RENESAS RD74VT1G245

RD74VT1G245
Bus Transceiver with 3–state Output /
Dual Supply Voltage Translator
REJ03D0494–0200
Rev.2.00
Apr. 01, 2005
Description
The RD74VT1G245 has one buffer in a 6 pin package. When DIR is high, data is transferred from the A inputs to the
B outputs, and when DIR is low, data is transferred from the B inputs to the A outputs. And this product has two
terminals (VCCA, VCCB), VCCA is connected with control input and A bus side VCCB is connected with B bus side. VCCA
and VCCB are isolated. The A port is designed to track VCCA, which accepts voltages from 1.2V to 3.6V, and the B port
is designed to track VCCB, which operation at 1.2V to 3.6V. Therefore, Bidirectional board voltage conversion is
possible. Low voltage and high-speed operation is suitable for the battery powered products (e.g., notebook computers),
and the low power consumption extends the battery life.
Features
• This product function as level shift transceiver that change VCCA input level to VCCB output level, VCCB input level to
VCCA output level by providing different supply voltage to VCCA and VCCB.
• Supply voltage range:
VCCA = 1.2 to 3.6 V
VCCB = 1.2 to 3.6 V
40 to +85°C
• Operating temperature range: −40
• Control input VI(max) = 3.6 V
(@VCCA = 0 to 3.6 V)
• A bus side input outputs VI/O (max) = 3.6 V
(@VCCA = 0 V or Output off state)
• B bus side input outputs VI/O (max) = 3.6 V
(@VCCB = 0 V or Output off state)
• High output current
A bus side: ±2 mA (@VCCA = 1.2 V)
B bus side:
±2 mA (@VCCB = 1.2 V)
±4 mA (@VCCA = 1.5±0.1 V)
±4 mA (@VCCB = 1.5±0.1 V)
±6 mA (@VCCA = 1.8±0.15 V)
±6 mA (@VCCB = 1.8±0.15 V)
±18 mA (@VCCA = 2.5±0.2 V)
±18 mA (@VCCB = 2.5±0.2 V)
±24 mA (@VCCA = 3.3±0.3 V)
±24 mA (@VCCB = 3.3±0.3 V)
• Ordering Information
Part Name
RD74VT1G245CLE
Package Type
Package Code
(Previous Code)
Package
Abbreviation
WCSP–6 pin
SXBG0006KB–A
(TBS–6AV)
CL
Rev.2.00 Apr. 01, 2005 page 1 of 13
Taping Abbreviation
(Quantity)
E (3,000 pcs / reel)
RD74VT1G245
Article Indication
Marking
Year code
Month code
VYYM
Function Table
Input
DIR
Operation
L
B→A
H
A→B
H: High level
L: Low level
Pin Arrangement
0.9 mm
3
4
A
2
5
DIR
1
6
(Bottom view)
Rev.2.00 Apr. 01, 2005 page 2 of 13
B
VCCB
1.4 mm
Height 0.5 mm
0.5 mm pitch
0.23 mm 6–Ball (CL) GND
Pin#1 INDEX
VCCA
(Top view)
RD74VT1G245
Logic Diagram
DIR
A
B
Absolute Maximum Ratings
Item
Supply voltage range
Input voltage range *1
Input/output voltage range
*1, 2
Symbol
Ratings
Unit
VCCA, VCCB
–0.5 to 4.6
V
VI
–0.5 to 4.6
V
DIR
VI/O
–0.5 to VCCA+0.5
V
A port output: “H” or “L”
–0.5 to 4.6
A port output: “Z” or VCCA: OFF
–0.5 to VCCB+0.5
B port output: “H” or “L”
–0.5 to 4.6
B port output: “Z” or VCCB: OFF
Input clamp current
IIK
–50
mA
Output clamp current
IOK
–50
mA
50
IO
±50
mA
Continuous output current
VCC or GND
ICCA, ICCB, IGND
±100
mA
θja
123
°C/W
Tstg
–65 to 150
°C
Storage temperature
Notes:
VI < 0
VO < 0
VO > VCC+0.5
Continuous output current
Package Thermal impedance
Conditions
The absolute maximum ratings are values, which mu
must not individually be exceeded, and furthermore, no two
of which may be realized at the same time.
1. The input and output voltage ratings may be exceeded if the input and output clamp-current ratings are
observed.
2. This value is limited to 4.6 V maximum.
Rev.2.00 Apr. 01, 2005 page 3 of 13
RD74VT1G245
Recommended Operating Conditions
Item
Supply voltage range
Input/Output voltage
Symbol
Ratings
Unit
VCCA
1.2 to 3.6
V
VCCB
1.2 to 3.6
VI
0 to 3.6
V
DIR
VI/O
0 to VCCA
V
A port output: “H” or “L”
0 to 3.6
A port output: “Z” or VCCA: OFF
0 to VCCB
B port output: “H” or “L”
0 to 3.6
Output current
IOHA
IOHB
–2
B port output: “Z” or VCCB: OFF
mA
VCCA = 1.5±0.1 V
–6
VCCA = 1.8±0.15 V
–18
VCCA = 2.5±0.2 V
–24
VCCA = 3.3±0.3 V
–2
mA
VCCB = 1.2 V
–4
VCCB = 1.5±0.1 V
–6
VCCB = 1.8±0.15 V
–18
VCCB = 2.5±0.2 V
2
VCCB = 3.3±0.3 V
mA
VCCA = 1.2 V
4
VCCA = 1.5±0.1 V
6
VCCA = 1.8±0.15 V
18
VCCA = 2.5±0.2 V
24
IOLB
VCCA = 1.2 V
–4
–24
IOLA
2
VCCA = 3.3±0.3 V
mA
VCCB = 1.2 V
4
VCCB = 1.5±0.1 V
6
VCCB = 1.8±0.15 V
18
VCCB = 2.5±0.2 V
VCCB = 3.3±0.3 V
24
Input transition rise or fall time
∆t / ∆v
10
ns / V
Operation free-air temperature
Ta
–40 to 85
°C
Rev.2.00 Apr. 01, 2005 page 4 of 13
Conditions
RD74VT1G245
Electrical Characteristics
(Ta = −40 to 85°C)
Item
Input voltage
Symbol
VIHA
VIHB
VILA
VILB
Output voltage
VOH
*
VCCA (V)
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
1.2 to 3.6
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
1.2 to 3.6
*
VCCB (V)
1.2 to 3.6
Typ

































Max










VCCA×0.25
VCCA×0.30
VCCA×0.35
0.7
0.8
VCCB×0.25
VCCB×0.30
VCCB×0.35
0.7
0.8






0.2
0.3
0.3
0.3
0.6
0.55
1.5
Unit
V
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
1.2 to 3.6
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
1.2 to 3.6
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
3.6
Min
VCCA×0.75
VCCA×0.70
VCCA×0.65
1.6
2.0
VCCB×0.75
VCCB×0.70
VCCB×0.65
1.6
2.0










VCC−0.2
0.9
1.1
1.25
1.7
2.2






–1.5
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
1.2 to 3.6
Test conditions
A port
Control input
V
B port
V
A port
Control input
V
B port
V
IOH = –100 µA
IOH = –2 mA
IOH = –4 mA
IOH = –6 mA
IOH = –18 mA
IOH = –24 mA
IOL = 100 µA
IOL = 2 mA
IOL = 4 mA
IOL = 6 mA
IOL = 18 mA
IOL = 24 mA
VIN = GND or VCCA
control input
VIN = VIH or VIL
Input current
IIN
1.2 to 3.6
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
1.2 to 3.6
1.2
1.5±0.1
1.8±0.15
2.5±0.2
3.3±0.3
3.6
Off state output
current
Output leakage
current
Quiescent
supply current
IOZ
3.6
3.6
–1.5

1.5
µA
IOFF
0
0


1.5
µA
ICCA
1.2 to 3.6
1.2 to 3.6
–3.0

3.0
µA
ICCB
1.2 to 3.6
1.2 to 3.6
–3.0

3.0
∆ICCA
3.6
3.6


250
∆ICCB
3.6
3.6


250
CIN
3.3
3.3

3.5

pF
VIN, VOUT =
0 to 3.6 V
IO(A port) = 0
VIN = VCCB or GND
IO(B port) = 0
VIN = VCCA or GND
A port or control
VCCA–0.6 (1 input)
B port
VCCB–0.6 (1 input)
VIN = VCC or GND
CI/O
3.3
3.3

6.0

pF
VO = VCC or GND
VOL
Increase in ICC
per input
Input
capacitance
Input/output
capacitance
V
µA
µA
Note: For conditions shown as Min or Max, use the appropriate values under recommended operating conditions.
Rev.2.00 Apr. 01, 2005 page 5 of 13
RD74VT1G245
Switching Characteristics
VCCA = 3.3±0.3 V
Ta = –40 to 85°C
Item
Propagation
delay time
VCCB=
VCCB=
1.2 V 1.5±0.1 V
From
To
Symbol (input) (output) Typ Min Max
tPLH
A
B
tPHL
tPLH
B
A
tPHL
Output
tHZ
Disable time
tLZ
tHZ
DIR
A
*1
tZH
Enable time
tZL
Note:
VCCB=
3.3±0.3 V
Min
Max
Min
Max
Min
Test
Max Unit conditions
9.1
2.0
8.8
1.5
5.8
1.0
4.0
1.0
3.2
9.1
2.0
8.8
1.5
5.8
1.0
4.0
1.0
3.2
4.0
1.0
4.2
1.0
3.8
1.0
3.4
1.0
3.2
4.0
1.0
4.2
1.0
3.8
1.0
3.4
1.0
3.2
4.0
1.0
4.5
1.0
4.5
1.0
4.5
1.0
4.5
4.0
1.0
4.5
1.0
4.5
1.0
4.5
1.0
4.5
8.0
1.0
6.0
1.0
5.5
B
11.2
2.0
10.2
1.5
11.2
2.0
10.2
1.5
8.0
1.0
6.0
1.0
5.5
DIR
A
15.2

14.4

11.8

9.4

8.7
15.2

14.4

11.8

9.4

8.7
*1
tZH*1
tZL*1
VCCB=
2.5±0.2 V
DIR
tLZ
Output
VCCB=
1.8±0.15 V
DIR
B
13.1

13.3

10.3

8.5

7.7
13.1

13.3

10.3

8.5

7.7
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
1. The enable time is a calculated value, derived using
ing the formula shown in the section entitled enable times on
page 12.
VCCA = 2.5±0.2 V
Ta = –40 to 85°C
Item
Propagation
delay time
From
To
Symbol (input) (output)
tPLH
A
B
tPHL
tPLH
B
A
DIR
A
tPHL
Output
tHZ
Disable time
tLZ
tHZ
DIR
B
tLZ
Output
tZH*1
Enable time
tZL*1
tZH*1
tZL
Note:
DIR
DIR
A
B
*1
VCCB=
1.2 V
Typ
VCCB=
1.5±0.1 V
VCCB=
1.8±0.15 V
VCCB=
2.5±0.2 V
VCCB=
3.3±0.3 V
Min
Min
Min
Min
Max
Max
Max
Test
Max Unit conditions
9.5
2.0
9.2
1.5
6.0
6.
1.0
4.2
1.0
3.4
9.5
2.0
9.2
1.5
6.
6.0
1.0
4.2
1.0
3.4
4.7
1.0
4.8
1.0
4.6
4.
1.0
4.2
1.0
4.0
4.7
1.0
4.8
1.0
4.
4.6
1.0
4.2
1.0
4.0
4.2
1.0
4.7
1.0
4.7
4.
1.0
4.7
1.0
4.7
4.2
1.0
4.7
1.0
4.
4.7
1.0
4.7
1.0
4.7
11.2
2.0
10.6
1.5
8.4
1.0
6.0
1.0
6.0
11.2
2.0
10.6
1.5
8.4
8.
1.0
6.0
1.0
6.0
15.9

15.4

13.0

10.2

10.0
15.9

15.4

13.0

10.2

10.0
13.7

13.9

10.7

8.9

8.1
13.7

13.9

10.7

8.9

8.1
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
1. The enable time is a calculated value, derived using the formula shown in the section entitled enable times on
page 12.
Rev.2.00 Apr. 01, 2005 page 6 of 13
RD74VT1G245
Switching Characteristics (Cont.)
VCCA = 1.8±0.15 V
Ta = –40 to 85°C
Item
Propagation
delay time
VCCB=
VCCB=
1.2 V 1.5±0.1 V
From
To
Symbol (input) (output) Typ Min Max
tPLH
A
B
tPHL
tPLH
B
A
tPHL
Output
tHZ
Disable time
tLZ
tHZ
DIR
A
DIR
B
DIR
A
tLZ
*1
Output
tZH
Enable time
tZL
*1
tZH*1
tZL*1
Note:
DIR
B
VCCB=
1.8±0.15 V
VCCB=
2.5±0.2 V
VCCB=
3.3±0.3 V
Min
Max
Min
Max
Min
Test
Max Unit conditions
9.8
2.0
9.6
1.5
6.5
1.0
4.6
1.0
3.8
9.8
2.0
9.6
1.5
6.5
1.0
4.6
1.0
3.8
6.4
1.5
7.2
1.5
6.5
1.5
6.0
1.5
5.8
6.4
1.5
7.2
1.5
6.5
1.5
6.0
1.5
5.8
5.5
1.5
7.5
1.5
7.5
1.5
7.5
1.5
7.5
5.5
1.5
7.5
1.5
7.5
1.5
7.5
1.5
7.5
12.0
2.0
11.5
1.5
9.2
1.0
7.2
1.0
7.0
12.0
2.0
11.5
1.5
9.2
1.0
7.2
1.0
7.0
18.4

18.7

15.7

13.2

12.8
18.4

18.7

15.7

13.2

12.8
15.3

17.1

14.0

12.1

11.3
15.3

17.1

14.0

12.1

11.3
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
1. The enable time is a calculated value, derived using
ing the formula shown in the section entitled enable times on
page 12.
VCCA = 1.5±0.1 V
Ta = –40 to 85°C
Item
Propagation
delay time
From
To
Symbol (input) (output)
tPLH
A
B
tPHL
tPLH
B
A
DIR
A
tPHL
Output
tHZ
Disable time
tLZ
tHZ
DIR
B
tLZ
Output
tZH*1
Enable time
tZL*1
tZH*1
tZL
Note:
DIR
DIR
A
B
*1
VCCB=
1.2 V
Typ
VCCB=
1.5±0.1 V
VCCB=
1.8±0.15 V
VCCB=
2.5±0.2 V
VCCB=
3.3±0.3 V
Min
Min
Min
Min
Max
Max
Max
Test
Max Unit conditions
10.0
2.0
10.5
1.5
7.2
1.0
4.8
1.0
4.2
10.0
2.0
10.5
1.5
7.2
7.
1.0
4.8
1.0
4.2
8.0
2.0
10.5
2.0
9.6
2.0
9.2
2.0
8.8
8.0
2.0
10.5
2.0
9.
9.6
2.0
9.2
2.0
8.8
6.0
2.0
10.0
2.0
10.0
10.
2.0
10.0
2.0
10.0
6.0
2.0
10.0
2.0
10.
10.0
2.0
10.0
2.0
10.0
12.5
2.0
12.7
1.5
12.0
12.
1.0
10.7
1.0
7.5
12.5
2.0
12.7
1.5
12.0
12.
1.0
10.7
1.0
7.5
20.5

23.2

21.6

19.9

16.3
20.5

23.2

21.6

19.9

16.3
16.0

20.5

17.2

14.8

14.2
16.0

20.5

17.2

14.8

14.2
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
1. The enable time is a calculated value, derived using the formula shown in the section entitled enable times on
page 12.
Rev.2.00 Apr. 01, 2005 page 7 of 13
RD74VT1G245
Switching Characteristics (Cont.)
VCCA = 1.2 V
Ta = –40 to 85°C
Item
Propagation
delay time
From
To
Symbol (input) (output)
tPLH
A
B
tPHL
tPLH
B
A
tPHL
Output
tHZ
Disable time
tLZ
tHZ
DIR
A
*1
tZH
Enable time
tZL
Note:
VCCB=
3.3±0.3 V
Typ
Typ
Typ
Typ
Typ
10.5
8.0
6.4
4.7
4.0
10.5
8.0
6.4
4.7
4.0
10.5
10.0
9.8
9.5
9.1
10.5
10.0
9.8
9.5
9.1
8.0
8.0
8.0
8.0
8.0
8.0
8.0
8.0
8.0
8.0
10.5
9.5
7.5
7.5
B
13.5
13.5
10.5
9.5
7.5
7.5
DIR
A
24.0
20.5
19.3
17.0
16.6
24.0
20.5
19.3
17.0
16.6
18.5
16.0
14.4
12.7
12.0
18.5
16.0
14.4
12.7
12.0
*1
tZH*1
tZL*1
VCCB=
VCCB=
VCCB=
1.5±0.1 V 1.8±0.15 V 2.5±0.2 V
DIR
tLZ
Output
VCCB=
1.2 V
DIR
B
Test
Unit conditions
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
ns CL = 15pF
RL = 2.0kΩ
1. The enable time is a calculated value, derived using
ing the formula shown in the section entitled enable times on
page 12.
Operating Characteristics
Ta = 25°C
Item
Power dissipation
capacitance
Symbol VCCA (V) VCCB (V) Min
CPD
3.3
3.3

Typ
12
Max
Unit

pF
Test conditions
f = 10 MHz
CL = 0
Power–up considerations
Level–translation devices offer an opportunity for successful mixed–voltage signal design.
A proper power–up sequence always should be followed to aavoid excessive supply current, bus contention, oscillations,
or other anomalies caused by improperly biased device pins.
Take these precautions to guard against such power–up problems.
1.
Connect ground before any supply voltage is applied.
2.
Next, power up the control side of the device. (Power up of VCCA is first. Next power up is VCCB)
3.
Depending on the direction of the data path, DIR can be high or low. If DIR high is needed (A data to B bus),
ramp it with VCCA. Otherwise, DIR low is needed (B data to A bus), ramp it with GND.
Rev.2.00 Apr. 01, 2005 page 8 of 13
RD74VT1G245
Test Circuit
See under table
2 kΩ
S1
OPEN
GND
*1
CL = 15 pF
2 kΩ
Load circuit for outputs
Symbol
S1
t PLH / tPHL
OPEN
t ZH / t HZ
GND
t ZL / t LZ
2 × VCC
Note: 1. CL includes probe and jig capacitance.
Rev.2.00 Apr. 01, 2005 page 9 of 13
RD74VT1G245
• Waveforms – 1
tr
tf
Vref
Input
VIH
90 %
Vref
90 %
10 %
10 %
t PLH
GND
t PHL
VOH
output
Vref
Vref
VOL
• Waveforms – 2
Input DIR
tr
tf
90 %
Vref
10 %
90 %
90 %
10 %
t ZL
10 %
GND
VOH
Output A or B
Waveform–1
Vref
VL
t ZH
Output A or B
Waveform–2
Symbol
VIH
90 %
Vref
10 %
t LZ
VOL
t HZ
VOH
VH
Vref
VOL
V CC = 1.2 V,
0.1 V
1.5±0.1
V CC = 1.8
1.8±0.15 V V CC = 2.5
2.5±0.2 V
V CC = 3.3±0.3 V
tr / t f
2.0 ns
2.0 ns
2.0 ns
2.0 ns
V IH
VCC
VCC
VCC
VCC
V ref
1/2 VCC
1/2 VCC
1/2 VCC
1/2 VCC
VH / V L
VH = VOH-0.1 V
VL = VOL+0.1 V
VH = VOH-0.15 V VH = VOH-0.15 V VH = VOH-0.3 V
VL = VOL+0.15 V VL = VOL+0.15 V VL = VOL+0.3 V
Notes: 1. Input waveform : PRR ≤ 10 MHz, Zo = 50 Ω, duty cycle 50%.
2. Waveform – 1 is for an output with internal conditions such that the output is low
except when disabled by the output control.
3. Waveform – 2 is for an output with internal conditions such that the output is high
except when disabled by the output control.
4. The output are measured one at a time with one transition per measurement.
Rev.2.00 Apr. 01, 2005 page 10 of 13
RD74VT1G245
Application Information
Figure 1 is an example circuit of the RD74VT1G245 being used in a bidirectional logic level–shifting application.
VCC1
VCC2
1
6
VCC1
VCC2
2
5
3
4
SYSTEM–2
SYSTEM–1
Figure 1. Bidirectional Logic Level–Shifting Application
Pin Description
PIN
NAME
FUNCTION
1
DIR
DIR
The GND (low–level) determines B–port to A–port direction
2
A
OUT
Output level depends on VCC1 voltage
3
GND
GND
4
B
IN
5
VCCB
VCC2
SYSTEM–2 supply voltage (1.2V to 3.6V)
6
VCCA
VCC1
SYSTEM–1 supply voltage (1.2V to 3.6V)
Rev.2.00 Apr. 01, 2005 page 11 of 13
DESCRIPTION
Device GND
Input threshold value depends on VCC2 voltage
RD74VT1G245
Application Information (Cont.)
Figure 2 shows the RD74VT1G245 used in a bidirectional logic level–shifting application. Since the RD74VT1G245
does not have an output enable (OE) pin, the system designer should take precautions to avoid bus contention between
SYSTEM–1 and SYSTEM–2 when changing directions.
VCC1
VCC1
VCC2
VCC2
Pullup/Down
or Bus–Hold*
Pullup/Down
I/O–1
DIR CTRL
1
6
2
5
3
4
or Bus–Hold*
SYSTEM–1
Notes:
I/O–2
SYSTEM–2
Following is a sequence that illustrates data transmission from SYSTEM–1 to SYSTEM–2 and then from SYSTEM–2
to SYSTEM–1.
STATE DIR CTRL
I/O–1
I/O–2
DESCRIPTION
1
H
IN
OUT
SYSTEM–1 data to SYSTEM–2
2
H
HI–Z
HI–Z
SYSTEM–2 is getting ready to send data to SYSTEM–1. I/O–1 and
I/O–2 are disabled. The bus–line state depends on Pull–up or Down.*
3
L
HI–Z
HI–Z
DIR bit is flipped. I/O–1 and I/O–2 are atill disabled. The bus–line
state depends on Pull–up or Down.*
4
L
OUT
IN
SYSTEM–2 data to SYSTEM–1
*: SYSTEM–1 and SYSTEM–2 must use same conditions, i.e., both pull–up or both pull–down.
Figure 2. Bidirectional Logic Level-Shifting Application
Calculate the enable times for the RD74VT1G245 using the following formulas:
1. tZH (DIR to A) = tLZ (DIR to B) + tPLH (B to A)
2. tZL (DIR to A) = tHZ (DIR to B) + tPHL (B to A)
3. tZH (DIR to B) = tLZ (DIR to A) + tPLH (A to B)
4. tZL (DIR to B) = tHZ (DIR to A) + tPHL (A to B)
In a bidirectional application, these enable times provide the maximum delay from the time the DIR bit is switched until
an output is expected. For example, if the RD74VT1G245 initially is transmitting from A to B, then the DIR bit is
switched, the B port of the device must be disabled before presenting it with an input. After the B port has been
disabled, an input signal applied to it appears on the corresponding A port after the specified propagation delay.
Rev.2.00 Apr. 01, 2005 page 12 of 13
RD74VT1G245
Package Dimensions
JEITA Package Code
S-XFBGA6-0.9x1.4-0.50
RENESAS Code
SXBG0006KB-A
Previous Code
TBS-6AV
MASS[Typ.]
0.001g
e
ZD
D
ZE
C
E
B
e
B
A
1
Pin#1 index area
2
A
6 × φb
y1 C
φ× M C A B
φ× M C
Reference
Symbol
* Reference value.
Rev.2.00 Apr. 01, 2005 page 13 of 13
Max
0.50
A1
0.155
0.185
(0.315) *
A2
0.25
0.20
D
0.90
E
1.40
e
0.50
x
0.05
y
0.05
A
A1
y C
A2
Seating plane
Nom
A
b
C
Dimension in Millimeters
Min
0.20
y
1
Z
D
0.20
Z
E
0.20
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