W567J300 [NUVOTON]
6-CHANNEL SPEECHMELODY PROCESSOR;型号: | W567J300 |
厂家: | NUVOTON |
描述: | 6-CHANNEL SPEECHMELODY PROCESSOR |
文件: | 总13页 (文件大小:638K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
W567JXXX Data Sheet
6-CHANNEL SPEECH+MELODY PROCESSOR
(BandDirectorTM Series)
Table of Contents-
1.
2.
3.
4.
5.
6.
GENERAL DESCRIPTION.......................................................................................................................2
FEATURES ..............................................................................................................................................3
PIN DESCRIPTION..................................................................................................................................4
BLOCK DIAGRAM ...................................................................................................................................5
ITEM VS PIN TABLE................................................................................................................................6
ELECTRICAL CHARACTERISTICS........................................................................................................7
6.1 Absolute Maximum Ratings............................................................................................................7
6.2 DC Characteristics..........................................................................................................................7
6.3 AC Characteristics ..........................................................................................................................8
7.
8.
TYPICAL APPLICATION CIRCUIT..........................................................................................................9
REVISION HISTORY .............................................................................................................................12
Publication Release Date Sep. 2012
- 1 -
Revision A12
W567JXXX
1. GENERAL DESCRIPTION
The W567Jxxx is a powerful microcontroller (uC) dedicated to speech and melody synthesis
applications. With the help of the embedded 8-bit microprocessor & dedicated H/W, the W567Jxxx can
synthesize 6-channel speech+melody simultaneously.
The two channels of synthesized speech can be in different kinds of format, for example ADPCM
and MDPCM. The W567Jxxx can provide 6-channel high-quality WinMelodyTM , which can emulate
the characteristics of musical instruments, such as piano and violin. The output of speech/melody
channels are mixed together through the on-chip digital mixer to produce colorful effects. With these
hardware resources, the W567Jxxx is very suitable for high-quality and sophisticated scenario
applications.
The W567Jxxx provides at most 24 bi-directional I/Os, 256 bytes RAM , IR carrier, Serial Interface
Management and more sophisticated applications, such as interactive toys, cartridge toys and final
count down function. 3 LED output pins with 256-level control means that numerous combination of
RGB colors may result in a versatility of colorful effects. In addition, W567Jxxx also provides PWM
mode output to save power during playback and Watch Dog Timer to prevent latch-up situation
occurring.
The W567Jxxx family contains several items with different playback duration as shown below.
Item
*Duration
Item
W567J070
81 sec.
W567J080
102 sec.
W567J100
115 sec.
W567J120
127 sec.
W567J151
162 sec.
W567J171
196 sec.
W567J210
230 sec.
W567J260
263 sec.
W567J300
320 sec.
W567J340
358 sec.
W567J380
400 sec.
Duration
Note:
*: The duration time is based on 5-bit MDPCM at 6 KHz sampling rate. The firmware library and timber library have been
excluded from user’s ROM space for the duration estimation.
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W567JXXX
2. FEATURES
Wide range of operating voltage:
8 MHz @ 3.0 volt ~ 5.5 volt
6 MHz @ 2.4 volt ~ 5.5 volt
Power management:
4 ~ 8 MHz system clocks, with Ring type or crystal type.
Stop mode for stopping all IC operations
Provides up to 24 I/O pins
W567J070~J120: 16 I/O
W567J151~J380: 24 I/O
F/W speech synthesis:
Multiple format parser that supports
6-bit MDPCM, 5-bit MDPCM, 4-bit MDPCM ,4-bit ADPCM, 8-bit Log PCM
algorithm can be used
Pitch shippable ADPCM for voice changer application
Programmable sample rate
Melody synthesis:
6 melody channels that can emulate characteristics of musical instruments
More MIDI events are supported for colorful melody playback
Built-in TimerG0 for general purpose applications
Harmonized synchronization among MIDI, Speech, LED, and Motor
Build-in 3 LED outputs with 256-level control of brightness.
Built-in Watch-Dog Timer (WDT) and Low Voltage Reset (LVR)
Provide serial interface to access the external memory in W567J070~J380
W55Fxx, W551Cxx
SPI flash
Built-in IR carrier generation circuit for simplifying firmware IR application
Current type digital-to-analog converters (DAC) with 13-bit resolution to drive speaker output
Direct-drive 12-bit PWM output to save power consumption
Support PowerScriptTM for developing codes in easy way
Full-fledged development system
Source-level ICE debugger (Assembly & PowerScriptTM format)
Ultra I/OTM tool for event synchronization mechanism
ICE system with USB port
User-friendly GUI environment
Available package form:
COB is essential
- 3 -
W567JXXX
3. PIN DESCRIPTION
PIN NAME
/RESET
I/O
FUNCTION
I
I
IC reset input, low active.
OSCIN
Main-clock oscillation input. When Ring type is used, connects Rosc
between OSCIN and VSS to generate the system clock frequency.
Reserved one 100pF~200pF capacity to VDD from OSCin pin to make
Ring frequency stability
When use X’tal, it is X’tal IN.
OSCOUT
O
Main-clock oscillation output only for X’tal.
General input/output pins. When used as output pin, it can be open–drain
or CMOS type and it can sink 25mA for high-current applications. When
used as input pin, there may have a pull-high option and generate
interrupt request to release IC from STOP mode.
BP00~BP07
I/O
BP04~BP06 are used as 3 LED outputs with 256-level control.
General input/output pins. When used as output pin, it can be open–drain
or CMOS type. When used as input pin, there may have a pull-high option
and generate interrupt request to release IC from STOP mode.
BP10~BP17
BP20~BP271
I/O
I/O
General input/output pins. When used as output pin, it can be open–drain
or CMOS type. When used as input pin, there may have a pull-high option
and generate interrupt request to release IC from STOP mode.
PWM+/DAC
PWM-
O
O
I
PWM driver positive output or Current type DAC output
PWM driver negative output
TEST
Test input, internally pulled high. Do not connect during normal operation.
Positive power supply for uP and peripherals.
VDD
Power
Power
All VDD pins must be bonded out and connect to VDD
Only W567J151/171 for Positive power supply for uP and peripherals.
It needs be bonded out and connect to VDD.
VDD1
VSS
Power Negative power supply for oscillation, uP and peripherals.
Power Positive power supply for oscillation.
VDDOSC
VDDSPK
VSSSPK
CVDD
Power Positive power supply for speaker driver.
Power Negative power supply for speaker driver.
O
For 3 battery(3.3V~5.5V) application , the capacitor, 0.1uF, shunts
between CVDD and GND as power stability for regulator output.
For 2 battery(2.2V~3.6V) application, CVDD will connect to VDD directly.
Note: W567J151/171 without CVDD pin, the application circuit don’t need
consider 3/2battery application.
Positive power supply for BP1 including serial interface Management
(SIM).
VDD_BP1
Power
1
BP2 isn’t provided in W567J070 ~ W567J120.
- 4 -
W567JXXX
4. BLOCK DIAGRAM
OSCIN
OSCOUT
BP10~17 BP20~27 BP00~07
BP13~16
Timing
Generator
Timers
&
HQ generator
Interrupt
Controller
Serial
Interface
I/O
8 bits uP
RESETB
Address/Data Bus
DAC/PWM+
PWM-
Data RAM
Program ROM
DAC/
PWM
Mixer
WDT
Notes:
1. BP2 isn’t provided in W567J070 ~ W567J120.
- 5 -
W567JXXX
5. ITEM VS PIN TABLE
PIN name
J070/ 080/
100/ 120
J151/ 171
J210/
260/ 300/
340/ 380
Comment
BP00~BP07
BP10~BP17
BP20~BP27
/RESET
TEST
V
V
-
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
PWM+/DAC
PWM-
OSCIN
OSCOUT
VDD
Crystal mode
VSS
VDDSPK
VSSSPK
VDD_BP1
Support speaker power
Support BP10~BP17
including SIM interface
power
VDDOSC
VSSOSC
CVDD
V
V
V
V
V
-
V
V
V
Support OSCIN/OUT power
Regulator out
VDD1
V
Connect to VDD
- 6 -
W567JXXX
6. ELECTRICAL CHARACTERISTICS
6.1 Absolute Maximum Ratings
PARAMETER
Supply Voltage to Ground Potential
D.C. Voltage on Any Pin to Ground Potential
Operating Temperature
RATING
-0.3 to +7.0
-0.3 to VDD +0.3
0 to +70
UNIT
V
V
C
C
Storage Temperature
-55 to +150
Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability
of the device.
6.2 DC Characteristics
(VDDVSS = 4.5 V, FM = 8 MHz, Ta = 25C, No Load unless otherwise specified)
SPEC.
PARAMETER
SYM.
TEST CONDITIONS
UNIT
Min.
Typ.
Max.
FSYS = 6 MHz
FSYS = 8 MHz
2.4
-
5.5
V
V
Operating Voltage
VDD
3.0
-
-
6
1
-
5.5
10
Operating Current
Standby Current
Input Low Voltage
Input High Voltage
IOP1
ISB
No load, FSYS = 6 MHz
STOP mode
mA
A
V
-
2
VIL
All input pins
VSS
0.3 VDD
VIH
All input pins
0.7 VDD
-5
-
VDD
-14
V
Input Current
IIN1
VIN = 0V, pulled-high
resistor = 500k ohm
-9
A
(BP0, BP1, BP2)
Input Current
IIN2
VIN = 0V, pulled-high
resistor = 150k ohm
-15
-30
-45
A
(BP0, BP1, BP2)
IOL
IOH
IOL
VDD = 3V, VOUT = 0.4V
VDD = 3V, VOUT = 2.6V
VDD = 4.5V, VOUT = 1.0V
8
-4
-
12
-6
-
-
-
mA
mA
mA
Output Current (BP0)
25
IOH
IOL
IOH
IOL
IOH
VDD = 4.5V, VOUT = 3.5V
VDD = 3V, VOUT = 0.4V
VDD = 3V, VOUT = 2.6V
VDD = 4.5V, VOUT = 1.0V
VDD = 4.5V, VOUT = 3.5V
-
4
-4
-
-12
8
-
-
-
-
-
mA
mA
mA
mA
mA
-6
Output Current
(BP1, BP2)
12
-12
-
- 7 -
W567JXXX
SPEC.
Typ.
PARAMETER
SYM.
TEST CONDITIONS
UNIT
Max.
Min.
-2.4
-4.0
-3.0
-5.0
-3.6
mA
-6.0
DAC Full Scale Current
IDAC
IOL1
VDD
=
4.5V, RL = 100
+200
-200
75
-
-
-
-
mA
mA
K
Output Current
PWM+ / PWM-
RL= 8 Ohm,
[PWM+]----[RL]----[PWM-]
IOH1
Pull-high Resistor Test
RPL
150
225
6.3 AC Characteristics
(VDD-VSS = 4.5 V, FM = 8 MHz, Ta = 25C; No Load unless otherwise specified)
SPEC.
Typ.
PARAMETER
SYM.
FM
TEST CONDITIONS
UNIT
Min.
Max.
5.4
7.2
6
8
6.6
Ring type, *Rosc = TBD
Ring type, *Rosc = TBD
Main-Clock
MHz
8.8
5
Main-Clock Wake-up
Stable Time
TWSM
-
-
3
3
mS
%
Ring type, R = TBD K
F
F
FMAX - FMIN
FMIN
Main-Clock Frequency
Deviation, Ring type
7.5
Cycle Time
TCYC
TRES
CPU clock = 6 MHz
After FSYS stable
166
4
-
-
DC
-
nS
/RESET Active Width
TCYC
*: Typical ROSC value for each part number should refer to design guide.
- 8 -
W567JXXX
7. TYPICAL APPLICATION CIRCUIT
a. Rosc with 2 Battery
(3)
VDDSPK
BP00
|
BP07
4.7uF
VDD/ VDDOSC
VDD_BP1/ VDD1
10ohm
BP10
|
BP17
0 .1uF
(2)
BP20
|
BP27
VDDSPK
120pF
OSCIN
Speaker 0
(5)
(4)
ROSC
8050
OSCOUT
TEST
Rs
PWM+/DAC
PWM-
X32I
X32O
Speaker0
/RESET
Reset
0.1uF
Switch
VSS
VSSSPK
CVDD
(1)
Notes:
1. The block (1): If the project is two-battery application (Voltage 3.6V~2.2V), it is necessary to connect CVDD to VDD.
2. The block (2): The low-pass filter circuit is necessary for VDD stability, in order to avoid VDDSPK noise.
3. The block (3): The capacitor, 4.7uF, shunted between VDD and GND is necessary for power stability. However, the
value of capacitor depends on the power loading of the application.
4. The typical value of Rosc is 300 K for 8MHz and 390 K for 6MHz, and the Rosc should be connected to GND
(VSS). Please refer to design guide to get typical Rosc value for each part number.
5. The block (4):The capacitor, 120pF, shunted between OSCIN and VDD is optional for Fosc stability, which can
prevent noise from happening, because it can block the affection of larger current while playing. However, the value
of capacitor depends on the application (100pF~200pF is recommended)
6. The block (5): The Rs value is suggested of 270 ~ 1K to limit large DAC output current flowing into transistor.
7. The above application circuit is for reference only. No warranty for mass production.
- 9 -
W567JXXX
b. Rosc with 3 Battery
(3)
VDDSPK
BP00
|
BP07
4.7uF
VDD/ VDDOSC
VDD_BP1/
VDD1
10ohm
BP10
|
BP17
0 .1uF
(2)
BP20
|
BP27
VDDSPK
120pF
Speaker 0
OSCIN
(5)
(4)
ROSC
8050
OSCOUT
TEST
Rs
PWM+/DAC
PWM-
X32I
X32O
Speaker0
/
RESET
Reset
0.1uF
Switch
VSSSPK
VSS
CVDD
(1)
0.1uF
Notes:
1. The block (1): If the project is three-battery application (Voltage 5.5V~3.0V), it is necessary to connect a 0.1uF
between CVDD and GND (VSS).
2. The block (2): The low-pass filter circuit is necessary for VDD stability, in order to avoid VDDSPK noise
3. The block (3): The capacitor, 4.7uF, shunted between VDD and GND is necessary for power stability. However,
the value of capacitor depends on the power loading of the application.
4. The typical value of Rosc is 300 K for 8MHz and 390 K for 6MHz, and the Rosc should be connected to
GND (VSS). Please refer to design guide to get typical Rosc value for each part number.
5. The block (4)The capacitor, 120pF, shunted between OSCIN and VDD is optional for Fosc, which can prevent
noise from happening, because it can block the affection of larger current while playing. However, the value of
capacitor depends on the application (100pF~200pF is recommended)
6. The block (5): The Rs value is suggested of 270 ~ 1K to limit large DAC output current flowing into
transistor.
7. The above application circuit is for reference only. No warranty for mass production.
- 10 -
W567JXXX
c. Crystal
(3)
VDDSPK
BP00
|
BP07
4.7uF
VDD/ VDDOSC
VDD_BP1/ VDD1
10ohm
BP10
|
0 .1uF
(2)
BP17
VDDSPK
BP20
|
BP27
Speaker 0
(5)
OSCIN
Cp1
Cp2
(4)
(4)
8050
Rs
OSCOUT
PWM+/DAC
PWM-
X32I
Cp3
Cp4
X32O
Speaker0
/
RESET
Reset
0.1uF
Switch
VSS
VSSSPK
CVDD
(1)
Notes:
1. The block (1): Please refer to (a) and (b) circuits for two-battery or three-battery application.
2. The block (2): The low-pass filter circuit is necessary for VDD stability, in order to avoid VDDSPK noise.
3. The block (3): The capacitor, 4.7uF, shunted between VDD and GND is necessary for power stability. However the
value of capacitor depends on the power loading of the application
4. The block (4): Cp1 and Cp2 (15~30pF) are optional for main Crystal, which can be skipped normally.
5. The block (5): The Rs value is suggested of 270 ~ 1K to limit large DAC output current flowing into transistor.
6. Cp3 and Cp4 (15~30pF) are optional for 32KHz Crystal, which can be skipped normally.
7. Please connect all VDD pins include VDDOSC/VDD_BP1 to VDD. If with SIM application, the VDD_BP1 pin can
connect to different voltage for SPI flash or W551Cxx and the BP10~BP17 also use the same power VDD_BP1.
8. The above application circuit is for reference only. No warranty for mass production.
9. Other application circuits please refer to Design Guide.
- 11 -
W567JXXX
d. PCB layout guide
1.
2.
The IC substrate should be connected to VSS in PCB layout, but VSSSPK can’t connect with IC
substrate directly. Both VSS and VSSSPK tie together in battery negative power.
Each VDD, VDDOSC, VDD_BP1, VDD1 and VDDSPK pad must connect to positive power to
support stable voltage for individual function work successfully. (Don’t let them be floating.)
8. REVISION HISTORY
VERSION
DATE
REASONS FOR CHANGE
PAGE
A0.0
Jan 2007
Preliminary release.
Add SIM function
A1.0
A2.0
May 2007
Nov 2007
Remove 32K Crystal current on DC characteristics
Modify application circuit
Remove multi-midi function
Modify application circuit and naming
Modify Logo
A3.0
A4.0
A5.0
Sep. 2008
Jun. 2009
May. 2010
Change logo
Modify application circuit
Add 2 battery application circuit
6
Update output current for BP1/2 @4.5V/3.0V and update BP0 @4.5V
Add application circuit for Ring OSCin pin to add 120pF to VDD
Modify the description for application circuit
8~15
A6.0
Dec, 2010
Support MD4 format for F/W library
8~15
3
A7.0
A8.0
July. 2011
Aug. 2011
Add new chip W567J151/171
Remove W567J160/170.
2,
Add new chip W567J151/171 pad description
Add new chip W567J151/171 application circuit
Add SIM application circuit
5
9~18
18
2
Add W567CP80 OTP chip
7
A9.0
Feb. 2012
Mar. 2012
Add items vs pad table
Modify application circuits
4
4
9
BP00~BP03 share pins as OTP writer in W567CP80.
Correct TEST pin as internal pull high
Update operating current DC spec.
A10.0
- 12 -
W567JXXX
Important Notice
Nuvoton Products are neither intended nor warranted for usage in systems or equipment, any
malfunction or failure of which may cause loss of human life, bodily injury or severe property
damage. Such applications are deemed, “Insecure Usage”.
Insecure usage includes, but is not limited to: equipment for surgical implementation, atomic
energy control instruments, airplane or spaceship instruments, the control or operation of
dynamic, brake or safety systems designed for vehicular use, traffic signal instruments, all
types of safety devices, and other applications intended to support or sustain life.
All Insecure Usage shall be made at customer’s risk, and in the event that third parties lay
claims to Nuvoton as a result of customer’s Insecure Usage, customer shall indemnify the
damages and liabilities thus incurred by Nuvoton.
- 13 -
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