With the output Nch transistor off in shared I/O ports with the open-drain output specifications. These pins cannot be used as input pins if the

CMOS output specifications are selected.When the port option is selected for PE.

2. With the output Nch transistor off in shared I/O ports with the open-drain output specifications. The rating for the pull-up output specification pins is

stipulated in terms of the output pull-up current IPO. These pins cannot be used as input pins if the CMOS output specifications are selected.

3. With the output Nch transistor off for CMOS output specification pins.
4. With the output Nch transistor off for pull-up output specification pins.
5. With the output Nch transistor off for open-drain output specification pins.
6. Reset state

Tone (DTMF) Output Characteristics

DC Characteristics

at Ta = +10 to +40°C, V

= 0 V

Figure 1 External Clock Input Waveform

No. 5486-16/26

LC66E2316

Parameter

Symbol

Conditions

min

typ

max

Unit

Note

[Pulse conditions]

INT0: Figure 6, conditions under which the INT0

INT0 high and low-level

IOH

, t

IOL

interrupt can be accepted, conditions under

Tcyc

which the timer 0 event counter or pulse width
measurement input can be accepted

High and low-level pulse widths

IIH

, t

IIL

INT1, INT2: Figure 6, conditions under which

Tcyc

for interrupt inputs other than INT0

the corresponding interrupt can be accepted

PIN1 high and low-level

PINH

, t

PINL

PIN1: Figure 6, conditions under which the

Tcyc

pulse widths

timer 1 event counter input can be accepted

RES high and low-level

RSH

, t

RSL

RES: Figure 6, conditions under which reset

Tcyc

pulse widths

can be applied.

Operating current drain

DD OP

: 4-MHz ceramic oscillator

6.0

: 4-MHz external clock

6.0

Halt mode current drain

DDHALT

: 4-MHz ceramic oscillator

4.0

8.0

: 4-MHz external clock

4.0

8.0

Hold mode current drain

DDHOLD

: V

= 1.8 to 5.5 V

0.01

µA

Parameter

Symbol

Conditions

min

typ

max

Unit

Tone output voltage (p-p)

DT: Dual tones, V

= 4.5 to 5.5 V

0.9

1.3

2.0

Row/column tone output

BCR1

DT: Dual tones, V

= 4.5 to 5.5 V

1.0

2.0

3.0

voltage ratio

Tone distortion

THD1

DT: Single tone, V

= 4.5 to 5.5 V

textL

OPEN

(OSC2)

OSC1

textR

textF

VSS

VDD

0.2VDD

0.8VDD

1/fext

textH

External clock

Figure 2 Ceramic Oscillator Circuit

Figure 3 Oscillator Stabilization Period

Table 1 Guaranteed Ceramic Oscillator Constants External capacitor type

Figure 4 Serial I/O Timing

Figure 5 Timing Load

Figure 6 Input Timing for the INT0, INT1, INT2, PIN1, and RES pins

Figure 7 Tone Output Pin Load

No. 5486-17/26

LC66E2316

External capacitor type

Built-in capacitor type

4 MHz

C1 = 33 pF ± 10%

4 MHz

(Murata Mfg. Co., Ltd.)

C2 = 33 pF ± 10%

(Murata Mfg. Co., Ltd.)

CSA4.00MG

CST4.00MG

4 MHz

C1 = 33 pF ± 10%

4 MHz

(Kyocera Corporation)

C2 = 33 pF ± 10%

(Kyocera Corporation)

KBR4.0MS

KBR4.0MES

OSC2

OSC1

Ceramic

oscillator

VDD

OSC

Oscillator
unstable period

tCFS

Stable oscillation

Operating VDD
minimum value

tICK tCKI

tCKL

tCKR

tCKCY

tCKH

tCKF

0.8VDD (input)

VDD-1 (output)

0.2VDD (input)

SCK0
SCK1

SI0

SI1

SO0

SO1

0.4VDD (output)

0.8VDD

0.2VDD

tCK0

VDD-1

0.4VDD

C=50pF

TEST

point

R=1k

tI0H
tI1H

tPINH

tRSH

tI0L
tI1L

tPINL

tRSL

0.8VDD

0.2VDD

P60/ML

P62/DT

R=10 k

LC66XXXX Series Instruction Table (by function)

Abbreviations:
AC:

Accumulator

E register

CF:

Carry flag

ZF:

Zero flag

HL:

Data pointer DPH, DPL

XY:

Data pointer DPX, DPY

Data memory

M (HL):

Data memory pointed to by the DPH, DPL data pointer

M (XY):

Data memory pointed to by the DPX, DPY auxiliary data pointer

M2 (HL): Two words of data memory (starting on an even address) pointed to by the DPH, DPL data pointer
SP:

Stack pointer

M2 (SP): Two words of data memory pointed to by the stack pointer
M4 (SP): Four words of data memory pointed to by the stack pointer
in:

n bits of immediate data

t2:

Bit specification

PCh:

Bits 8 to 11 in the PC

PCm:

Bits 4 to 7 in the PC

PCl:

Bits 0 to 3 in the PC

Fn:

User flag, n = 0 to 15

TIMER0: Timer 0
TIMER1: Timer 1
SIO:

Serial register

Port

P (i4):

Port indicated by 4 bits of immediate data

INT:

Interrupt enable flag

( ), [ ]:

Indicates the contents of a location

Transfer direction, result

Exclusive or

Logical and

Logical or

Addition

Subtraction

--:

Taking the one's complement

No. 5486-18/26

LC66E2316

Bit

No. 5486-19/26

LC66E2316

Continued on next page.

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Accumulator manipulation instructions]

CLA

Clear AC

1 0 0 0

0 0 0 0

Clear AC to 0.

Has a vertical

(Equivalent to LAI 0.)

skip function.

DAA

Decimal adjust AC

1 1 0 0

1 1 1 1

(AC) + 6

Add six to AC.

in addition

0 0 1 0

0 1 1 0

(Equivalent to ADI 6.)

Decimal adjust AC

1 1 0 0

1 1 1 1

(AC) + 10

DAS

in subtraction

0 0 1 0

1 0 1 0

(Equivalent to

Add 10 to AC.

ADI 0AH.)

CLC

Clear CF

0 0 0 1

1 1 1 0

Clear CF to 0.

STC

Set CF

0 0 0 1

1 1 1 1

Set CF to 1.

CMA

Complement AC

0 0 0 1

1 0 0 0

(AC)

Take the one's complement

of AC.

Increment AC

0 0 0 1

0 1 0 0

(AC) + 1

Increment AC.

ZF, CF

Decrement AC

0 0 1 0

0 1 0 0

(AC) 1

Decrement AC.

ZF, CF

Rotate AC right

(CF),

RAR

through CF

0 0 0 1

0 0 0 0

ACn

(ACn + 1),

Shift AC (including CF) right.

(AC

)

Rotate AC left

(CF),

RAL

through CF

0 0 0 0

0 0 0 1

ACn + 1

(ACn),

Shift AC (including CF) left.

CF, ZF

(AC

)

TAE

Transfer AC to E

0 1 0 0

0 1 0 1

(AC)

Transfer the contents of AC to E.

TEA

Transfer E to AC

0 1 0 0

0 1 1 0

(E)

Transfer the contents of E to AC.

XAE

Exchange AC with E

0 1 0 0

(AC)

(E)

Exchange the contents of
AC and E.

[Memory manipulation instructions]

Increment M

0 0 0 1

0 0 1 0

M (HL)

Increment M (HL).

ZF, CF

[M (HL)] + 1

Decrement M

0 0 1 0

M (HL)

Decrement M (HL).

ZF, CF

[M (HL)] 1

IMDR i8

Increment M direct

1 1 0 0

0 1 1 1

M (i8)

[M (i8)] + 1

Increment M (i8).

ZF, CF

DMDR i8 Decrement M direct

1 1 0 0

0 0 1 1

M (i8)

[M (i8)] 1

Decrement M (i8).

ZF, CF

SMB t2

Set M data bit

0 0 0 0

1 1 t

[M (HL), t2]

Set the bit in M (HL) specified
by t0 and t1 to 1.

RMB t2

Reset M data bit

0 0 1 0

1 1 t

[M (HL), t2]

Clear the bit in M (HL)

specified by t0 and t1 to 0.

[Arithmetic, logic and comparison instructions]

Add the contents of AC and

Add M to AC

0 0 0 0

0 1 1 0

(AC) +

M (HL) as two's complement

ZF, CF

[M (HL)]

values and store the result
in AC.

Add the contents of AC and

ADDR i8 Add M direct to AC

1 1 0 0

1 0 0 1

(AC) + [M (i8)]

M (i8) as two's complement

ZF, CF

values and store the result
in AC.

Add the contents of AC,

ADC

Add M to AC with CF

0 0 0 0

0 0 1 0

(AC) +

M (HL) and C as two's

ZF, CF

[M (HL)] + (CF)

complement values and
store the result in AC.

Add the contents of AC and

ADI i4

Add immediate data

1 1 0 0

1 1 1 1

(AC) +

the immediate data as two's

to AC

0 0 1 0

, I

complement values and store
the result in AC.

Subtract the contents of AC

CF will be zero if

SUBC

Subtract AC from M

0 0 0 1

0 1 1 1

[M (HL)]

and CF from M (HL) as two's

ZF, CF

there was a

with CF

(AC) (CF)

complement values and store

borrow and one

the result in AC.

otherwise.

And M with AC then

(AC)

Take the logical and of AC

ANDA

store AC

0 0 0 0

0 1 1 1

[M (HL)]

and M (HL) and store the

result in AC.

Or M with AC then

(AC)

Take the logical or of AC and

ORA

store AC

0 0 0 0

0 1 0 1

[M (HL)]

M (HL) and store the result

in AC.

Number of

bytes

Number of

cycles

Continued from preceding page.

No. 5486-20/26

LC66E2316

Continued on next page.

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Arithmetic, logic and comparison instructions]

Exclusive or M with

(AC)

Take the logical exclusive or

EXL

AC then store AC

0 0 0 1

0 1 0 1

[M (HL)]

of AC and M (HL) and store

the result in AC.

And M with AC then

M (HL)

(AC)

Take the logical and of AC

ANDM

store M

0 0 0 0

0 0 1 1

[M (HL)]

and M (HL) and store the

result in M (HL).

Or M with AC then

M (HL)

(AC)

Take the logical or of AC and

ORM

store M

0 0 0 0

0 1 0 0

[M (HL)]

M (HL) and store the result

in M (HL).

Compare the contents of AC
and M (HL) and set or clear CF
and ZF according to the result.

Compare AC with M

0 0 0 1

0 1 1 0

[M (HL)] + (AC) + 1

ZF, CF

Compare the contents of AC
and the immediate data
I

and set or clear CF

and ZF according to the result.

CI i4

Compare AC with

1 1 0 0

1 1 1 1

+ (AC) + 1

ZF, CF

immediate data

1 0 1 0

Compare the contents of DP

CLI i4

Compare DP

with

1 1 0 0

1 1 1 1

if (DP

) = I

with the immediate data.

immediate data

1 0 1 1

Set ZF if identical and clear

if (DP

) I

ZF if not.

if (AC, t2) = [M (HL), Compare the corresponding

CMB t2

Compare AC bit with

1 1 0 0

1 1 1 1

t2]

bits specified by t0 and t1 in

M data bit

1 1 0 1

0 0 t

AC and M (HL). Set ZF if

if (AC, t2) [M (HL),

identical and clear ZF if not.

t2]

[Load and store instructions]

LAE

Load AC and E from

0 1 0 1

1 1 0 0

M (HL),

Load the contents of M2 (HL)

M2 (HL)

M (HL + 1)

into AC, E.

LAI i4

Load AC with

1 0 0 0

Load the immediate data

Has a vertical

immediate data

into AC.

skip function

LADR i8

Load AC from M

1 1 0 0

0 0 0 1

[M (i8)]

Load the contents of M (i8)

direct

into AC.

Store AC to M

0 1 0 0

0 1 1 1

M (HL)

(AC)

Store the contents of AC into
M (HL).

SAE

Store AC and E to

0 1 0 1

1 1 1 0

M (HL)

(AC)

Store the contents of AC, E

M2 (HL)

M (HL + 1)

(E)

into M2 (HL).

Load the contents of M (reg)
into AC.
The reg is either HL or XY

Load AC from

depending on t

LA reg

M (reg)

0 1 0 0

1 0 t

[M (reg)]

Number of

bytes

Number of

cycles

Magnitude

CF ZF

comparison

[M (HL)] > (AC)

[M (HL)] = (AC)

[M (HL)] < (AC)

Magnitude

CF ZF

comparison

> AC

= AC

< AC

reg

Continued from preceding page.

No. 5486-21/26

LC66E2316

Continued on next page.

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Load and store instructions]

Load the contents of M (reg)
into AC. (The reg is either HL

ZF is set

Load AC from M (reg)

[M (reg)]

or XY.) Then increment the

according to the

LA reg, I

then increment reg

0 1 0 0

1 0 t

(DP

) + 1

contents of either DP

or DP

. ZF

result of

or DP

(DP

) + 1

The relationship between t

incrementing

and reg is the same as that

or DP

for the LA reg instruction.

Load the contents of M (reg)
into AC. (The reg is either HL

ZF is set

Load AC from M (reg)

[M (reg)]

or XY.) Then decrement the

according to the

LA reg, D

then decrement reg

0 1 0 1

1 0 t

(DP

) 1

contents of either DP

or DP

. ZF

result of

or DP

(DP

) 1

The relationship between t

decrementing

and reg is the same as that

or DP

for the LA reg instruction.

Exchange the contents of
M (reg) and AC.
The reg is either HL or XY

Exchange AC with

depending on t

XA reg

M (reg)

0 1 0 0

1 1 t

(AC)

[M (reg)]

Exchange the contents of
M (reg) and AC. (The reg is

ZF is set

Exchange AC with

(AC)

[M (reg)]

either HL or XY.) Then

according to the

XA reg, I M (reg) then

0 1 0 0

1 1 t

(DP

) + 1

increment the contents of

result of

increment reg

or DP

(DP

) + 1

either DP

or DP

. The

incrementing

relationship between t

and

or DP

reg is the same as that for
the XA reg instruction.

Exchange the contents of
M (reg) and AC. (The reg is

ZF is set

Exchange AC with

(AC)

[M (reg)]

either HL or XY.) Then

according to the

XA reg, D M (reg) then

0 1 0 1

1 1 t

(DP

) 1

decrement the contents of

result of

decrement reg

or DP

(DP

) 1

either DP

or DP

. The

decrementing

relationship between t

and

or DP

reg is the same as that for
the XA reg instruction.

XADR i8

Exchange AC with

1 1 0 0

1 0 0 0

(AC)

[M (i8)]

Exchange the contents of AC

M direct

and M (i8).

LEAI i8

Load E & AC with

1 1 0 0

0 1 1 0

Load the immediate data i8

immediate data

into E, AC.

Load into E, AC the ROM data

RTBL

Read table data from

0 1 0 1

1 0 1 0

E, AC

at the location determined by

program ROM

[ROM (PCh, E, AC)]

replacing the lower 8 bits of
the PC with E, AC.

Output from ports 4 and 5 the

Read table data from

Port 4, 5

ROM data at the location

RTBLP

program ROM then

0 1 0 1

1 0 0 0

[ROM (PCh, E, AC)]

determined by replacing the

output to P4, 5

lower 8 bits of the PC with
E, AC.

[Data pointer manipulation instructions]

Load DP

with zero

LDZ i4

and DP

with

0 1 1 0

Load zero into DP

and the

immediate data

DPL

immediate data i4 into DP

respectively

LHI i4

Load DP

with

1 1 0 0

1 1 1 1

Load the immediate data i4

immediate data

0 0 0 0

into DP

LLI i4

Load DP

with

1 1 0 0

1 1 1 1

Load the immediate data i4

immediate data

0 0 0 1

into DP

LHLI i8

Load DP

, DP

with

1 1 0 0

0 0 0 0

Load the immediate data into

immediate data

, DP

LXYI i8

Load DP

, DP

with

1 1 0 0

0 0 0 0

Load the immediate data into

immediate data

, DP

Number of

bytes

Number of

cycles

reg

Continued from preceding page.

No. 5486-22/26

LC66E2316

Continued on next page.

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Data pointer manipulation instructions]

Increment DP

0 0 0 1

(DP

) + 1

Increment the contents

of DP

Decrement DP

0 0 1 0

0 0 0 1

(DP

) 1

Decrement the contents

of DP

Increment DP

0 0 0 1

0 0 1 1

(DP

) + 1

Increment the contents

of DP

Decrement DP

0 0 1 0

0 0 1 1

(DP

) 1

Decrement the contents

of DP

TAH

Transfer AC to DP

1 1 0 0

1 1 1 1

(AC)

Transfer the contents of AC

1 1 1 1

0 0 0 0

to DP

THA

Transfer DP

to AC

1 1 0 0

1 1 1 1

(DP

)

Transfer the contents of DP

1 1 1 0

0 0 0 0

to AC.

XAH

Exchange AC

0 1 0 0

0 0 0 0

(AC)

(DP

)

Exchange the contents of AC

with DP

and DP

TAL

Transfer AC to DP

1 1 0 0

1 1 1 1

(AC)

Transfer the contents of AC

1 1 1 1

0 0 0 1

to DP

TLA

Transfer DP

to AC

1 1 0 0

1 1 1 1

(DP

)

Transfer the contents of DP

1 1 1 0

0 0 0 1

to AC.

XAL

Exchange AC

0 1 0 0

0 0 0 1

(AC)

(DP

)

Exchange the contents of AC

with DP

and DP

TAX

Transfer AC to DP

1 1 0 0

1 1 1 1

(AC)

Transfer the contents of AC

1 1 1 1

0 0 1 0

to DP

TXA

Transfer DP

to AC

1 1 0 0

1 1 1 1

(DP

)

Transfer the contents of DP

1 1 1 0

0 0 1 0

to AC.

XAX

Exchange AC

0 1 0 0

0 0 1 0

(AC)

(DP

)

Exchange the contents of AC

with DP

and DP

TAY

Transfer AC to DP

1 1 0 0

1 1 1 1

(AC)

Transfer the contents of AC

1 1 1 1

0 0 1 1

to DP

TYA

Transfer DP

to AC

1 1 0 0

1 1 1 1

(DP

)

Transfer the contents of DP

1 1 1 0

0 0 1 1

to AC.

XAY

Exchange AC

0 1 0 0

0 0 1 1

(AC)

(DP

)

Exchange the contents of AC

with DP

and DP

[Flag manipulation instructions]

SFB n4

Set flag bit

0 1 1 1

Set the flag specified
by n4 to 1.

RFB n4

Reset flag bit

0 0 1 1

Reset the flag specified

by n4 to 0.

[Jump and subroutine instructions]

PC13, 12

This becomes

JMP

Jump in the current

1 1 1 0 P

PC13, 12

Jump to the location in the

PC12 + (PC12)

addr

bank

PC11 to 0

same bank specified by the

immediately

to P

immediate data P12.

following a BANK
instruction.

Jump to the address

PC13 to 8

Jump to the location

JPEA

stored at E and AC

0 0 1 0

0 1 1 1

PC13 to 8,

determined by replacing the

in the current page

PC7 to 4

(E),

lower 8 bits of the PC

PC3 to 0

(AC)

by E, AC.

PC13 to 11

PC10 to 0

CAL

Call subroutine

0 1 0 1

0 P

to P

Call a subroutine.

addr

M4 (SP)

(CF, ZF, PC13 to 0),
SP

(SP)-4

PC13 to 6,
PC10

CZP

Call subroutine in the

1 0 1 0

PC5 to 2

to P

, Call a subroutine on page 0

addr

zero page

M4 (SP)

in bank 0.

(CF, ZF, PC12 to 0),
SP

SP-4

BANK

Change bank

0 0 0 1

1 0 1 1

Change the memory bank
and register bank.

Number of

bytes

Number of

cycles

Continued from preceding page.

No. 5486-23/26

LC66E2316

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Jump and subroutine instructions]

Store the contents of reg in
M2 (SP). Subtract 2 from SP
after the store.

PUSH

Push reg on M2 (SP)

1 1 0 0

1 1 1 1

M2 (SP)

(reg)

reg

1 1 1 1

1 i

(SP) 2

Add 2 to SP and then load the

POP

1 1 0 0

1 1 1 1

(SP) + 2

contents of M2(SP) into reg.

reg

Pop reg off M2 (SP)

1 1 1 0

1 i

reg

[M2 (SP)]

The relation between i1i0 and
reg is the same as that for the
PUSH reg instruction.

Return from

(SP) + 4

Return from a subroutine or

subroutine

0 0 0 1

1 1 0 0

[M4 (SP)]

interrupt handling routine. ZF
and CF are not restored.

Return from interrupt

(SP) + 4

Return from a subroutine or

RTI

routine

0 0 0 1

1 1 0 1

[M4 (SP)]

interrupt handling routine. ZF

ZF, CF

CF, ZF

[M4 (SP)]

and CF are restored.

[Branch instructions]

PC7 to 0

Branch to the location in the

BAt2

Branch on AC bit

1 1 0 1

0 0 t

same page specified by P

addr

if the bit in AC specified by

if (AC, t2) = 1

the immediate data t

is one.

PC7 to 0

Branch to the location in the

BNAt2

Branch on no AC bit

1 0 0 1

0 0 t

same page specified by P

addr

if the bit in AC specified by

if (AC, t2) = 0

the immediate data t

is zero.

PC7 to 0

Branch to the location in the

BMt2

1 1 0 1

0 1 t

same page specified by P

addr

Branch on M bit

if the bit in M (HL) specified

if [M (HL),t2]

by the immediate data t

= 1

is one.

PC7 to 0

Branch to the location in the

BNMt2

1 0 0 1

0 1 t

same page specified by P

addr

Branch on no M bit

if the bit in M (HL) specified

if [M (HL),t2]

by the immediate data t

= 0

is zero.

Internal control
registers can also
be tested by

PC7 to 0

Branch to the location in the

executing this

same page specified by P

instruction

BPt2

Branch on Port bit

1 1 0 1

1 0 t

if the bit in port (DP

)

immediately after

addr

if [P (DP

), t2]

specified by the immediate

a BANK

= 1

data t

is one.

instruction.
However, this is
limited to
registers that can
be read out.

Internal control
registers can also
be tested by

PC7 to 0

Branch to the location in the

executing this

same page specified by P

instruction

BNPt2

Branch on no Port bit

1 0 0 1

1 0 t

if the bit in port (DP

)

immediately after

addr

if [P (DP

), t2]

specified by the immediate

a BANK

= 0

data t

is zero.

instruction.
However, this is
limited to
registers that can
be read out.

Number of

bytes

Number of

cycles

Continued on next page.

reg

Illegal value

Continued from preceding page.

No. 5486-24/26

LC66E2316

Continued on next page.

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Branch instructions]

PC7 to 0

Branch to the location in the

BC addr

Branch on CF

1 1 0 1

1 1 0 0

same page specified by P

if CF is one.

if (CF) = 1

PC7 to 0

Branch to the location in the

BNC

Branch on no CF

1 0 0 1

1 1 0 0

same page specified by P

addr

if CF is zero.

if (CF) = 0

PC7 to 0

Branch to the location in the

BZ addr

Branch on ZF

1 1 0 1

same page specified by P

if ZF is one.

if (ZF) = 1

PC7 to 0

Branch to the location in the

BNZ

Branch on no ZF

1 0 0 1

1 1 0 1

same page specified by P

addr

if ZF is zero.

if (ZF) = 0

PC7 to 0

Branch to the location in the

BFn4

1 1 1 1

same page specified by P

addr

Branch on flag bit

if the flag (of the 16 user

if (Fn) = 1

flags) specified by n

is one.

PC7 to 0

Branch to the location in the

BNFn4

1 0 1 1

same page specified by P

addr

Branch on no flag bit

if the flag (of the 16 user

if (Fn) = 0

flags) specified by n

is zero.

[I/O instructions]

IP0

Input port 0 to AC

0 0 1 0

0 0 0 0

(P0)

Input the contents of port

0 to AC.

Input port to AC

0 0 1 0

0 1 1 0

[P (DP

)]

Input the contents of port

P (DP

) to AC.

IPM

Input port to M

0 0 0 1

1 0 0 1

M (HL)

[P (DP

)]

Input the contents of port
P (DP

) to M (HL).

IPDR i4

Input port to

1 1 0 0

1 1 1 1

[P (i4)]

Input the contents of

AC direct

0 1 1 0

P (i4) to AC.

Input port 4, 5 to

1 1 0 0

1 1 1 1

[P (4)]

Input the contents of ports

IP45

E, AC respectively

1 1 0 1

0 1 0 0

[P (5)]

P (4) and P (5) to E and AC
respectively.

Output AC to port

0 0 1 0

0 1 0 1

P (DP

)

(AC)

Output the contents of AC to
port P (DP

OPM

Output M to port

0 0 0 1

1 0 1 0

P (DP

)

[M (HL)]

Output the contents of M (HL)
to port P (DP

OPDR i4

Output AC to

1 1 0 0

1 1 1 1

P (i4)

(AC)

Output the contents of AC

port direct

0 1 1 1

to P (i4).

Output E, AC to port

1 1 0 0

1 1 1 1

P (4)

(E)

Output the contents of E and

OP45

4, 5 respectively

1 1 0 1

0 1 0 1

P (5)

(AC)

AC to ports P (4) and P (5)
respectively.

Set to one the bit in port

SPB t2

Set port bit

0 0 0 0

1 0 t

[P (DP

), t2]

P (DP

) specified by the

immediate data t

Clear to zero the bit in port

RPB t2

Reset port bit

0 0 1 0

1 0 t

[P (DP

), t2]

P (DP

) specified by the

immediate data t

And port with

P (P

to P

)

Take the logical AND of P (P

ANDPDR

immediate data then

1 1 0 0

0 1 0 1

[P (P

to P

)]

to P

) and the immediate data

i4, p4

output

to I

and output the result

to P (P

to P

Or port with

P (P

to P

)

Take the logical OR of P (P

ORPDR

immediate data then

1 1 0 0

0 1 0 0

[P (P

to P

)]

to P

) and the immediate data ZF

i4, p4

output

to I

and output the result

to P (P

to P

Number of

bytes

Number of

cycles

Continued from preceding page.

No. 5486-25/26

LC66E2316

Instruction code

Affected

Mnemonic

Operation

Description

status

Note

bits

[Timer control instructions]

TIMER0

[M2 (HL)],

Write the contents of M2 (HL),

WTTM0

Write timer 0

1 1 0 0

1 0 1 0

(AC)

AC into the timer 0 reload
register.

1 1 0 0

1 1 1 1

Write the contents of E, AC

WTTM1

Write timer 1

1 1 1 1

0 1 0 0

TIMER1

(E), (AC)

into the timer 1 reload
register A.

M2 (HL),

Read out the contents of the

RTIM0

Read timer 0

1 1 0 0

1 0 1 1

(TIMER0)

timer 0 counter into M2 (HL),
AC.

RTIM1

Read timer 1

1 1 0 0

1 1 1 1

E, AC

(TIMER1)

Read out the contents of the

1 1 1 1

0 1 0 1

timer 1 counter into E, AC.

START0 Start timer 0

1 1 0 0

1 1 1 1

Start timer 0 counter

Start the timer 0 counter.

1 1 1 0

0 1 1 0

START1 Start timer 1

1 1 0 0

1 1 1 1

Start timer 1 counter

Start the timer 1 counter.

1 1 1 0

0 1 1 1

STOP0

Stop timer 0

1 1 0 0

1 1 1 1

Stop timer 0 counter

Stop the timer 0 counter.

1 1 1 1

0 1 1 0

STOP1

Stop timer 1

1 1 0 0

1 1 1 1

Stop timer 1 counter

Stop the timer 1 counter.

1 1 1 1

0 1 1 1

[Interrupt control instructions]

MSET

Set interrupt master

1 1 0 0

1 1 0 1

MSE

Set the interrupt master

enable flag

0 1 0 1

0 0 0 0

enable flag to one.

MRESET

Reset interrupt

1 1 0 0

1 1 0 1

MSE

Clear the interrupt master

master enable flag

1 0 0 1

0 0 0 0

enable flag to zero.

EIH i4

Enable interrupt high

1 1 0 0

1 1 0 1

EDIH

(EDIH) i4

Set the interrupt enable flag

0 1 0 1

to one.

EIL i4

Enable interrupt low

1 1 0 0

1 1 0 1

EDIL

(EDIL) i4

Set the interrupt enable flag

0 1 0 0

to one.

DIH i4

Disable interrupt high

1 1 0 0

1 1 0 1

EDIH

(EDIH) i4

Clear the interrupt enable

1 0 0 1

flag to zero.

DIL i4

Disable interrupt low

1 1 0 0

1 1 0 1

EDIL

(EDIL) i4

Clear the interrupt enable

1 0 0 0

flag to zero.

WTSP

Write SP

1 1 0 0

1 1 1 1

(E), (AC)

Transfer the contents of E,

1 1 0 1

1 0 1 0

AC to SP.

RSP

Read SP

1 1 0 0

1 1 1 1

E, AC

(SP)

Transfer the contents of SP

1 1 0 1

1 0 1 1

to E, AC.

[Standby control instructions]

HALT

1 1 0 0

1 1 1 1

HALT

Enter halt mode.

1 1 0 1

1 1 1 0

HOLD

1 1 0 0

1 1 1 1

HOLD

Enter hold mode.

1 1 0 1

1 1 1 1

[Serial I/O control instructions]

STARTS Start serial I O

1 1 0 0

1 1 1 1

START SI O

Start SIO operation.

1 1 1 0

WTSIO

Write serial I O

1 1 0 0

1 1 1 1

SIO

(E), (AC)

Write the contents of E,

1 1 1 0

1 1 1 1

AC to SIO.

RSIO

Read serial I O

1 1 0 0

1 1 1 1

E, AC

(SIO)

Read out the contents of SIO

1 1 1 1

into E, AC.

[Other instructions]

Consume one machine cycle

NOP

No operation

0 0 0 0

No operation

without performing any
operation.

SB i2

Select bank

1 1 0 0

1 1 1 1

PC13, PC12

Specify the memory bank.

1 1 0 0

0 0 I

Number of

bytes

Number of

cycles

No. 5486-26/26

LC66E2316

This catalog provides information as of February, 1997. Specifications and information herein are subject to
change without notice.

No products described or contained herein are intended for use in surgical implants, life-support systems, aerospace
equipment, nuclear power control systems, vehicles, disaster/crime-prevention equipment and the like, the failure of
which may directly or indirectly cause injury, death or property loss.

Anyone purchasing any products described or contained herein for an above-mentioned use shall:

Accept full responsibility and indemnify and defend SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and
distributors and all their officers and employees, jointly and severally, against any and all claims and litigation and all
damages, cost and expenses associated with such use:

Not impose any responsibility for any fault or negligence which may be cited in any such claim or litigation on
SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and distributors or any of their officers and employees
jointly or severally.

Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed for
volume production. SANYO believes information herein is accurate and reliable, but no guarantees are made or implied
regarding its use or any infringements of intellectual property rights or other rights of third parties.

Ð­Ð»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: LC66P2316

ÐÐ»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: LC66P2316