NEC UPD16835AGS-BGG

DATA SHEET
MOS INTEGRATED CIRCUIT
µPD16835A
MONOLITHIC QUAD H BRIDGE DRIVER CIRCUIT
DESCRIPTION
The µPD16835A is a monolithic quad H bridge driver IC that employs a CMOS control circuit and a MOS FET
output circuit. Because it uses MOS FETs in its output stage, this driver IC consumes less power than conventional
driver ICs that use bipolar transistors.
Because the µPD16835A controls a motor by inputting serial data, its package has been shrunk and the number
of pins reduced. As a result, the performance of the application set can be improved and the size of the set has been
reduced.
The µPD16835A employs a current-controlled 64-step micro step driving method that drives stepper motor with
low vibration.
The µPD16835A is housed in a 38-pin plastic shrink SOP to contribute to the miniaturization of the application set.
The µPD16835A can simultaneously drive two stepper motors and is ideal for the mechanisms of camcorders.
FEATURES
• Four H bridge circuits employing power MOS FETs
• Current-controlled 64-step micro step driving
• Motor control by serial data (8 bytes x 8 bits) (original oscillation: 4-MHz input)
Data is input with the LSB first.
EVR reference setting voltage: 100 to 250 mV (@VREF = 250 mV) ... 4-bit data input (10-mV step)
Chopping frequency: 32 to 124 kHz ... 5-bit data input (4-kHz step)
Original oscillation division or internal oscillation selectable
Number of pulses in 1 VD: 0 to 252 pulses ... 6 bits + 2-bit data input (4 pulses/step)
Step cycle: 0.25 to 8191.75 µs ... 15-bit data input (0.25- µs step)
• 3-V power supply. Minimum operating voltage: 2.7 V (MIN.)
• Low current consumption IDD: 3.0 mA (MAX.), IDD (RESET): 100 µA (MAX.), IMO(RESET): 1.0 µA (MAX.)
• 38-pin plastic shrink SOP (7.62 mm (300))
ORDERING INFORMATION
Part number
Package
µPD16835AGS-BGG
38-pin plastic shrink SOP (7.62 mm (300))
The information in this document is subject to change without notice. Before using this document, please
confirm that this is the latest version.
Not all devices/types available in every country. Please check with local NEC representative for
availability and additional information.
Document No.
S15973EJ1V0DS00 (1st edition)
Date Published February 2002 N CP(K)
Printed in Japan
©
2002
37
RESET
VD
36
VREF
32
SCLK
7
SDATA
35
LATCH
34
BLOCK DIAGRAM
2
OSCOUT
OSCIN
EXP0 EXP1 EXP2 EXP3
33
17
18
19
21
38
VDD
8
VM1
23
VM2
27
VM3
9
x2
SERIAL-PARARELLE DECODER
PULSE GENERATER
EXTOUT SELECTOR
1/N
Data Sheet S15973EJ1V0DS
VM4
13
EVR1
COSC
2
SELECTOR
EVR2
CURRENT SET α
OSC
EVR1
EVR2
22
CURRENT SET β
31
+
+
–
FILTER
VM
LGND
1
PGND
20
H BRIDGE
α 1ch
+
–
FILTER
A1
A2
3
FILA
28
29
FBB
–
FILTER
VM
H BRIDGE
α 2ch
26
24
+
B1
B2
4
FILB
16
15
FBC
FILTER
VM
H BRIDGE
β 1ch
30
+
C1
H BRIDGE
β 2ch
14
C2
5
FILC
12
11
FBD
D1
10
D2
6
FILD
µPD16835A
FBA
+
VM
25
EXTβ
+
+
–
EXTα
µPD16835A
PIN CONFIGURATION
38-pin plastic shrink SOP (7.62 mm (300))
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
LGND
COSC
FILA
FILB
FILC
FILD
VREF
VDD
VM3
D2
FBD
D1
VM4
C2
FBC
C1
EXP0
EXP1
EXP2
RESET
OSCOUT
OSCIN
SCLK
SDATA
LATCH
VD
EXTβ
B2
FBB
B1
VM2
A2
FBA
A1
VM1
EXTα
EXP3
PGND
Data Sheet S15973EJ1V0DS
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
3
µPD16835A
1. PIN FUNCTIONS
Pin No.
4
Symbol
Function
1
LGND
Control circuit GND pin
2
COSC
Chopping capacitor connection pin
3
FILA
α 1-ch filter capacitor connection pin (1000 pF TYP.)
4
FILB
α 2-ch filter capacitor connection pin (1000 pF TYP.)
5
FILC
β 1-ch filter capacitor connection pin (1000 pF TYP.)
6
FILD
β 2-ch filter capacitor connection pin (1000 pF TYP.)
7
VREF
Reference voltage input pin (250 mV TYP.)
8
VDD
Control circuit supply voltage input pin
9
VM3
Output circuit supply voltage input pin
10
D2
β 2-ch output pin
11
FBD
β 2-ch sense resistor connection pin
12
D1
β 2-ch output pin
13
VM4
Output circuit supply voltage connection pin
14
C2
β 1-ch output pin
15
FBC
β 1-ch sense resistor connection pin
16
C1
β 1-ch output pin
17
EXP0
Output monitor pin (open drain)
18
EXP1
Output monitor pin (open drain)
19
EXP2
Output monitor pin (open drain)
20
PGND
Power circuit GND pin
21
EXP3
Output monitor pin (open drain)
22
EXTα
Logic circuit monitor pin
23
VM1
Output circuit supply voltage input pin
24
A1
α 1-ch output pin
25
FBA
α 1-ch sense resistor connection pin
26
A2
α 1-ch output pin
27
VM2
Output circuit supply voltage input pin
28
B1
α 2-ch output pin
29
FBB
α 2-ch sense resistor connection pin
30
B2
α 2-ch output pin
31
EXTβ
Logic circuit monitor pin
32
VD
Video sync signal input pin
33
LATCH
Latch signal input pin
34
SDATA
Serial data input pin
35
SCLK
Serial clock input pin
36
OSCIN
Original oscillation input pin (4 MHz TYP.)
37
OSCOUT
Original oscillation output pin
38
RESET
Reset signal output pin
Data Sheet S15973EJ1V0DS
µPD16835A
2. I/O PIN EQUIVALENT CIRCUIT
Pin Name
Equivalent Circuit
Pin Name
Equivalent Circuit
VDD
VDD
LATCH
SDATA
SCLK
VDD
Pad
OSCIN
RESET
Pad
Pull-down
resistor (125 Ω)
VDD
OSCOUT
EXTα
EXTβ
VDD
EXP0
EXP1
EXP2
EXP3
Pad
Pad
VDD
VREF
Pad
VDD
FILA
FILB
FILC
FILD
Pad
Buffer
VM
A1, A2
B1, B2
C1, C2
D1, D2
Parasitic diodes
Pad
FB
Data Sheet S15973EJ1V0DS
5
4 MHz
OSCIN
100 kΩ x 4
OSCOUT
VD
VREF
EXP0 EXP1 EXP2 EXP3
SCLK SDATA LATCH
RESET
REGULATOR
3.3 V
x2
VDD
VM1
SERIAL-PARARELLE DECODER
VM2
VM3
EXTOUT SELECTOR
PULSE GENERATER
1/N
Data Sheet S15973EJ1V0DS
VM4
COSC
BATTERY
4.8 to 11 V
SELECTOR
OSC
EVR1 EVR2
EVR1 EVR2
CURRENT SET α
CURRENT SET β
EXTα
EXTβ
3. EXAMPLE OF STANDARD CONNECTION
6
250 mV
EVR : 1010
fOSC : 64 kHz
CPU
33 pF
+
+
+
+
–
+
–
FILTER
VM
+
–
FILTER
VM
+
–
FILTER
VM
+
FILTER
VM
LGND
PGND
H BRIDGE
α 1ch
FBA
A1
H BRIDGE
α 2ch
A2 FILA FBB
B1
B2 FILB
H BRIDGE
β 1ch
FBC
C1
H BRIDGE
β 2ch
C2 FILC FBD
D1
D2 FILD
6.8 Ω x 2
6.8 Ω
1000 pF
6.8 Ω
1000 pF
1000 pF x 2
MOTOR 2
µPD16835A
MOTOR 1
µPD16835A
4. STANDARD CHARACTERISTICS CURVES
PT vs. TA Characteristics
I MO (RESET) vs. VM Characteristics
1.4
1
OFF VM pin Current I MO (RESET) (µ A)
Total Power Dissipation P T (W)
1.2
1.0
125°C/W
0.8
0.6
0.4
0.2
0
–10
0
80
100
20
40
60
Ambient Temperature TA (°C)
0.8
0.6
0.4
0.2
0
120
TA = 25°C,
no load,
after reset
4
IDD vs. VDD Characteristics
200
output open
4
VDD pin Current IDD (mA)
VDD pin Current at Reset State I DD (RESET) (µA)
TA = 25°C,
operating,
3
2
1
2
3
4
5
Control Circuit Supply Volage VDD (V)
TA = 25°C,
after reset
150
100
50
0
6
2
VIH/VDD, VIL/VDD vs. VDD Characteristics
6
High-level/Low-level Input Current IIH/IIL (µ A)
60
TA = 25°C
Input Voltage VIH/VDD, VIL/VDD (V)
3
4
5
Control Circuit Supply Volage VDD (V)
IIH/IIL vs. VIN Characteristics
1
0.8
0.6
VIH
VIL
0.4
0.2
0
12
IDD (RESET) vs. VDD Characteristics
5
0
6
8
10
Output Circuit Supply Voltage VM (V)
2
3
4
5
Control Circuit Supply Volage VDD (V)
6
TA = 25°C,
IIH: VIN = VDD,
IIL: VIN = 0 V
40
IIH
20
IIL
0
2
Data Sheet S15973EJ1V0DS
3
5
4
Input Voltage VIN (V)
6
7
µPD16835A
fOSC vs. VDD Characteristics
fSTEP vs. VDD Characteristics
6
TA = 25°C,
COSC = 100 pF,
DATA: all high
140
TA = 25°C,
COSC = 100 pF
Step Frequency fSTEP (kHz)
Chopping Frequency fOSC (kHz)
150
130
120
110
5
4
3
100
90
2
3
4
5
Control Circuit Supply Voltage VDD (V)
2
6
2
VREFVER vs. VDD Characteristics
IM (MAX) vs. EVR Characteristics
Sine Wave Peak Output Current IM (MAX) (mA)
EVR Variable Voltage V REFVER (mV)
TA = 25°C,
VREF = 250 mV
30
20
10
2
5
3
4
Control Circuit Supply Voltage VDD (V)
6
70
50
40
30
20
50
tON, tOFF vs. VM Characteristics
Turn-on Time, Turn-off Time tON/tOFF (ns)
8
TA = 25°C,
IM = 100 mA,
CFIL : none
400
300
tON
tOFF
200
100
4
10
6
8
Output Circuit Supply Voltage VM (V)
TA = 25°C, VM = 6 V
Rs = 6.8 Ω, fOSC = 64 kHz,
L = 25 mH/R = 100 Ω at 1 kHz
60
500
0
6
80
40
0
3
4
5
Control Circuit Supply Voltage VDD (V)
12
Data Sheet S15973EJ1V0DS
100
150
200
250
Reference Setting Voltage EVR (mV)
300
µPD16835A
5. INTERFACE (I/F) CIRCUIT DATA CONFIGURATION (fCLK = 4-MHz EXTERNAL CLOCK INPUT)
Input data consists of serial data (8 bytes x 8 bits).
Input serial data with the LSB first, from the 1st byte to 8th byte.
(1) Initial data
(2) Standard data
<1st byte>
Bit
<1st byte>
Data
Function
Setting
Bit
DATA selection
D7
Data
Function
Setting
0
HEADER DATA2
DATA selection
D7
1
HEADER DATA2
D6
1
HEADER DATA1
D6
0
HEADER DATA1
D5
1
HEADER DATA0
D5
0
HEADER DATA0
D4
0
−
−
D4
0
−
D3
1 or 0
EXP3
Hi-Z or L
D3
1 or 0
EXP3
Hi-Z or L
D2
1 or 0
EXP2
Hi-Z or L
D2
1 or 0
EXP2
Hi-Z or L
D1
1 or 0
EXP1
Hi-Z or L
D1
1 or 0
EXP1
Hi-Z or L
D0
1 or 0
EXP0
Hi-Z or L
D0
1 or 0
EXP0
Hi-Z or L
Remark Hi-Z : High impedance,
Remark Hi-Z : High impedance,
L : Low level (current sink)
L : Low level (current sink)
<2nd byte>
Bit
−
<2nd byte>
Data
Function
Setting
Bit
Data
Function
Setting
D7
D7
1 or 0
α ROTATION
α ch CCW/CW
D6
D6
1 or 0
α ENABLE
α ch ON/OFF
Start point wait
D5
D4
8-bit data
D3
input Note
256 µs to 65.28 ms
First Point Wait
Setting
(1 to 255)
D2
∆t = 256 µs
D5
D3
6-bit data
D2
input
D1
D1
D0
D0
Note Input other than “0”.
α ch
D4
Number of
α Pulse Number
pulses in 1 VD
Setting (0 to 63)
∆n = 4 pulses Note
Note The number of pulses can be varied in 4-pulse
steps.
<3rd byte>
Bit
<3rd byte>
Data
Function
Setting
Bit
Data
Function
Setting
D7
D7
15-bit data
D6
Start point drive
D6
α ch pulse
D5
wait
D5
cycle
0.25 to 8191.75 µs
D4
8-bit data
First Point
256 µs to 65.28 ms
D4
D3
input Note
Magnetize Wait
Setting
D3
Low-order
D2
8-bit data
(1 to 32767)
input
∆t = 0.25 µs
D2
(1 to 255)
D1
∆t = 256 µs
D0
D1
α Pulse Width
Setting
D0
Note Input other than “0”.
Data Sheet S15973EJ1V0DS
9
µPD16835A
<4th byte>
Bit
<4th byte>
Data
Function
OSCSEL
Setting
Bit
Data
Internal/external
D7
1 or 0
15-bit data
Function
Current Set α
Setting
D7
1 or 0
D6
0
-
-
D6
D5
0
-
-
D5
α ch
pulse cycle :
D4
Chopping
D4
D3
frequency :
D3
D2
D1
5-bit data
input
Chopping
32 to 124 kHz
Frequency
Setting
Note
High-order
D2
D1
(8 to 31)
D0
α Pulse Width
set2/set1
0.25 to 8191.75 µs
Setting
8-bit data
(1 to 32767)
input
∆t = 0.25 µs
D0
∆f = 4 kHz
Note The frequency is 0 kHz if 0 to 7 is input.
<5th byte>
Bit
D7
<5th byte>
Data
EXTα
EXTβ
Bit
-
-
D7
1 or 0
β ROTATION
β ch CCW/CW
D6
1 or 0
β ENABLE
β ch ON/OFF
0
Note 5
ENABLE α
D5
Note 5
ROTATION α
D4
Note 5
Pulse Out α
Pulse Out β
D4
D6
Note1
Note2
ENABLE β
Note1
ROTATION β
Note2
Data
D5
Setting
β ch
D3
Note 5
FF7 α
FF7 β
D3
6-bit data
D2
Note 5
FF3 α
FF3 β
D2
input
D1
Note 5
Checksum Note3
FF2 β
D1
D0
Note 5
Chopping Note4
FF1 β
D0
Notes 1. H level : Conducts, L level : Stops
Function
Number of
β Pulse Number
pulses in 1 VD
Setting (1 to 63)
∆n = 4 pulses Note
Note The number of pulses can be varied in 4-pulse
2. H level : Reverse (CCW),
steps.
L level : Forward (CW)
3. H level : Normal data input,
L level : Abnormal data input
4. Not output in internal oscillation mode.
5. Select one of D0 to D6 and input “1”.
If two or more of D0 to D6 are selected,
they are positively ORed for output.
<6th byte>
Bit
<6th byte>
Data
Function
D7
Setting
Bit
Data
α ch Output current
D7
15-bit data
Setting
D6
4-bit data
α ch
setting 2 EVR : 100
D6
β ch pulse
D5
input
Current Set2
to 250 mV
D5
cycle:
Setting (0 to 15) Note
D4
D4
D3
D2
D1
4-bit data
input
D0
α ch
Current Set1
β Pulse Width
0.25 to 8191.75 µs
α ch Output current
D3
Low-order
setting 1 EVR : 100
D2
8-bit data
(1 to 32767)
input
∆t = 0.25 µs
to 250 mV
D1
Setting (0 to 15) Note
D0
Note A voltage of about double EVR is output to
the FIL pin.
10
Function
Data Sheet S15973EJ1V0DS
Setting
µPD16835A
<7th byte>
Bit
<7th byte>
Data
Function
D7
Setting
Bit
β ch Output
D6
4-bit data
β ch
current setting 2
D5
input
Current Set2
EVR: 100 to 250 mV
Setting (0 to 15)
D4
D3
D7
1 or 0
D6
15-bit data
Function
Current Set β
7-bit data
β ch
current setting 1
D2
D1
input
Current Set1
EVR: 100 to 250 mV
D1
Setting (0 to 15)Note
High-order
D3
4-bit data
set2/set1
cycle:
D4
D2
Setting
β ch pulse
D5
Note
β ch Output
D0
Data
β Pulse Width
0.25 to 8191.75 µs
Setting
(1 to 32767)
input
∆t = 0.25 µs
D0
Note A voltage of about double EVR is output to
the FIL pin.
<8th byte>
Bit
<8th byte>
Data
Function
Setting
Bit
Data
D7
1 or 0
D7
1 or 0
D6
1 or 0
D6
1 or 0
D5
1 or 0
D5
1 or 0
D4
1 or 0
D4
1 or 0
D3
1 or 0
D3
1 or 0
D2
1 or 0
D2
1 or 0
D1
1 or 0
D1
1 or 0
D0
1 or 0
D0
1 or 0
Checksum
Checksum Note
Note Data is input so that the sum of the 1st
through the 8th bytes is 00H.
Function
Checksum
Setting
Checksum Note
Note Data is input so that the sum of the 1st
through the 8th bytes is 00H.
Data Sheet S15973EJ1V0DS
11
µPD16835A
Data Configuration
Data can be input in either of two ways. Initial data can be input when the power is first applied, or standard data
can be input during normal operation. Input serial data with the LSB first, i.e., starting from the D0 bit (LSB) of the 1st
byte. Therefore, the D7 bit of the 8th byte is the most significant bit (MSB).
When inputting initial data, set a start point wait time that specifies the delay from power application to pulse
output, and the start point drive wait time. At the same time, also set a chopping frequency and a reference voltage
(EVR) that determines the output current of each channel. Because the µPD16835A has an EXT pin for monitoring
the internal operations, the parameter to be monitored can be selected by initial data.
When inputting standard data, input the rotation direction of each channel, the number of pulses, and the data for
the pulse cycle.
Initial data or standard data is selected by using bits D5 to D7 of the 1st byte (see Table 5-1).
Table 5-1. Data Selection Mode (1st byte)
D7
D6
D5
1
1
1
Initial data
Data type
0
0
0
Standard data
Remark If the high-order three bits are high, the initial data is selected;
if they are low, the standard data is selected.
Data other than (0, 0, 0) and (1, 1, 1) must not be input.
Input the serial data during start point wait time.
Details of Data Configuration
How to input initial data and standard data is described below.
(1) Initial data input
<1st byte>
The 1st byte specifies the type of data (initial data or standard data) and determines the presence or absence of
the EXP pin output. Bits D5 to D7 of this byte specify the type of data as shown in Table 5-1, while bits D0 to D3
select the EXP output (open drain).
Table 5-2. 1st Byte Data Configuration
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
1
1
1
0
0 or 1
0 or 1
0 or 1
0 or 1
The EXP pin goes low (current sink) when the input data is “0”, and high (high impedance state) when the input
data is “1”. Pull this pin up to VDD for use. Input “0” to bit D4.
12
Data Sheet S15973EJ1V0DS
µPD16835A
<2nd byte>
The 2nd byte specifies the delay between data being read and data being output. This delay is called the start up
wait time, and the motor can be driven from that point at which the start up wait time is “0”. This time is counted at the
rising edge of VD. The start up wait time can be set to 65.28 ms (when a 4-MHz clock is input), and can be fine-tuned
by means of 8-bit division (256-µs step: with 4-MHz clock). The start up wait time is set to 65.28 ms when all the bits
of the 2nd byte are set to “1”.
Caution Always input data other than “0” to this byte because the start up wait time is necessary for
latching data. If “0” is input to this byte, data cannot be updated. Transfer standard data during the
start up wait time.
<3rd byte>
The 3rd byte specifies the delay between the start point wait time being cleared and the output pulse being
generated. This time is called the start up drive wait time, and the output pulse is generated from the point at which
the start up drive wait time reaches “0”. The start up drive wait time is counted at the falling edge of the start up wait
time. The start up drive wait time can be set to 65.28 ms (with 4-MHz clock) and can be fine-tuned by means of 8-bit
division (256-µs step: with 4-MHz clock). The start up drive wait time is set to 65.28 ms when all the bits of the 3rd
byte are “1”.
Caution Always input data other than “0” to this byte because the start up drive wait time is necessary for
latching data. If “0” is input to this byte, data cannot be updated.
<4th byte>
The 4th byte selects a chopping frequency by using 5-bit data. It also selects whether the chopping frequency is
created by dividing the original oscillation (external clock) or whether the internal oscillator is used. The chopping
frequency is selected by bits D0 to D4. Bit D7 specifies the method used to create the chopping frequency. When this
bit is “0”, the original oscillation (external clock input to OSCIN) is used; when it is “1”, the internal oscillator is used.
Bits D5 and D6 are fixed to “0”.
The chopping signal is output after the initial data has been input and the first standard data has been latched
(see Timing Chart).
Table 5-3. 4th Byte Data Configuration (Initial data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0
0
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
The chopping frequency is set to 0 kHz and to a value in the range of 32 to 124 kHz (in 4-kHz steps), as follows.
Although the chopping frequency is set by 5 bits of data, it is internally configured using 7-bit data (with the loworder 2 bits fixed to 0).
Data Sheet S15973EJ1V0DS
13
µPD16835A
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0
0
0
0
0
0
0
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0
0
0
0
1
1
1
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0
0
0
1
0
0
0
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0
0
0
1
0
0
1
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0
0
1
1
1
1
1
fOSC = 0 kHz
fOSC = 0 kHz
fOSC = 32 kHz
fOSC = 36 kHz
fOSC = 124 kHz
<5th byte>
The 5th byte selects a parameter to be output to the EXT pin (logic operation monitor pin). Input data to bits D0 to
D6 of this byte. Bit D7 is fixed to “0”.
There are two EXT pins. EXTα indicates the operating status of α ch, and EXTβ indicates that of β ch. The
relationship between each bit and each EXT pin is as shown in Table 5-4.
Table 5-4. 5th Byte Data Configuration (Initial data)
Bit
Data
D7
0
D6
0 or 1
EXTα
EXTβ
Not used
Not used
ENABLE α
ENABLE β
D5
0 or 1
ROTATION α
ROTATION β
D4
0 or 1
PULSEOUT α
PULSEOUT β
D3
0 or 1
FF7 α
FF7 β
D2
0 or 1
FF3 α
FF3 β
D1
0 or 1
CHECKSUM
FF2 β
D0
0 or 1
CHOPPING
FF1 β
The checksum bit is cleared to “0” in the event of an error. Normally, it is “1”.
If two or more signals that output signals to EXTα and EXTβ are selected, they are positively ORed for output.
Caution The CHOPPING signal is not output in internal oscillation mode.
14
Data Sheet S15973EJ1V0DS
µPD16835A
Remark
The meanings of the symbols listed in Table 5-4 are as follows:
ENABLE : Output setting (H : Conducts, L : Stops)
ROTATION : Rotation direction (H : Reverse (CCW), L : Forward (CW))
PULSEOUT : Output pulse signal
FF7 : Presence/absence of pulse in LATCH cycle (Outputs H level if output pulse information exists in
standard data.)
FF3 : Pulse gate (output while pulse exists)
FF2 : Outputs H level during start up wait time + start up drive wait time
FF1 : Outputs H level during start up wait time
CHECKSUM : Checksum output (H : when normal data is transmitted,
L : when abnormal data is transmitted)
CHOPPING : Chopping wave output (in original oscillation mode only)
<6th byte>
The 6th byte sets the peak output current value of α ch. The output current is determined by the EVR reference
voltage.
The 250-mV (TYP.) voltage input from an external source to the VREF pin is internally doubled and input to a 4-bit
D/A converter. By dividing this voltage by 4-bit data, an EVR reference voltage can be set inside the IC within the
range of 200 to 500 mV, in units of 20 mV.
The µPD16835A can set two values of the EVR reference voltage in advance. This is done by using bits D0 to D3
or D4 to D7. Which of the two EVR reference voltage values is to be used is specified by the CURRENT SET bit in
the standard data.
If all the bits of the 6th byte are “0”, the EVR reference voltage of 200 mV is selected; if they are “1”, the EVR
reference voltage of 500 mV is selected.
Table 5-5. 6th Byte Data Configuration (Initial data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
Remark Bits D4 to D7 : Reference voltage 2 (EVR α2)
Bits D0 to D3 : Reference voltage 1 (EVR α1)
<7th byte>
The 7th byte specifies the peak output current value of β ch. The output current is determined by the EVR
reference voltage.
The 250-mV (TYP.) voltage input from an external source to the VREF pin is internally doubled and input to a 4-bit
D/A converter. By dividing this voltage by 4-bit data, an EVR reference voltage can be set inside the IC within a range
of 200 to 500 mV, in units of 20 mV.
The µPD16835A can set two values of the EVR reference voltage in advance. This is done using bits D0 to D3 or
D4 to D7. Which of the two EVR reference voltage values is to be used is specified by the CURRENT SET bit in the
standard data.
If all the bits of the 7th byte are “0”, the EVR reference voltage of 200 mV is selected; if they are “1”, the EVR
reference voltage of 500 mV is selected.
Data Sheet S15973EJ1V0DS
15
µPD16835A
Table 5-6. 7th Byte Data Configuration (Initial data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
Remark Bits D4 to D7 : Reference voltage 2 (EVR β2)
Bits D0 to D3 : Reference voltage 1 (EVR β1)
<8th byte>
The 8th byte is checksum data. Normally, the sum of the 8-byte data is 00H.
If the sum is not 00H because data transmission is abnormal, the stepping operation is inhibited and the
checksum output pin (EXT pin) is kept “L”.
(2) Standard data input
<1st byte>
The 1st byte specifies the type of data and whether the EXP pin output is used, such as when the initial data is
input.
Table 5-7. 1st Byte Data Configuration
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
1
1
1
0
0 or 1
0 or 1
0 or 1
0 or 1
The EXP pin goes low (current sink) when the input data is “0”, and high (high impedance state) when the input
data is “1”. Input “0” to bit D4.
<2nd byte>
The 2nd byte specifies the rotation direction of the α channel, enables output of the α channel, and the number of
pulses (252 pulses MAX.) during the 1VD period (in 1 cycle of FF2) of the α channel.
Bit D7 is used to specify the rotation direction. The rotation is in the forward direction (CW mode) when this bit is
“0”; it is in the reverse direction (CCW mode) when the bit is “1”.
Bit D6 is used to enable the output of the α channel. The α channel enters the high impedance state when this bit
is “0”; it is in conduction mode when the bit is “1”.
The number of pulses is set by bits D0 to D5. It is set by 6 bits in terms of software. However, the actual circuit
uses an 8-bit counter with the low-order two bits fixed to “0”. Therefore, the number of pulses that is actually
generated during start up wait time + start up drive wait (FF2) cycle is the number of pulses input x 4. The number of
pulses can be set to a value in the range of 0 to 252, in units of 4 pulses.
16
Data Sheet S15973EJ1V0DS
µPD16835A
Table 5-8. 2nd Byte Data Configuration (Standard data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
Rotation direction
ENABLE
Number of pulses
<3rd and 4th bytes>
The 3rd and 4th bytes select the pulse cycle of the α channel and which of the two reference voltages, created in
the initial mode, is to be used (CURRENT SETα).
The pulse cycle is specified using 15 bits : bits D0 (least significant bit) to D7 of the 3rd byte, and bits D0 to D6
(most significant bit) of the 4th byte. The pulse cycle can be set to a value in the range of 0.25 to 8191.75 µs in units
of 0.25 µs (with a 4-MHz clock).
CURRENT SETα is specified by bit D7 of the 4th byte. When this bit is “0”, reference voltage 1 (EVRα1) is
selected; when it is “1”, reference voltage 2 (EVRα2) is selected. For further information, refer to the description of the
6th byte of the initial data.
Table 5-9. 4th Byte Data Configuration (Standard data)
Table 5-10. 3rd Byte Data Configuration (Standard data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
CURRENT SETα
Most significant
Least significant bit
bit
(Reference) 6th Byte Data Configuration for Initial Data
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
Remark Bits D4 to D7 : Reference voltage 2 (EVR α2)
Bits D0 to D3 : Reference voltage 1 (EVR α1)
<5th byte>
The 5th byte specifies the rotation direction of the β channel, enables output of the β channel, and the number of
pulses (252 pulses MAX.) during the 1VD period (in one cycle of FF2) of the β channel.
Bit D7 is used to specify the rotation direction. The rotation is in the forward direction (CW mode) when this bit is
“0”; it is in the reverse direction (CCW mode) when the bit is “1”.
Bit D6 is used to enable the output of the β channel. The β channel goes into a high impedance state when this bit
is “0”; it is in the conduction mode when the bit is “1”.
The number of pulses is set by bits D0 to D5. It is set by six bits in terms of software. However, the actual circuit
uses an 8-bit decoder with the low-order two bits fixed to “0”. Therefore, the number of pulses that is actually
generated during start up wait time + start up drive wait (FF2) cycle is the number of pulses input x 4. The number of
pulses can be set in a range of 0 to 252 and in units of 4 pulses.
Data Sheet S15973EJ1V0DS
17
µPD16835A
Table 5-11. 5th Byte Data Configuration (Standard data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
Rotation direction
ENABLE
Number of pulses
<6th and 7th bytes>
The 6th and 7th bytes select the pulse cycle of the β channel and which of the two reference voltages, created in
the initial mode, is to be used (CURRENT SETβ).
The pulse cycle is specified using 15 bits : bits D0 (least significant bit) to D7 of the 6th byte, and bits D0 to D6
(most significant bit) of the 7th byte. The pulse cycle can be set to a value in the range of 0.25 to 8191.75 µs in units
of 0.25 µs (with a 4-MHz clock).
CURRENT SETβ is specified by bit D7 of the 7th byte. When this bit is “0”, reference voltage 1 (EVRβ1) is
selected; when it is “1”, reference voltage 2 (EVRβ2) is selected. For further information, refer to the description of the
7th byte of the initial data.
Table 5-12. 7th Byte Data Configuration (Standard data)
Table 5-13. 6th Byte Data Configuration (Standard data)
Bit
D7
D6
D5
D4
D3
D2
D1
D0
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
CURRENT SETβ
Most significant bit
Least significant bit
(Reference) 7th Byte Data Configuration for Initial Data
Bit
D7
D6
D5
D4
D3
D2
D1
D0
Data
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
0 or 1
Remark Bits D4 to D7 : Reference voltage 2 (EVR β2)
Bits D0 to D3 : Reference voltage 1 (EVR β1)
<8th byte>
The 8th byte is checksum data. Normally, the sum of the 8-byte data is 00H.
If the sum is not 00H because data transmission is abnormal, the stepping operation is inhibited and the
checksum output pin (EXT pin) is held at “L”.
18
Data Sheet S15973EJ1V0DS
µPD16835A
(Data Update Timing)
The standard data (pulse width, number of pulses, rotation direction, current setting, and ENABLE) of this product
are set and updated at the following latch timing.
Table 5-14. Data Update Timing
ENABLE change
1→1
0→1
1→0
0→0
Pulse width
FF2↓
FF2↓
FF2↓
−
Number of pulses
FF2↓
FF2↓
FF2↓
−
Rotation direction
FF2↓
FF2↓
FF2↓
−
Current setting
FF2↓
FF1↓
FF2↓
−
ENABLE
FF2↓
FF1↓
FF2↓
−
The timing at which data is to be updated differs, as shown in Table 5-14, depending on the enabled status.
For example, suppose the enable signal is currently “0” (output high impedance) and “1” (output conduction) is
input by the next data. In this case, the pulse width, number of pulses, and rotation direction signals are updated at
FF2(upon the completion of start up wait), and the current setting and ENABLE signals are updated at FF1 (upon
completion of start up drive wait).
VD
FF1
Start up wait
FF2
Start up wait +
start up drive wait
Pulse output
Pulse width, number of pulses, and rotation direction
are updated.
Current setting and ENABLE are updated
(ENABLE change: 0 to 1).
VD
(1)
LATCH
I1
Initial data
identification
(2)
(3)
S1
Standard data
identification
S2
S3
I1 data is output.
FF1, FF2 output
Data Sheet S15973EJ1V0DS
19
µPD16835A
(1)
Pulse width
(2)
Internal data retained.
(3)
Updated to S2 data at FF2
Not output
Output reset
Rotation direction
Number of pulses
Internal output retained
Not output
Internal data retained.
Not output
Output reset
Current setting
Internal output retained
Not output
Updated to S2 data at either FF1 or FF2
ENABLE
Internal output retained
Not output
by enable data of (2)
The initial mode of this product is as follows.
The IC operation can be initialized as follows:
(1) Turns ON VDD.
(2) Make RESET input “L”.
(3) Input serial initial data.
In initial mode, the operating status of the IC is as shown in Table 5-15.
Table 5-15. Operations in Initial Mode
Item
Specifications
Current consumption
100 µA
OSC
Oscillation stops.
Input of external clock is inhibited.
VD
Input inhibited.
FF1 to FF7
“L” level
PULSE OUT
“L” level
EXP0 to EXP3
Undefined in the case of (1) above.
Previous value is retained in the case of (2) above.
Can be updated by serial data in the case of (3) above.
Serial operation
Can be accessed after initialization in the case of (1) above.
Can be accessed after RESET has gone “H” in the case of (2) above.
Can be accessed in the case of (3) above.
Step pulse output is inhibited and FF7 is made “L” if the following conditions are satisfied.
(1) If the set number of pulses (2nd/5th: standard data) is 00H.
(2) If the checksum value is other than 00H.
(3) If the start up wait time is set to 1 VD or longer.
(4) If the start up wait time + start up drive wait time is set to 1 VD or longer.
(5) If start up wait is completed earlier than LATCH (↓).
(6) If VD is not input.
20
Data Sheet S15973EJ1V0DS
µPD16835A
Cautions on Correct Use
(1) With this product, input the data for start up wait and start up drive wait. Because the standard data are
set or updated by these wait times, if the start up wait time and start up drive wait time are not input, the
data are not updated.
(2) The start up wait time must be longer than LATCH.
(3) If the rising of the start up drive wait time is the same as the falling of the last output pulse, a count error
occurs, and the IC may malfunction.
(4) Input the initial data in a manner that it does not straddle the video sync signal (VD). If it does, the initial
data is not latched.
(5) Transmit the standard data during the start up wait time (FF1). If it is input at any other time, the data
may
not be transmitted correctly.
(6) If the LGND potential is undefined, the data may not be input correctly. Keep the LGND potential to the
minimum level. It is recommended that LGND and PGND be divided for connection (single ground) to
prevent the leakage of noise from the output circuit.
Data Sheet S15973EJ1V0DS
21
µPD16835A
6. ELECTRICAL SPECIFICATIONS
Absolute Maximum Ratings (TA = 25°C)
Parameter
Supply voltage
Symbol
Condition
Rating
Unit
VDD
–0.5 to +6.0
V
VM
–0.5 to +11.2
V
Input voltage
VIN
–0.5 to VDD+ 0.5
V
Reference voltage
VREF
500
mV
H bridge drive current Note 1
IM(DC)
DC
±150
mA/phase
Instantaneous H bridge drive
IM(pulse)
PW ≤ 10 ms, Duty ≤ 5%
±300
mA/phase
current Note 1
Power consumption Note 2
PT
1.0
W
Peak junction temperature
TCH(MAX.)
150
°C
Storage temperature
Tstg
–55 to +150
°C
Notes 1. Permissible current per phase with the IC mounted on a PCB.
2. When the IC is mounted on a glass epoxy PCB (10 cm x 10 cm x 1 mm).
Caution
If the absolute maximum rating of even one of the above parameters is exceeded even
momentarily, the quality of the product may be degraded. Absolute maximum ratings, therefore,
specify the values exceeding which the product may be physically damaged. Be sure to use the
product within the range of the absolute maximum ratings.
Recommended Operating Range
Parameter
Supply voltage
Symbol
MIN.
TYP.
MAX.
Unit
VDD
2.7
5.5
V
VM
4.8
11
V
Input voltage
VIN
Reference voltage
VREF
0
EXP pin input voltage
VEXPIN
VDD
V
EXP pin input current
IEXPIN
100
µA
H bridge drive current
IM(DC)
+100
mA
225
250
−100
−200
Note 1
VDD
V
275
mV
H bridge drive current
IM(pulse)
Clock frequency (OSCIN)
fCLK Note 2
3.9
Clock frequency amplitude
VfCLK Note 2
0.7 VDD
Serial clock frequency (SCLK)
fSCLK
Video sync signal width
PW(VD) Note 3
250
ns
LATCH signal wait time
t(VD-LATCH) Note 4
400
ns
Note 4
4
+200
mA
4.2
MHz
VDD
V
5.0
MHz
SCLK wait time
t(SCLK-LATCH)
400
ns
SDATA setup time
tsetup Note 4
80
ns
SDATA hold time
thold Note 4
80
ns
Note 3
Chopping frequency
fOSC
Reset signal pulse width
tRST
100
32
Operating temperature
TA
−10
Peak junction temperature
TCH(MAX.)
Notes 1. PW ≤ 10 ms, duty ≤ 5%
2. COSC = 33 pF, VREF = 250 mV
3. fCLK = 4 MHz
4. Serial data delay time(see the figure on the next page.)
22
Data Sheet S15973EJ1V0DS
124
kHz
µs
+70
°C
125
°C
µPD16835A
VD
t (VD-LATCH)
LATCH
64 clocks (8 bits x 8 bytes)
SCLK
t (SCLK-LATCH)
t (SCLK-LATCH)
Ignored because LATCH is at L level.
LATCH
SDATA
SCLK
Ignored because LATCH is at L level.
50%
D1
50%
t (SCLK-LATCH)
D2
D3
50%
tsetup thold
Data Sheet S15973EJ1V0DS
23
µPD16835A
ELECTRICAL CHARACTERISTICS
DC Characteristics (Unless otherwise specified, VDD = 3.3 V, VM = 6.0 V, VREF = 250 mV, TA = 25°C, fCLK = 4 MHz,
COSC = 33 pF, CFIL = 1000 pF, EVR = 100 mV (0000))
Parameter
Symbol
Condition
MIN.
TYP.
MAX.
Unit
Off VM pin current
IMO(RESET)
No load, reset period
1.0
µA
VDD pin current
IDD
Output open
3.0
mA
VDD pin current
IDD(RESET)
Reset period
100
µA
High level input voltage
VIH
LATCH, SCLK, SDATA, VD,
Low level input voltage
VIL
RESET, OSCIN
Input hysteresis voltage
VH
Monitor output voltage 1
VOM α (H), VOM β (H) 5th byte
(EXT α, β)
VOM α (L), VOM β (L)
5th byte
Monitor output voltage 2
VOEXP(H)
Pull up (VDD)
(EXP0 to EXP3 : open drain)
VOEXP(L)
IOEXP = 100 µA
High level input current
IIH
VIN = VDD
Low level input current
IIL
VIN = 0 V
Reset pin high level input
IIH(RST)
VRST = VDD
IIL(RST)
VRST = 0
RIND
LATCH, SCLK, SDATA, VD
RON
IM = 100 mA
Chopping frequency (internal
fOSC(1)
DATA: 00000 (4th byte)
oscillation: COSC = 100 pF)
fOSC(2)
DATA: 11111 (4th byte)
Step frequency
fSTEP
Minimum step
VD delay time Note 2
∆tVD
Sine wave peak output
IM
0.7 VDD
V
0.3 VDD
300
V
mV
0.9 VDD
V
0.1 VDD
V
VDD
V
0.1 VDD
V
0.06
mA
µA
−1.0
1.0
µA
current
Reset pin low level input
µA
−1.0
current
Input pull down resistor
H bridge ON resistance
Note 1
50
3.5
kΩ
5.0
Ω
0
100
124
kHz
150
4
kHz
250
L = 25 mH/R = 100 Ω (1 kHz)
current Note 3
200
52
ns
mA
EVR = 200 mV (1010)
RS = 6.8 Ω, fOSC = 64 kHz
FIL pin voltage Note 4
FIL pin step voltage
Note 4
VEVR
EVR = 200 mV (1010)
VEVRSTEP
Minimum step
370
400
430
20
mV
mV
AC Characteristics (Unless otherwise specified, VDD = 3.3 V, VM = 6.0 V, TA = 25°C, fCLK = 4 MHz)
Parameter
Symbol
H bridge output circuit turn on tONH
Condition
MIN.
TYP.
MAX.
Unit
IM = 100 mA Note 5
1.0
2.0
µs
IM = 100 mA Note 5
1.0
2.0
µs
time
H bridge output circuit turn off tOFFH
time
Notes 1. Total of ON resistance at top and bottom of output H bridge
2. By OSCIN and VD sync circuit
3. FB pin is monitored.
4. FIL pin is monitored. A voltage about twice that of the EVR value is output to the FIL pin.
5. 10 to 90% of the pulse peak value without filter capacitor (CFIL)
24
Data Sheet S15973EJ1V0DS
TIMING CHART (1)
Initialization
RESET
VD
LATCH
Initial
DATA
I1
Standard
EXP: 1
Standard
: 1
S2 EXP
ENABLE: 1
S1
Dummy data
EXP
: 0
ENABLE: 0
Standard
S3 EXP : 1
error DATA
Standard
Standard
: 0
S4 EXP
ENABLE: 1
S5
EXP
: 1
ENABLE: 0
OSCOUT
(original oscillation)
Input at rising
edge of RESET
Start point wait
(FF1)
Output by
I1 data
Data Sheet S15973EJ1V0DS
Start point wait +
start point drive wait
(FF2)
Output by
I1 data
Output by S2
data setting
ENABLE OUTNote 1
Output by S5
data setting
Output by chopping
setting of I1 data
Chopping pulse
Output by EXP
setting of S1 data
Output by EXP
setting of I1 data
EXP0 to EXP3
Output by EXP
setting of S2DATA
S4DATA output
Pulse error
S2DATA output
PULSE OUT
PULSE GATE
(FF3)
Outputs high level for standard data while a
pulse output signal exists (LATCH cycle)
PULSE CHECKNote 2
(FF7)
CHECK SUMNote 3
High level because
data is normal.
No pulse output because
data is erroneous
Low level because
data is abnormal.
to high, and at the falling edge of FF2 when the level changes from high
to low.
D0
D1
D2
(LSB)
Data is held at rising edge of SCLK.
D3
D4
D5
D6
D7
2. FF7 is an output signal that is used to check for the presence or absence
of a pulse in the standard data, is updated at the falling edge of LATCH
and reset once at the rising edge of LATCH. If CHECK SUM is other than
“00H”, FF7 goes low, inhibiting pulse output, even if a pulse is generated.
25
3. CHECK SUM output is updated at the falling edge of LATCH.
µPD16835A
SDATA
8th byte
Restore to high level because
data is normal.
Notes 1. ENABLE is set at the falling edge of FF1 when the level changes from low
SCLK
1st byte
Enable
Outputs high level while
pulse is being generated
µPD16835A
TIMING CHART (2)
CLK
(PULSE OUT)
MOB
(CW mode)
Current direction: A2
A1
H bridge α , β
1ch output status
Current direction: A1
Current direction: B2
A2
Current direction: B2
B1
B1
H bridge α , β
2ch output status
Current direction: B1
B2
(Expanded view)
Note2
Note1
CW mode
CCW mode
Note1
CW mode
CLK
PULSE OUT
Position No.
1
2
3
4
5
6
5
4
3
2
3
4
CCW
H bridge
1ch output status
CW
CW
CCW
CW
CW
H bridge
2ch output status
CCW
CW
CW
CCW
Notes1. In CW mode : Position No. is incremented.
2. In CCW mode : Position No. is decremented.
Remarks 1. The current value of the actual wave is approximated to the value shown on the next page.
2. The C1, C2, D1, and D2 pins of β channel correspond to the A1, A2, B1, and B2 pins of α channel.
3. The CW mode is set if the D7 bit of the 2nd and 5th bytes of the standard data is “0”.
4. The CCW mode is set if the D7 bit of the 2nd and 5th bytes of the standard data is “1”.
26
Data Sheet S15973EJ1V0DS
µPD16835A
RELATION BETWEEN ROTATION ANGLE, PHASE CURRENT, AND VECTOR QUANTITY
(64-DIVISION MICRO STEP)
(Values of µPD16835A for reference)
Step
Rotation angle (θ )
A phase current
B phase current
Vector quantity
MIN.
TYP.
MAX.
MIN.
TYP.
MAX.
θ0
0
−
0
−
−
100
−
TYP.
100
θ1
5.6
2.5
9.8
17.0
−
100
−
100.48
θ2
11.3
12.4
19.5
26.5
93.2
98.1
103
100
θ3
16.9
22.1
29.1
36.1
90.7
95.7
100.7
100.02
θ4
22.5
31.3
38.3
45.3
87.4
92.4
97.4
100.02
θ5
28.1
40.1
47.1
54.1
83.2
88.2
93.2
99.99
θ6
33.8
48.6
55.6
62.6
78.1
83.1
88.1
99.98
θ7
39.4
58.4
63.4
68.4
72.3
77.3
82.3
99.97
θ8
45
65.7
70.7
75.7
65.7
70.7
75.7
99.98
θ9
50.6
72.3
77.3
82.3
58.4
63.4
68.4
99.97
θ 10
56.3
78.1
83.1
88.1
48.6
55.6
62.6
99.98
θ 11
61.9
83.2
88.2
93.2
40.1
47.1
54.1
99.99
θ 12
67.5
87.4
92.4
97.4
31.3
38.3
45.3
100.02
θ 13
73.1
90.7
95.7
100.7
22.1
29.1
36.1
100.02
θ 14
78.8
93.2
98.1
103
12.4
19.5
26.5
100
θ 15
84.4
−
100
−
2.5
9.8
17.0
100.48
θ 16
90
−
100
−
−
0
−
100
Remark These data do not indicate guaranteed values.
Data Sheet S15973EJ1V0DS
27
µPD16835A
7. PACKAGE DRAWING
38-PIN PLASTIC SSOP (7.62 mm (300))
38
20
detail of lead end
F
G
1
P
19
A
L
E
H
I
J
S
C
N
S
B
K
D
M
M
NOTE
Each lead centerline is located within 0.10 mm of
its true position (T.P.) at maximum material condition.
ITEM
A
MILLIMETERS
12.7±0.3
B
0.65 MAX.
C
0.65 (T.P.)
D
0.37 +0.05
−0.1
E
0.125±0.075
F
1.675±0.125
G
1.55
H
7.7±0.2
I
5.6±0.2
J
1.05±0.2
K
0.2 +0.1
−0.05
L
0.6±0.2
M
0.10
N
0.10
P
+7°
3° −3°
P38GS-65-BGG-1
28
Data Sheet S15973EJ1V0DS
µPD16835A
8. RECOMMENDED SOLDERING CONDITIONS
When soldering this product, it is highly recommended to observe the conditions as shown below. If other
soldering processes are used, or if the soldering is performed under different conditions, please make sure to consult
with our sales offices.
For more details, refer to our document “SEMICONDUCTOR DEVICE MOUNTING TECHNOLOGY MANUAL”
(C10535E).
Type of Surface Mount Device
µPD16835AGS-BGG: 38-pin plastic shrink SOP (7.62 mm (300))
Process
Infrared Ray Reflow
Soldering conditions
Peak temperature: 235°C or below (Package surface temperature),
Symbol
IR35-00-3
Reflow time: 30 seconds or less (at 210°C or higher),
Maximum number of reflow processes: 3 time or less,
Number of days: None Note,
Flux: Rosin-based flux with low chlorine content (chlorine 0.2 Wt% or below) is
recommended.
Vapor Phase Soldering
Peak temperature: 215°C or below (Package surface temperature),
VP15-00-3
Reflow time: 40 seconds or less (at 200°C or higher),
Maximum number of reflow processes: 3 time or less,
Number of days: None Note,
Flux: Rosin-based flux with low chlorine content (chlorine 0.2 Wt% or below) is
recommended.
Wave Soldering
Solder temperature: 260°C or below, Flow time: 10 seconds or less,
WS60-00-1
Maximum number of flow processes: 1 time,
Pre-heating temperature: 120°C or below (Package surface temperature),
Flux: Rosin-based flux with low chlorine content (chlorine 0.2 Wt% or below) is
recommended.
Partial Heating Method
Pin temperature: 300°C or below,
−
Heat time: 3 seconds or less (Per each side of the device).
Note Number of days the device can be stored after the dry pack has been opened, at conditions of 25°C, 65%RH.
Caution Apply only one kind of soldering condition to a device, except for “partial heating method”, or the
device will be damaged by heat stress.
Data Sheet S15973EJ1V0DS
29
µPD16835A
[MEMO]
30
Data Sheet S15973EJ1V0DS
µPD16835A
NOTES FOR CMOS DEVICES
1
PRECAUTION AGAINST ESD FOR SEMICONDUCTORS
Note:
Strong electric field, when exposed to a MOS device, can cause destruction of the gate oxide and
ultimately degrade the device operation. Steps must be taken to stop generation of static electricity
as much as possible, and quickly dissipate it once, when it has occurred. Environmental control
must be adequate. When it is dry, humidifier should be used. It is recommended to avoid using
insulators that easily build static electricity. Semiconductor devices must be stored and transported
in an anti-static container, static shielding bag or conductive material. All test and measurement
tools including work bench and floor should be grounded. The operator should be grounded using
wrist strap. Semiconductor devices must not be touched with bare hands. Similar precautions need
to be taken for PW boards with semiconductor devices on it.
2
HANDLING OF UNUSED INPUT PINS FOR CMOS
Note:
No connection for CMOS device inputs can be cause of malfunction. If no connection is provided
to the input pins, it is possible that an internal input level may be generated due to noise, etc., hence
causing malfunction. CMOS devices behave differently than Bipolar or NMOS devices. Input levels
of CMOS devices must be fixed high or low by using a pull-up or pull-down circuitry. Each unused
pin should be connected to V DD or GND with a resistor, if it is considered to have a possibility of
being an output pin. All handling related to the unused pins must be judged device by device and
related specifications governing the devices.
3
STATUS BEFORE INITIALIZATION OF MOS DEVICES
Note:
Power-on does not necessarily define initial status of MOS device. Production process of MOS
does not define the initial operation status of the device. Immediately after the power source is
turned ON, the devices with reset function have not yet been initialized. Hence, power-on does
not guarantee out-pin levels, I/O settings or contents of registers. Device is not initialized until the
reset signal is received. Reset operation must be executed immediately after power-on for devices
having reset function.
Data Sheet S15973EJ1V0DS
31
µPD16835A
• The information in this document is current as of January, 2002. The information is subject to
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M8E 00. 4