NAIS AQY221N2VY

RF (Radio Frequency)
C (by)
✕ R 10 SSOP Type
4.45
.175
1.80
.071
2.65
.104
mm inch
1
4
2
3
UL
CSA
pending
pending
PhotoMOS
RELAYS
FEATURES
TYPICAL APPLICATIONS
1. Reduced package size
Lower surface has been reduced 60%
and mounting space 40% compared to
conventional 4-pin SOP type.
2. Lower output capacitance and onresistance
Output capacitance(C): 1.0pF (typ.)
ON resistance(R): 9.5Ω (typ.)
3. Mounting space has been reduced
and output signals have been
improved by using new flat lead
terminals.
Measuring and testing equipment
1. Test equipment
IC tester, Liquid crystal driver tester,
semiconductor performance tester
2. Board tester
Bear board tester, In-circuit tester,
function tester
3. Medical equipment
Ultrasonic wave diagnostic machine
4. Multi-point recorder
Warping, thermo couple
Conventional
SOP type
SSOP
Flat lead
4. High speed switching
Turn on time: 0.02ms
Turn off time: 0.02ms
TYPES
Circuit
arrangement
Type
1 Form A
AC/DC type
Output rating*
Load voltage Load current
40 V
120 mA
Tape and reel packing style
Picked from the 1/4-pin side Picked from the 2/3-pin side
AQY221N2VY
AQY221N2VW
Packing quantity
in tape and reel
3,500 pcs.
* Indicate the peak AC and DC values.
Notes: (1)Tape package is the standard packing style.
(2)For space reasons, the initial letters of the product number “AQY and V”, the package type indicator “Y” and “W” are omitted from the seal.
RATING
1. Absolute maximum ratings (Ambient temperature: 25°C 77°F)
Item
LED forward current
LED reverse voltage
Input
Peak forward current
Power dissipation
Load voltage (peak AC)
Continuous load current (peak AC)
Output
Peak load current
Power dissipation
Total power dissipation
I/O isolation voltage
Temperature Operating
limits
Storage
2
Symbol
IF
VR
IFP
Pin
VL
IL
Ipeak
Pout
PT
Viso
Topr
Tstg
AQY221N2V
50mA
3V
1A
75mW
40V
0.12A
0.3A
250mW
300mW
1,500V AC
–40°C to +85°C –40°F to +185°F
–40°C to +100°C –40°F to +212°F
Remarks
f=100 Hz, Duty factor=0.1%
Peak AC,DC
100 ms (1 shot), VL= DC
Non-condensing at low temperatures
AQY221N2V
2. Electrical characteristics (Ambient temperature: 25°C 77°F)
Item
Symbol
AQY221N2V
Typical
1.0 mA
LED operate current
IFon
IL = 80 mA
Maximum
3.0 mA
Minimum
Input
0.2 mA
LED turn off current
IFoff
IL = 80 mA
Typical
0.9 mA
Typical
1.14 V (1.35 V at IF = 50mA)
LED dropout voltage
VF
IF = 5mA
Maximum
1.5 V
9.5Ω
Typical
On resistance
Ron
IF = 5mA
IL = 80 mA
Within 1 s on time
IF = 0
VB = 0 V
f = 1 MHz
12.5Ω
Maximum
Typical
Output
Condition
1.0 pF
Output capacitance
Cout
Maximum
1.5 pF
Typical
0.01 nA
Off state leakage current
IF = 0
VL = Max.
ILeak
Maximum
10 nA
Typical
IF = 5mA
VL = 10V
RL = 125Ω
IF = 5mA
VL = 10V
RL = 125Ω
0.02 ms
Turn on time*
Ton
Maximum
0.5ms
Typical
0.02ms
Switching speed
Turn off time*
Transfer
characteristics
Toff
Maximum
0.2 ms
Typical
0.8 pF
I/O capacitance
1.5 pF
f = 1MHz
VB = 0
1,000MΩ
500V DC
Ciso
Maximum
Initial I/O isolation resistance
Minimum
Riso
Note: Recommendable LED forward current IF = 5 mA.
For type of connection, see Page 5.
*Turn on/Turn off time
Input
90%
10%
Output
Ton
Toff
REFERENCE DATA
Allowable ambient temperature: –40°C to +85°C
–40°F to +185°F
2. Load current vs. Load voltage characteristics
Ambient temperature: 25°C 77°F
Measured portion: between terminals 3 and 4
LED current: 5 mA; Load voltage: Max. (DC);
Load current: 80mA (DC)
140
Load current, mA
Load current, mA
120
100
80
60
3. On resistance vs. ambient temperature
characteristics
200
25
160
20
On resistance, Ω
1. Load current vs. ambient temperature
characteristics
120
80
15
10
40
40
5
20
0
-40
-20
0
20
40
60
8085 100
Ambient temperature, °C
0
0
10
20
30
Load voltage, V
40
50
0
-40
-20
0
20 40
60 8085
Ambient temperature, °C
3
AQY221N2V
5. Turn off time vs. ambient temperature
characteristics
6. LED operate current vs. ambient
temperature characteristics
Measured portion: between terminals 3 and 4
LED current: 5 mA; Load voltage: 10V (DC);
Continuous load current: 80mA (DC)
LED current: 5 mA; Load voltage: 10V (DC);
Continuous load current: 80mA (DC)
Load voltage: Max. (DC);
Continuous load current: 80mA (DC)
0.1
0.08
0.08
0.06
0.04
2
LED operate current, mA
0.1
Turn off time, ms
Turn on time, ms
4. Turn on time vs. ambient temperature
characteristics
0.06
0.04
1.5
1
0.5
0.02
0.02
0
-40
-20
0
20
40
60
0
8085
-40
-20
Ambient temperature, °C
0
20
40
60
0
8085
-40
-20
0
20
40
60
8085
Ambient temperature, °C
Ambient temperature, °C
7. LED turn off current vs. ambient temperature
characteristics
8. LED dropout voltage vs. ambient
temperature characteristics
9. Voltage vs. current characteristics of output
at MOS portion
Load voltage: Max. (DC);
Continuous load current: 80mA (DC)
LED current: 5 to 50 mA
Measured portion: between terminals 3 and 4
Ambient temperature: 25°C 77°F
1.5
1
Current, mA
LED dropout voltage, V
LED turn off current, mA
120
1.5
2
1.4
1.3
1.1
-40
-20
0
20
40
60
1.0
8085
-40 -20
Ambient temperature, °C
Measured portion: between terminals 3 and 4
Ambient temperature: 25°C 77°F
0.5 1 1.5 2.0 2.5 3.0
-20 Voltage, V
0
20
40
60
-40
-60
10mA
-80
5mA
-100
-120
8085 100
11. LED forward current vs. turn on time
characteristics
12. LED forward current vs. turn off time
characteristics
Measured portion: between terminals 3 and 4
Load voltage: 10V (DC); Continuous load current:
80mA (DC); Ambient temperature: 25°C 77°F
Measured portion: between terminals 3 and 4
Load voltage: 10V (DC); Continuous load current:
80mA (DC); Ambient temperature: 25°C 77°F
0.12
-6
10-9
0.1
0.08
0.09
Turn off time, µs
Turn on time, µs
10-3
Off state leakage current, A
40
Ambient temperature, °C
10. Off state leakage current
10
60
30mA
20mA
0.5
0
80
20
-3.0-2.5 -2.0 -1.5-1.0 -0.5
50mA
1.2
100
0.06
0.06
0.04
0.03
0.02
10-12
0
0
10
20
30
40
0
50
10
20
Load voltage, V
30
50
40
0
60
0
10
20
30
40
50
14. Isolation characteristics
(50Ω impedance)
15. Insertion loss characteristics
(50Ω impedance)
Measured portion: between terminals 3 and 4
Frequency: 1 MHz, 30m Vrms; Ambient temperature:
25°C 77°F
Measured portion: between terminals 3 and 4
Ambient temperature: 25°C 77°F
Measured portion: between terminals 3 and 4
Ambient temperature: 25°C 77°F
2
80
1.5
40
0.5
20
1.5
1
0.5
0
10
20
30
40
Applied boltage, V
4
60
1
0
2
Insertion loss, dB
100
Isolation, dB
Output capacitance, pF
13. Applied voltage vs. output capacitance
characteristics
2.5
60
LED forward current, mA
LED forward current, mA
50
0 4
10
105
106
107
Frequency, Hz
108
0
104
105
106
Frequency, Hz
107
AQY221N2V
16. On resistance distribution
17. Turn on time distribution
18. Turn off time distribution
Measured portion: between terminals 3 and 4
Continuous load current: 80mA (DC)
Quantity, n=60; Ambient temperature: 25°C 77°F
Load voltage: 10V (DC)
Continuous load current: 80mA (DC)
Quantity, n = 60; Ambient temperature: 25°C 77°F
Load voltage: 10V (DC)
Continuous load current: 80mA (DC)
Quantity, n = 60; Ambient temperature: 25°C 77°F
50
35
60
30
50
Quantity, n
Quantity, n
20
15
Quantity, n
40
25
30
40
30
20
20
10
10
10
5
0
8.6
9
9.4
9.8
0
10.2
0
0.02
0.04
0.06
0.08
Turn on time, ms
On resistance, Ω
0
0.1
0
0.02
0.04
0.06
0.08
0.1
Turn off time, ms
19. LED operate current distribution
Load voltage: 10V (DC)
Continuous load current: 80mA (DC)
Quantity, n = 60; Ambient temperature: 25°C 77°F
20
Quantity, n
15
10
5
0
0.4
0.6
0.8
1
1.2 1.4 1.6
LED operate current, mA
1.8
DIMENSIONS
mm inch
4.45
.175
Recommended mounting pad (TOP VIEW)
0.70
.028
2.65
.104
0.90
.035
1.27
.050
4.35
.171
Tolerance:±0.1 ±.004
1.80
.071
0.20
.008
0.20
.008
(4.85)
(.191)
0.40
.016
0.40
.016
1.27
.050
Terminal thickness = 0.15 .006
General tolerance: ±0.1 ±.004
SCHEMATIC AND WIRING DIAGRAMS
Notes: 1. E1: Power source at input side; VIN: Input voltage; IF: LED forward current; IIN: Input current; VL: Load voltage; IL: Load current
Output
configuration
Schematic
1
Wiring diagram
4
1a
2
Load
3
AC/DC
E1
1
4
2
3
IF
4
IL
VL (AC,DC)
Load
IL
VL (AC,DC)
3
Load
5
AQY221N2V
CAUTIONS FOR USE
1. Short across terminals
Do not short circuit between terminals
when relay is energized. There is
possibility of breaking the internal IC.
2. Surge voltages at the input
If reverse surge voltages are present at
the input terminals, connect a diode in
reverse parallel across the input terminals
and keep the reverse voltages below the
reverse breakdown voltage.
5. Output spike voltages
1) If an inductive load generates spike
voltages which exceed the absolute
maximum rating, the spike voltage must
be limited.
Typical circuits are shown below.
1
4
2
3
Load
6. Cleaning solvents compatibility
Dip cleaning with an organic solvent is
recommended for removal of solder flux,
dust, etc. Select a cleaning solvent from
the following table. If ultrasonic cleaning is
used, the severity of factors such as
frequency, output power and cleaning
solvent selected may cause loose wires
and other defects. Make sure these
conditions are correct before use. For
details, please consult us.
Cleaning solvent
1
4
2
3
3. Recommended LED forward current
(IF)
It is recommended that the LED forward
current (IF) be kept at 5mA.
4. Ripple in the input power supply
If ripple is present in the input power
supply, observe the following:
1) For LED operate current at Emin, maintain the value mentioned in the table of "3.
Recommended LED forward current (IF)."
2) Keep the LED operate current at 50
mA or less at Emax.
Emin.
1
4
2
3
Add a clamp diode
to the load
Load
Add a CR snubber
circuit to the load
Adueous
Alcohol
base
Others
• Trichlene
• Chloroethlene
• Indusco
• Hollis
• Lonco Terg
• IPA
• Ethanol
• Thinner
• Gasoline
❍
❍
❍
✕
2) If spike voltages generated at the load
are limited with a clamp diode and the
circuit wires are long, spike voltages will
occur by inductance.
Keep wires as short as possible to
minimize inductance.
Emax.
7. Soldering
When soldering this terminals, the following conditions are recommended.
(1) IR (Infrared reflow) soldering method
(2) Vapor phase soldering method
T3
T2
T2
(3) Double wave soldering method
T2
T1
T1
T1
t1
t2
T1 = 155 to 165°C 311 to 329°F
T2 = 180°C 200°C 356 to 392°F
T3 = 245°C 473°F or less
t1 = 120 s or less
t2 = 30 s or less
(4) Soldering iron method
Tip temperature: 280 to 300°C
536 to 572°F
Wattage: 30 to 60 W
Soldering time: within 5 s
6
Chlorine
base
Compatibility
(❍: Yes ✕: No)
t1
t2
T1 = 180 to 200°C 366 to 392°F
T2 = 215°C 419°F or less
t1 = 40 s
t2 = 40 s or less
(5) Others
Check mounting conditions before using
other soldering methods (hot-air, hot
plate, pulse heater, etc.)
• The temperature profile indicates the
temperature of the soldered terminal on
the surface of the PC board. The ambient
t1
t2
t3
T1 = 155 to 165°C 311 to 329°F
T2 = 260°C 500°F or less
t1 = 60 s or less
t2+t3 = 5 s or less
temperature may increase excessively.
Check the temperature under mounting
conditions.
• The conditions for the infrared reflow
soldering apply when preheating using
the VPS method.
AQY221N2V
8. The following shows the packaging format
1) Tape and reel
Type
Tape dimensions
0.3±0.05
.012±.002
SSOP
4-pin type
mm inch
Dimensions of paper tape reel
Tractor feed holes
1.50 +0.5
-0 dia.
Direction of picking
1.50 +0.5
-0 dia.
3.0±0.1
4.0±0.1 1.75±0.1
.118±.004
.157±.004 .069±.004
5.1±0.2
.201±.008
21±0.8
.827±.031 80±1 dia.
3.150±.039 dia.
2±0.5
.079±.020
250±2 dia.
9.843±.079 dia.
80±1 dia.
3.150±.039 dia.
12.0±0.3
.472±.012
Device mounted
on tape
2.7±0.3
.106±.012
4.0±0.1
.157±.004
1.50-0+0.1 dia. 5.5±0.1
.059-0+.004 dia. .217±.004
13±0.5 dia.
.512±.020 dia. 14±1.5
.551±.059
(1) When picked from 1/4-pin side: Part No. AQY❍❍❍VY (Shown above)
(2) When picked from 2/3-pin side: Part No. AQY❍❍❍VW
2) Storage
PhotoMOS relays implemented in SSOP
types are sensitive to moisture and come
in sealed moisture-proof packages.
Observe the following cautions on
storage.
• After the moisture-proof package is
unsealed, take the devices out of storage
as soon as possible (within 1 month at the
most).
• If the devices are to be left in storage for
a considerable period after the moistureproof package has been unsealed, it is
recommended to keep them in another
moisture-proof bag containing silica gel
(within 3 months at the most).
9. Transportation and storage
1) Extreme vibration during transport will
warp the lead or damage the relay.
Handle the outer and inner boxes with
care.
2) Storage under extreme conditions will
cause soldering degradation, external
appearance defects, and deterioration of
the characteristics. The following storage
conditions are recommended:
• Temperature: 0 to 45°C 32 to 113°F
• Humidity: Less than 70% R.H.
• Atomosphere: No harmful gasses such
as sulfurous acid gas, minimal dust.
10. Applying stress that exceeds the
absolute maximum rating
If the voltage or current value for any of
the terminals exceeds the absolute
maximum rating, internal elements will
deteriorate because of the excessive
voltage or current. In extreme cases,
wiring may melt, or silicon P/N junctions
may be destroyed.
As a result, the design should ensure that
the absolute maximum ratings will never
be exceeded, even momentarily.
(Use at 15 V DC or lower and 9 V DC or
lower is recommended.)
8/1/2001
2±0.5
.079±.020
11. Deterioration and destruction
caused by discharge of static
electricity
This phenomenon is generally called
static electricity destruction. This occurs
when static electricity generated by
various factors is discharged while the
relay terminals are in contact. The result
can producing internal destruction of the
element.
To prevent problems from static electricity,
the following precautions and measures
should be taken when using your device.
1) Employees handling relays should
wear anti-static clothing and should be
grounded through protective resistance of
500 kΩ to 1 MΩ.
2) A conductive metal sheet should be
placed over the work table. Measuring
instruments and jigs should be grounded.
3) When using soldering irons, either use
irons with low leakage current, or ground
the tip of the soldering iron. (Use of lowvoltage soldering irons is also
recommended.)
4) Devices and equipment used in
assembly should also be grounded.
5) When packing printed circuit boards
and equipment, avoid using high-polymer
materials such as foam styrene, plastic,
and other materials which carry an
electrostatic charge.
6) When storing or transporting relays, the
environment should not be conducive to
generating static electricity (for instance,
the humidity should be between 45 and
60%). Relays should always be protected
using non-conductive packing materials.
All Rights Reserved, © Copyright Matsushita Electric Works, Ltd.
7
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