SANYO LC78601E

Ordering number : EN6020
CMOS IC
LC78601E
Compact Disc Player DSP with
Built-in Microcontroller
Overview
The LC78601E CMOS IC implements compact disc
player signal processing, servo control, LCD display, key
input acquisition, and remote controller processing
without requiring control by a separate microcontroller.
The basic functions provided include demodulation of the
EFM signal from the optical pickup, deinterleaving, error
detection and correction, 8× oversampling digital filters,
D/A converter (with built-in analog low-pass filter), LCD
driver, remote controller processing, key acquisition, and
control processing. Thus this IC can provide excellent
cost/performance characteristics when implementing a
low-end CD player.
Functions
• Implements CD play/pause, disc stop, track selection,
fast forward, reverse, repeat mode playback of 1 track or
the whole disc, programmed play (setup, play, and clear)
of up to 16 tracks, and random repeat play under the
control of key input or remote controller input.
<Signal-Processing Block>
• Slices an input high-frequency signal at an accurate
level, converts the EFM signal, and generates a clock
with an average frequency of 4.3218 MHz using a PLL
circuit that performs a phase comparison with an
internal VCO.
• Accurately generates not only the reference clock but
also all necessary internal timings using an external
16.9344MHz crystal.
• Controls the disc motor speed using a frame difference
signal created based on the reproduced clock signal and
a reference clock.
• Performs detection, protection, and interpolation for the
frame synchronizing signal to assure stable data readout.
• Demodulates the EFM signal, converting it to 8-bit
symbol data.
• Separates the subcode data from the EFM signal and
outputs that data to the internal control processing block.
• After applying a CRC check to the subcode Q signal,
outputs that signal to the internal control processing
block.
• Buffers the demodulated EFM signal data in internal
RAM and compensates for ±4 frames of jitter due to
disc speed fluctuations.
• Performs unscrambling and deinterleaving by reordering
the demodulated EFM signal data to the stipulated order.
• Performs error detection and correction and flag
processing (C1: dual errors, C2: dual errors)
• The C2 flags are set based on the C1 flags and the result
of the C2 processing, and the signal is interpolated or
previous value hold is applied based on the C2 flags.
Dual interpolation is adopted in the interpolation circuit.
Previous value hold is applied if two or more
consecutive errors are indicated by the C2 flags.
• Performs track jump, focus start, disc motor start/stop,
muting on/off, track count, and other operations under
control of the internal control processing block.
• Provides digital outputs.
• Generates D/A converter input signals with continuity
improved by 8× oversampling digital filters.
• Includes on-chip third-order noise shaper delta-sigma
D/A converters with built-in analog low-pass filter.
• Digital deemphasis circuit
• Adopts zero-cross muting.
<Display Block>
• On-chip LCD drivers for 2-digit display plus play,
program, repeat, and random indicators
• On-chip bias voltage generator
<Control Processing Block>
• Key matrix circuit with 4 inputs and 2 outputs for an
8-key matrix
• Supports remote controller input.
Any and all SANYO products described or contained herein do not have specifications that can handle
applications that require extremely high levels of reliability, such as life-support systems, aircraft’s
control systems, or other applications whose failure can be reasonably expected to result in serious
physical and/or material damage. Consult with your SANYO representative nearest you before using
any SANYO products described or contained herein in such applications.
SANYO assumes no responsibility for equipment failures that result from using products at values that
exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges, or other
parameters) listed in products specifications of any and all SANYO products described or contained
herein.
SANYO Electric Co.,Ltd. Semiconductor Bussiness Headquarters
TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110-8534 JAPAN
D1898RM (OT) No. 6020-1/11
LC78601E
Features
Package Dimensions
• Package: 64-pin QFP
• 5-V single-voltage power supply
unit: mm
3159-QFP64E
[LC78601E]
SANYO: QFP64E(QIP64E)
Equivalent Circuit Block Diagram
Slice level
control
VCO clock
oscillator
Clock control
RAM address
generator
Interpolation
and muting
Synchronization
detection
EFM demodulation
CLV digital
servo
Bilingual support circuit
C1 and C2 error detection
and correction
Flag processing
Digital output circuit
Subcode
separator QCRC
Digital
attenuator
8 × oversampling
digital filters
Servo commander
Crystal oscillator
circuit
Timing generator
System control
LCD driver
No. 6020-2/11
LC78601E
Pin Assignment
Top view
Specifications
Absolute Maximum Ratings at Ta = 25°C, VSS = 0 V
Parameter
Maximum supply voltage
Input voltage
Output voltage
Allowable power dissipation
Ratings
Unit
VDD max
Symbol
Conditions
VSS – 0.3 to VSS + 7.0
V
VIN
VSS – 0.3 to VSS + 0.3
V
VOUT
VSS – 0.3 to VSS + 0.3
Pd max
V
300
mW
Operating temperature
Topr
–20 to +75
°C
Storage temperature
Tstg
–40 to +125
°C
Allowable Operating Ranges at Ta = –20 to +75°C, VDD = 4.5 to 5.5 V, VSS = 0 V
Parameter
Supply voltage
High-level input voltage
Low-level input voltage
Input level
Symbol
Conditions
VDD
VDD, XVDD, L/RVDD, VVDD
Normal speed playback
typ
max
Unit
4.5
5.5
V
VIH1
DEFI, 3 V/*5 V, TMOD, *RES, HFL, TES
0.7 VDD
VDD
V
VIH2
*KEYI1 to 4
0.8 VDD
VDD
V
VIH3
EFMIN
0.6 VDD
VDD
V
VIH4
PUIN, RMTSL1 to 3, REMOTE, CLOSE, DRF
0.8 VDD
VDD
V
VIL1
DEFI, 3 V/*5 V, TMOD, *RES, HFL, TES
0
0.3 VDD
V
VIL2
*KEYI1 to 4
0
0.5 VDD
V
VIL3
EFMIN
0
0.4 VDD
V
VIL4
PUIN, RMTSL1 to 3, REMOTE, CLOSE, DRF
0
0.2 VDD
VIN1
EFMIN: Slice level control
1.0
1.0
VIN2
XIN: Capacitor coupled input
Operating frequency range
fOP
EFMIN
Crystal oscillator frequency
fX
XIN, XOUT
Input voltage
Ratings
min
VLCD1
V
Vp-p
Vp-p
10
16.9344
0.5 VDD
MHz
MHz
VDD
V
No. 6020-3/11
LC78601E
Electrical Characteristics at Ta = –20 to +75°C, VDD = 4.5 to 5.5 V, VSS = 0 V
Parameter
Current drain
High-level input current
Low-level input current
Symbol
Pull-down resistance
Charge pump output current
Ratings
min
typ
Unit
max
VDD, XVDD, L/RVDD, VVDD
IIH1
DEFI, 3 V/*5 V, EFMIN, TMOD, HFL,
TES, PUIN, *KEYI1 to 4, RMTSL1 to 3, VIN = VDD
REMOTE, CLOSE, *RES, DRF
IIH2
LASER, FSTA, EFBAL, SP8
VIN = VDD
250
IIL1
DEFI, 3 V/*5 V, EFMIN, TMOD, HFL,
TES, RMTSL2 to 3, REMOTE, *RES,
DRF
VIN = 0 V
–5
IIL2
PUIN, *KEYI1 to 4, RMTSL1, CLOSE
VIN = 0 V
–25
VOH1
EFMO, CLV, TOFF, TGL, JP, LASER,
FSTA, EFBAL, SP8, FSEQ, PCK,
SLOF, SLED+, SLED–, EFLG, FSX,
*AMUTE
IOH = –1 mA
0.8 VDD
V
VOH2
S1 to 6
IOH = –0.02 mA
0.8 VDD
V
VOH3
COM1 to 3
IOH = – 0.1 mA
0.8 VDD
V
VOH4
DOUT
IOH = –12 mA
0.9 VDD
V
VOL1
EFMO, CLV, TOFF, TGL, JP, FSEQ,
PCK, SLOF, SLED+, SLED–,
*KEYO1 to 2, EFLG, FSX,
RMTSL2 to 3, *AMUTE
IOL = 1 mA
0.2 VDD
V
VOL2
*RANDOM
IOL = 8 mA
0.2 VDD
V
VOL3
S1 to 6
IOL = 0.02 mA
0.2 VDD
V
VOL4
COM1 to 3
IOL = 0.1 mA
0.2 VDD
V
VOL5
DOUT
IOL = 12 mA
0.1 VDD
V
IOFFH
PDO, CLV, JP, *KEY01 to 2,
*RANDOM
VOUT = VDD
5
µA
IOFFL
PDO, CLV, JP, *KEY01 to 2,
*RANDOM
VOUT = 0 V
RPU
PUIN, *KEYI1 to 4, RMTSL1, CLOSE,
*RES
RPD
LASER, FSTA, EFBAL, SP8
Output off leakage current
Pull-up resistance
Conditions
IDD
High-level output voltage
Low-level output voltage
Applicable pins
35
500
55
mA
5
µA
1000
µA
µA
–50
–100
–5
µA
µA
100
kΩ
10
kΩ
IPDOH
PDO
RISET = 68 kΩ
64
80
96
µA
IPDOL
PDO
RISET = 68 kΩ
–96
–80
–64
µA
1-Bit D/A Converter Analog Characteristics at Ta = 25°C, VDD = L/RVDD = 5 V, VSS = L/RVSS = 0 V
Parameter
Ratings
Symbol
Applicable pins
Conditions
THD+N
LCHO, RCHO
1 kHz: 0dB data input
20kHz low-pass filter used (built-in AD725D)
Dynamic range
DR
LCHO, RCHO
1 kHz: –60dB data input
20kHz low-pass filter and A filter used (built-in AD725D)
86
88
dB
Signal-to-noise ratio
S/N
LCHO, RCHO
1 kHz: 0dB data input
20kHz low-pass filter and A filter used (built-in AD725D)
96
98
dB
Crosstalk
CT
LCHO, RCHO
1 kHz: 0dB data input
20kHz low-pass filter used (built-in AD725D)
80
82
dB
Total harmonic distortion
min
typ
0.02
max
0.035
Unit
%
Note: Measure in normal speed playback mode with the Sanyo 1-bit D/A converter block reference circuit.
No. 6020-4/11
LC78601E
1-Bit D/A Converter Output Block Reference Circuit
Analog output
Left channel
(right channel)
AD725D
(Manufactured by
Shibasoku Ltd.)
Oscillator
element
Oscillator element: 16.9344 MHz
The following oscillator elements are recommended
CSA-309 <C = 8 pF> (Citizen Watch Co., Ltd.)
CSA16.93MXZ040 (C = 15 pF) (Murata Mfg. Co., Ltd.)
CSA16.93MXZ0C3 (built-in capacitor)
(Murata Mfg. Co., Ltd.)
No. 6020-5/11
LC78601E
Pin Functions
Pin No.
Pin
I/O
1
DEFI
I
Defect detection signal (DEF) input. (Must be connected to 0 V if unused.)
Function
2
3 V/*5 V
I
Supply voltage selection input. (High: 3V operation, low: 5V operation)
3
PDO
O
Internal VCO control phase comparator output
Pin state during reset
—
—
Undefined
4
VVSS
—
5
ISET
AI
6
VVDD
7
FR
8
VSS
—
Digital system ground. This pin must be connected to 0 V.
—
9
EFMO
O
Undefined
10
EFMIN
I
Slice level
control pins
EFM signal output
11
TMOD
I
Test input. This pin must be connected to 0 V.
Internal VCO ground. This pin must be connected to 0 V.
—
PDO output current adjustment resistor connection
—
—
Internal VCO power supply
—
AI
VCO frequency range adjustment
—
PLL circuit pins
EFM signal input
—
—
12
CLV
O
Disc motor control output. This is a 3-value output.
13
HFL
I
Track detection signal input. This is a Schmitt input.
Hi-Z
—
14
TES
I
Tracking error signal input. This is a Schmitt input.
—
15
TOFF
O
Tracking off output
High output
16
TGL
O
Tracking gain switching output. A low level output raises the gain.
Undefined
17
JP
O
Track jump control output. This is a 3-value output.
18
LASER
O
Laser control. A pull-down resistor is built in.
Pulled down
19
FSTA
O
FSTA control. A pull-down resistor is built in.
Pulled down
20
EFBAL
O
EFBAL control. A pull-down resistor is built in.
Pulled down
21
SP8
O
SP8 control. A pull-down resistor is built in.
Pulled down
22
VDD
—
Digital system power supply
Undefined
Hi-Z
—
23
FSEQ
O
Synchronizing signal detection output. Outputs a high level if the synchronizing signal detected
from the EFM signal and the internally generated synchronizing signal match.
24
PCK
O
EFM data playback clock monitor. 4.3218 MHz when the phase is locked.
(Note that this output is only provided in test mode. This pin outputs a low level during normal
mode operation.)
Low output
25
SLOF
O
Sled off control output
High output
26
SLED+
O
27
SLED–
O
Sled feed output
Low output
Low output
28
PUIN
I
Limit switch detection input
—
29
DOUT
O
Digital output (EIAJ format)
Undefined
30
S6
O
Segment output (6)
Low output
31
S5
O
Segment output (5)
Low output
32
S4
O
Segment output (4)
Low output
33
S3
O
Segment output (3)
Low output
34
S2
O
Segment output (2)
Low output
35
S1
O
Segment output (1)
Low output
36
COM3
O
Common driver output (3)
Low output
37
COM2
O
Common driver output (2)
Low output
Low output
38
COM1
O
Common driver output (1)
39
VSS
—
Digital system ground. This pin must be connected to 0 V.
—
40
VLCD1
—
LCD drive bias 1/2 VDD monitor
—
41
*KEYI4
I
Key matrix input (4). A pull-up resistor is built in.
—
42
*KEYI3
I
Key matrix input (3). A pull-up resistor is built in.
—
43
*KEYI2
I
Key matrix input (2). A pull-up resistor is built in.
—
44
*KEYI1
I
Key matrix input (1). A pull-up resistor is built in.
45
*KEYO1
O
Key matrix common output (1). This is an open-drain output.
—
Hi-Z
46
*KEYO2
O
Key matrix common output (2). This is an open-drain output.
Hi-Z
47
*RANDOM
O
Random mode indicator output (Low: random mode, high: modes other than random mode.)
Hi-Z
48
RMTSL3
I/O
Remote controller identifier input (3). This pin functions as an output pin set to the low level
during resets (when the *RES pin is low) and for a few milliseconds after the *RES pin
switches to the high level. Therefore, applications that will set this pin high must connect an
external pull-up resistor to this pin.
Low output
Continued on next page.
No. 6020-6/11
LC78601E
Continued from preceding page.
Pin No.
Pin
I/O
Function
Pin state during reset
49
EFLG
O
Monitor for C1, C2, single, and double error corrections.
(Note that this output is only provided in test mode. This pin outputs a low level during normal
mode operation.)
50
FSX
O
Outputs a 7.35 kHz synchronizing signal that is generated by dividing the crystal oscillator output.
(Note that this output is only provided in test mode. This pin outputs a low level during normal
mode operation.)
Low output
51
*AMUTE
O
Audio mute output signal
Low output
52
REMOTE
I
Remote controller signal input
53
RMTSL2
Low output
—
I/O
Remote controller identifier input (2). This pin functions as an output pin set to the low level
during resets (when the *RES pin is low) and for a few milliseconds after the *RES pin
switches to the high level. Therefore, applications that will set this pin high must connect an
external pull-up resistor to this pin.
Low output
Undefined
54
LCHO
O
Left channel D/A converter output
55
L/RVDD
—
D/A converter power supply
56
L/RVSS
—
D/A converter ground. This pin must be connected to 0 V.
57
RCHO
O
Right channel D/A converter output
—
—
Undefined
58
CLOSE
I
Close switch detection input. A pull-up resistor is built in.
—
59
RMTSL1
I
Remote controller identifier input (1). A pull-up resistor is built in.
—
60
XOUT
O
61
XIN
I
62
XVDD
—
63
*RES
64
DRF
Connections for a 16.9344 crystal element
Clock output
—
Crystal oscillator circuit power supply
—
I
IC reset input. Applications must set this pin low temporarily when power is first applied.
—
I
DRF input. (Connected when an LA9250M is used.)
—
Note: The same potential must be connected to all the power supply pins (VDD, VVDD, L/RVDD, and XVDD).
No. 6020-7/11
Note: This circuit is an example of typical connections used with the LC78601E, but is not a complete circuit, i.e. certain peripheral components and circuits have been omitted.
Contact your Sanyo representative for detailed information on this circuit.
Sample Application Circuit
LC78601E
No. 6020-8/11
LC78601E
Notes on Application Design
It goes without saying that applications must strictly observe the absolute maximum ratings and allowable operating
ranges (and recommended operating conditions) stipulated for this IC to achieve reliability as a system. However, we
also strongly recommend that designers carefully consider both the mounting conditions and the actual usage
environment, including ambient temperatures and static electricity, when designing applications.
This section provides additional notes concerning design, mounting, and certain other points that require care during
application design.
1. Handling of Unused Pins
If any unused pins on this IC are left in the open state, certain internal states may become undefined. Unused pins for
which the handling is specified in the documentation must be handled as specified. Also be sure that no output pins
contact any power supply or ground lines or any other output pin.
2. Latch-up Prevention
• Due to the internal structure of this IC, the same potential must be applied to all power supply pins.
— Also provide the same potential to the servo system ASP. Since the slice level control circuit is shared with this IC,
the same power supply potential must be applied. Also be sure to apply the same potential to all ASP power supply
pins.
— For products in which the power supply pins are completely isolated within the IC and special allowances apply, be
sure to follow the detailed instructions in the documentation.
• The IC may latch up if timing discrepancies appear between the rise times for different power supply pins. Design
applications so that no discrepancies appear.
• Do not raise the voltage of any input or output pin above the VDD level, and do not lower the voltage below VSS. This
point requires special care when power is first applied.
• Do not allow overvoltages or abnormal signal noise levels to be applied to this IC.
• In general, latch-up can be prevented by tying unused input pins to VDD or VSS. However, the directions for unused pin
handling in the documentation for this IC must be followed.
• Do not short the outputs.
3. Interface
When different devices are connected, incorrect operation may result if the input VIL and VIH and the output VOL and
VOH levels do not match. Insert level shifters so that the IC is not destroyed if it is connected to a device that uses a
different power-supply voltage, such as in a dual power supply system applications.
4. Load Capacitance and Output Current
• If a load with a large capacitance is connected, the wiring may fuse since such a load can result in the equivalent of an
output short for an extended period. Also, excessive charge and discharge currents can cause noise and degrade
application performance or lead to incorrect operation. Use loads of the recommended capacitance.
• Excessive output sink or source currents can lead to problems similar to those described above. Use this IC within the
recommended current levels while taking the maximum allowable power dissipation into consideration as well.
5. Notes on Power Application and Reset
• There are cases where care is required at power on, during a reset, and when the reset state is cleared. Refer to the
specifications sheet for the product and observe the notes concerning power on and IC reset.
• The pin output states, the pin I/O direction settings, and the contents of the registers are not guaranteed when power is
first applied in this IC. Items that are defined by the reset operation and when the mode is set are guaranteed after that
operation. Applications must first apply a reset to this IC after power is applied. Since pin states and register contents
that are not defined by the reset operation may change over time from the states in early versions due to long term
variations across lots, applications should not depend on these values.
No. 6020-9/11
LC78601E
6. Notes on Thermal Design
The failure rate of semiconductor devices is accelerated by higher ambient temperatures and power dissipation levels.
We strongly recommend taking changes in ambient conditions into account and providing as large a margin as
possible in thermal design to assure high reliability.
7. Notes on Printed Circuit Board Pattern Design
• Ideally, the influence of shared impedances should be minimized by separating the VDD and ground lines for each
system.
• Design VDD and ground lines to be as short and as wide as possible, and to have the lowest high-frequency impedance
possible. Ideally, decoupling capacitors (0.01 to 1 µF) should be inserted in each VDD/ground pair. These capacitor
should be placed as close to the corresponding VDD pin as possible. It is also appropriate to insert capacitors of about
100 to 220 µF between each VDD and ground as low-frequency filters. However, be careful not to use values that are
too large for these capacitors, since that can result in latch-up.
— In the servo system, the reference voltage line (VREF) and the driver VCC and ground lines are handled in the same
way. The driver ground line should be made especially wide. If at all possible, use the recommended driver pattern,
which, being directly under the device, was also designed to provide a heat dissipation effect as well.
— If a current output pickup is used, locate the optical pickup element connector and the ASP RF input as close
together as possible. Even if a voltage output type pickup is used, the I/V conversion resistor located at the ASP
input should be located near the ASP RF input.
• The EFM signal line should be made as short as possible, and should either be located away from adjacent lines or
should be shielded from adjacent lines by VSS or VDD shield lines.
Since the slice level control output (EFMO) can easily disrupt the EFM signal line, the resistor connected to the output
pin should be located as close to the pin as possible. Note that reducing the value of this resistor increases the influence
of spurious radiation and cares must be taken for the output level when the value increases.
• Cover the area around the crystal with the ground pattern.
8. Other Notes
If you have any questions during the application design phase, do not hesitate to contact your Sanyo sales
representative or the nearest Sanyo semiconductor sales office.
This IC is specifically designed for use in CD players, and as such its specifications differ from those of generalpurpose product standard logic ICs. We recommend system debugging using the end product system itself and
adopting failsafe system design if required by the application.
No. 6020-10/11
LC78601E
Specifications of any and all SANYO products described or contained herein stipulate the performance,
characteristics, and functions of the described products in the independent state, and are not guarantees
of the performance, characteristics, and functions of the described products as mounted in the customer’s
products or equipment. To verify symptoms and states that cannot be evaluated in an independent device,
the customer should always evaluate and test devices mounted in the customer’s products or equipment.
SANYO Electric Co., Ltd. strives to supply high-quality high-reliability products. However, any and all
semiconductor products fail with some probability. It is possible that these probabilistic failures could
give rise to accidents or events that could endanger human lives, that could give rise to smoke or fire,
or that could cause damage to other property. When designing equipment, adopt safety measures so
that these kinds of accidents or events cannot occur. Such measures include but are not limited to protective
circuits and error prevention circuits for safe design, redundant design, and structural design.
In the event that any or all SANYO products (including technical data, services) described or contained
herein are controlled under any of applicable local export control laws and regulations, such products must
not be exported without obtaining the export license from the authorities concerned in accordance with the
above law.
No part of this publication may be reproduced or transmitted in any form or by any means, electronic or
mechanical, including photocopying and recording, or any information storage or retrieval system,
or otherwise, without the prior written permission of SANYO Electric Co., Ltd.
Any and all information described or contained herein are subject to change without notice due to
product/technology improvement, etc. When designing equipment, refer to the “Delivery Specification”
for the SANYO product that you intend to use.
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.
This catalog provides information as of December, 1998. Specifications and information herein are
subject to change without notice.
PS No. 6020-11/11