AQY2C1R2PX

Super miniature TSON package, Capacitor Coupled isolation type 1. Super miniature TSON package contributes to space savings and high density mounting. 3.5 mm2 mounting area achieved. Approx. 46 % less than previous product (SON type). 0.8 .031 1.95 .077 1.80 .071 mm inch Control circuit Rectifier circuit 4 Oscillation circuit 2 (AQY2) FEATURES New 1 CC TSON C×R New 100% 44% 22% 16% 12% SON VSSOP TSON 3 SOP 4pin SSOP 2. Low current consumption (input current: Max. 0.2 mA) 3. Guaranteed performance at high temperature (Max. 105°C 221°F) 4. Voltage driving type (3 V to 5 V) 5. Input current of CC type is less than half of previous products, contributing energy saving of device and increases drivability Comparison with previous products RoHS compliant Input current Typical Maximum CC type (AQY2C1R2P VIN = 5 V) 0.09 mA 0.2 mA HS type (AQY232S) 0.35 mA 0.5 mA GU type (AQY212S) 0.9 mA 3 mA TYPICAL APPLICATIONS 1. Measuring equipment: IC tester, probe cards, board tester and other testing equipment 2. Telecommunication equipment 3. Security, voltage operating equipment application for requiring low electricity consumption. Security equipment: Security camera, intruder detection Disaster-preventing equipment: Fire alarm, smoke, heat and fire detectors Industrial equipment: Electric measuring equipment, Industrial measuring equipment Electric meter, Gas meter and other meters. *Does not support automotive application. –1– ASCTB359E 201505-T CC TSON C×R (AQY2) OPERATING PRINCIPLE Output side OUT Driver IC OUT IN (+) Input side Power MOSFET IN (−)  When operated  When turned off When signal voltage is applied to the input terminal, the oscillation circuit in the driver IC operates. When the signal voltage at the input terminal is cut off, the oscillation circuit in the driver IC stops. The oscillating input signal is converted to DC voltage by the rectifier circuit after passing through the isolation capacitor in the driver IC. When oscillation of the input signal stops, the driver IC voltage decreases. The DC voltage that was converted then passes through the control circuit in the driver IC and charges the MOSFET gate on the output side. When the voltage supplied from the driver IC decrease, the control circuit rapidly discharges the gate charge of MOSFET. When the gate voltage of MOSFET supplied from the driver IC reaches a preset voltage value, the MOSFET begins to conduct and turns on the load. This operation makes MOSFET stop conducting and turns off the load. –2– ASCTB359E 201505-T CC TSON C×R (AQY2) TYPES Output rating*1 Load voltage Load current 30 V 0.75 A 40 V 0.3 A Type AC/DC dual use Part No. (Tape and reel packing style)*2 Picked from the 1 and 2-pin side Picked from the 3 and 4-pin side AQY2C1R6PX AQY2C1R6PZ AQY2C1R2PX AQY2C1R2PZ Packing quantity in the tape and reel 3,500 pcs. Notes: *1. Indicate the peak AC and DC values. *2. Only tape and reel package is available. For space reasons, only “1R6” or “1R2” is marked on the product as the part number. RATING 1. Absolute maximum ratings (Ambient temperature: 25°C 77°F) Item Input voltage Input side Input reverse voltage Power dissipation Load voltage (peak AC) Continuous load current Output side Peak load current Power dissipation Total power dissipation I/O isolation voltage Operating temperature Storage temperature Symbol VIN VRIN Pin VL IL Ipeak Pout PT Viso Topr Tstg AQY2C1R6P AQY2C1R2P Remarks 5.5 V 0.2 V 1.2 mW 30 V 0.75 A 1.5 A 40 V 0.3 A 0.75 A 250 mW 250 mW 200 V AC –40°C to +105°C –40°F to +221°F –40°C to +125°C –40°F to +257°F Peak AC, DC 100 ms (1shot), VL = DC Non-condensing at low temperatures 2. Electrical characteristics (Ambient temperature: 25°C 77°F) Item Symbol Typ. AQY2C1R6P AQY2C1R2P 1.7 V 1.8 V VFon Operate voltage Max. 2.5 V Min. 0.5 V VFoff Turn off voltage Typ. Input Input current On resistance Output Output capacitance Off state leakage current Turn on time* Transfer characteristics Turn off time* I/O capacitance Typ. Max. Typ. Max. Typ. Max. Typ. Max. Typ. Max. Max. Typ. Max. Typ. Max. Typ. Max. Typ. Max. Typ. Max. 1.5 V IIN Ron Cout 1.4 V 0.04 mA 0.1 mA 0.09 mA 0.2 mA 0.22 Ω — 0.2 Ω 0.4 Ω 40 pF 100 pF ILeak Ton VIN = 3.3 V VIN = 5 V 0.9 Ω — 0.8 Ω 1.5 Ω 14.5 pF 18 pF 10 nA 0.25 ms 1 ms 0.06 ms 0.5 ms 0.06 ms Toff 0.04 ms 0.2 ms 0.1 ms 0.06 ms 0.5 ms 1.2 pF 3 pF Ciso VIN = 3.3 V, IL = Max. VIN = 5 V, IL = Max. VIN = 0 V, f = 1 MHz, VB = 0 V VIN = 0 V, VL = Max. 0.15 ms 0.12 ms Test condition VIN / t 100 mV/ms AQY2C1R6P: IL = 100 mA AQY2C1R2P: IL = Max. VIN / t 100 mV/ms AQY2C1R6P: IL = 100 mA AQY2C1R2P: IL = Max. VIN = 3.3 V, VL = 10 V, RL = 100 Ω VIN = 5 V, VL = 10 V, RL = 100 Ω VIN = 3.3 V, VL = 10 V, RL = 100 Ω VIN = 5 V, VL = 10 V, RL = 100 Ω f = 1 MHz, VB = 0 V *Turn on/Turn off time Input 90% 10% Output Ton Toff –3– ASCTB359E 201505-T CC TSON C×R (AQY2) RECOMMENDED OPERATING CONDITIONS Please obey the following conditions to ensure proper device operation and resetting. Item Input voltage Symbol VIN Minimum 3 Typical — Maximum 5 Unit V REFERENCE DATA 1. Load current vs. ambient temperature characteristics 2. On resistance vs. ambient temperature characteristics 3. Turn on time vs. ambient temperature characteristics Allowable ambient temperature: –40°C to +105°C –40°F to +221°F Measured portion: between terminals 3 and 4, Input voltage: 5V Load voltage: 10V (DC) Continuous load current: 750mA (DC) AQY2C1R6P 300mA (DC) AQY2C1R2P Measured portion: between terminals 3 and 4, Input voltage: 5V Load voltage: 10V (DC) Continuous load current: 100mA AQY2C1R6P On resistance, Ω Load current, mA 800 600 400 2.5 0.5 2 0.4 1.5 AQY2C1R2P 1 Turn on time, ms 1000 0.3 0.2 AQY2C1R2P 0.5 200 AQY2C1R6P 0.1 AQY2C1R6P AQY2C1R2P 0 -40 -20 0 105 0 20 40 60 80 100 120 Ambient temperature, °C -40 -20 0 105 0 20 40 60 80 100 Ambient temperature, °C 105 0 20 40 60 80 100 Ambient temperature, °C -40 -20 5. Operate voltage vs. ambient temperature characteristics 6. Turn off voltage vs. ambient temperature characteristics Measured portion: between terminals 3 and 4, Input voltage: 5V Load voltage: 10V (DC) Continuous load current: 100mA Measured portion: between terminals 3 and 4 Load voltage: 10V (DC) Continuous load current: 100mA (DC) AQY2C1R6P 300mA (DC) AQY2C1R2P Measured portion: between terminals 3 and 4 Load voltage: 10V (DC) Continuous load current: 100mA (DC) AQY2C1R6P 300mA (DC) AQY2C1R2P 5 5 0.4 4 4 0.3 0.2 3 AQY2C1R2P 2 Turn off voltage, V 0.5 Operate voltage, V Turn off time, ms 4. Turn off time vs. ambient temperature characteristics 3 2 AQY2C1R6P AQY2C1R6P AQY2C1R6P 0.1 1 1 AQY2C1R2P AQY2C1R2P 0 -40 -20 105 0 20 40 60 80 100 Ambient temperature, °C 0 -40 -20 7.Input current vs. ambient temperature characteristics 8. Current vs. voltage characteristics of output at MOS portion Input voltage: 3.3V, 5V Measured portion: between terminals 3 and 4 Input voltage: 5V Ambient temperature: 25°C 77°F 0.25 9. Input current vs. input voltage characteristics Ambient temperature: 25°C 77°F (Recommended input voltage: 3 to 5 V) 0.25 0.15 0.8 AQY2C1R6P 0.6 0.4 0.2 AQY2C1R2P -0.5 -0.4 -0.3 -0.2 -0.1 0.1 0.2 0.3 0.4 0.5 5V 0.1 -0.2 Voltage, V Input current, mA 0.2 105 0 20 40 60 80 100 Ambient temperature, °C -40 -20 1 Current, A Input current, mA 0 105 0 20 40 60 80 100 Ambient temperature, °C 0.2 0.15 0.1 -0.4 3.3V 0.05 -0.6 0.05 -0.8 0 -40 -20 105 0 20 40 60 80 100 Ambient temperature, °C -1 0 2 3 4 5 6 Input voltage, V –4– ASCTB359E 201505-T CC TSON C×R (AQY2) 11. Turn on time vs. input voltage characteristics 12. Turn off time vs. input voltage characteristics Measured portion: between terminals 3 and 4 Ambient temperature: 25°C 77°F Measured portion: between terminals 3 and 4, Load voltage: 10V (DC) Continuous load current: 100mA (DC) Ambient temperature: 25°C 77°F Measured portion: between terminals 3 and 4, Load voltage: 10V (DC) Continuous load current: 100mA (DC) Ambient temperature: 25°C 77°F 1 0.5 0.8 0.4 10-6 10-9 Turn off time, ms 10-3 Turn on time, ms Off state leakage current, A 10. Off state leakage current vs. load voltage characteristics 0.6 0.4 AQY2C1R6P AQY2C1R6P 0.3 0.2 AQY2C1R6P 10 0.2 AQY2C1R2P -12 0.1 AQY2C1R2P 0 10 20 30 40 Load voltage, V 0 2 50 3 AQY2C1R2P 4 5 Input voltage, V 0 2 6 3 4 5 Input voltage, V 6 14. Isolation vs. frequency characteristic (50Ω impedance) 15. Insertion loss vs. frequency characteristic (50Ω impedance) Measured portion: between terminals 3 and 4 Frequency: 1MHz (30mVrms), 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, Input voltage: 5V Ambient temperature: 25°C 77°F 100 0.5 40 80 0.4 30 Insertion loss, dB 50 Isolation, dB Output capacitance, pF 13. Output capacitance vs. applied voltage characteristics 60 40 20 0.3 0.2 AQY2C1R6P 10 AQY2C1R2P 20 AQY2C1R2P 0.1 AQY2C1R2P AQY2C1R6P AQY2C1R6P 0 10 20 30 40 0 5 10 50 106 Applied voltage, V 107 Frequency, Hz 0 4 10 108 105 106 Frequency, Hz 16.-(2) On resistance distribution 17.-(1) Turn on time distribution Sample: AQY2C1R6P, Measured portion: between terminals 3 and 4 Input voltage: 5V, Continuous load current: 750mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F Sample: AQY2C1R2P, Measured portion: between terminals 3 and 4 Input voltage: 5V, Continuous load current: 300mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F Sample: AQY2C1R6P, Input voltage: 5V Load voltage: 10V (DC), Continuous load current: 100mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F 50 50 40 40 40 30 Quantity, n 50 Quantity, n Quantity, n 16.-(1) On resistance distribution 30 30 20 20 20 10 10 10 0 0.14 0.16 0.18 0.20 0.22 On resistance, Ω 0.24 0 0.64 0.68 0.72 0.76 0.80 On resistance, Ω –5– 0.84 107 0 0 0.04 0.08 0.12 0.16 Turn on time, ms 0.2 ASCTB359E 201505-T CC TSON C×R (AQY2) 18.-(1) Turn off time distribution 18.-(2) Turn off time distribution Sample: AQY2C1R2P, Input voltage: 5V Load voltage: 10V (DC), Continuous load current: 100mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F Sample: AQY2C1R6P, Input voltage: 5V Load voltage: 10V (DC), Continuous load current: 100mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F Sample: AQY2C1R2P, Input voltage: 5V Load voltage: 10V (DC), Continuous load current: 100mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F 50 50 40 40 40 30 Quantity, n 50 Quantity, n Quantity, n 17.-(2) Turn on time distribution 30 20 20 20 10 10 10 0 0.03 0.04 0.05 0.06 0.07 Turn on time, ms 0 0 0.08 0.04 0.08 0.12 0.16 Turn off time, ms 0.2 19.-(1) Operate voltage distribution 19.-(2) Operate voltage distribution Sample: AQY2C1R6P, Load voltage: 10V (DC) Continuous load current: 100mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F Sample: AQY2C1R2P, Load voltage: 10V (DC) Continuous load current: 300mA (DC) n: 50 pcs., Ambient temperature: 25°C 77°F 50 50 40 40 Quantity, n Quantity, n 30 30 20 10 10 1.6 1.8 2 2.2 Operate voltage, V 2.4 0.04 0.05 0.06 0.07 Turn off time, ms 0.08 30 20 0 1.4 0 0.03 0 1.4 1.6 1.8 2 2.2 Operate voltage, V –6– 2.4 ASCTB359E 201505-T CC TSON C×R (AQY2) DIMENSIONS (mm inch) The CAD data of the products with a CAD Data mark can be downloaded from: http://industrial.panasonic.com/ac/e/ External dimensions CAD Data Recommended mounting pad (Top view) 1.95 .077 1.025 .040 0.60 .024 0.513 .020 0.95 .037 1.80 .071 0.575 .023 Lot No. 1 Input: DC+ 2 Input: DC− 3 Output: AC/DC 4 Output: AC/DC 0.80 .031 0.60 .024 0.40 .016 0.75 .030 1.50 .059 10 0. C 0.30 .012 0 .0 4 0.40 .016 Tolerance: ±0.1 ±.004 1.50 .059 1 0.75 .030 0.75 .030 2 4 0.65 .026 0.475 .019 3 0.775 .031 1.025 .040 General tolerance: ±0.2 ±.008 SCHEMATIC AND WIRING DIAGRAMS VIN: Input voltage, IIN: Input current, VL: Load voltage, IL: Load current Output configuration Schematic Control circuit Rectifier circuit 2 Connection Wiring diagram 4 Oscillation circuit 1 Load type 1a AC/DC — VIN 1 4 2 3 IIN 4 IL VL (AC,DC) Load IL VL (AC,DC) 3 3 Load –7– ASCTB359E 201505-T CC TSON C×R (AQY2) CAUTIONS FOR USE SAFETY WARNINGS • Do not use the product under conditions that exceed the range of its specifications. It may cause overheating, smoke, or fire. 1. Derating design Derating is essential in any reliable design and is a significant factor for product life. Even if the conditions of use (temperature, current, voltage, etc.) of the product fall within the absolute maximum ratings, reliability can be reduced remarkably when continually used under high load (high temperature, high humidity, high current, high voltage, etc.). Therefore, please derate sufficiently below the absolute maximum rating and verify operation of the actual design before use. Also, if there is the possibility that the inferior quality of this product could possibility cause great adverse affect on human life or physical property we recommend that, from the perspective of a manufacturer’s liability, sufficient amount of derating to be added to the maximum rating value and implement safety measures such as fail-safe circuit. 2. Input voltage For rising and dropping ratio of input voltage(dv/dt), maintain min. 100mV/ms. 3. 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 overvoltage or overcurrent. In extreme cases, wiring may melt, or silicon P/N junctions may be destroyed. Therefore, the circuit should be designed in such a way that the load never exceed the absolute maximum ratings, even momentarily. 4. Oscillation circuit and control circuit The oscillation circuit and control circuit of product may be destroyed by external noise, surge, static electricity and so on. For noise effect to peripheral circuits when oscillation circuit operates, please implement safety measures on the system before use by verifying operation under the actual design. • Do not touch the recharging unit while the power is on. There is a danger of electrical shock. Be sure to turn off the power when performing mounting, maintenance, or repair operations on the device (including connecting parts such as the terminal board and socket). • Check the connection diagrams in the catalog and be sure to connect the terminals correctly. Erroneous connections could lead to unexpected operating errors, overheating, or fire. 5. Deterioration and destruction caused by discharge of static electricity This phenomenon is generally called static electricity destruction, and occurs when static electricity generated by various factors is discharged while the PhotoMOS® terminals are in contact, 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 PhotOMOS® should wear anti-static clothing and should be grounded through protective resistance of 500kΩ to 1MΩ. 7. 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 of AC/DC dual use type are shown below. It is the same with DC only type. (2) A conductive metal sheet should be placed over the worktable. 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 low-voltage 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 PhotoMOS®, the environment should not be conducive to generating static electricity (for instance, the humidity should be between 45% and 60%), and PhotoMOS® should be protected using conductive packing materials. 6. Short across terminals Do not short circuit between terminals when device is energized, since there is possibility of breaking of the internal IC. 1 4 2 3 Add a clamp diode to the load 1 4 2 3 Add a CR snubber circuit to the load 2) Even if spike voltages generated at the load are limited with a clamp diode if the circuit wires are long, spike voltages will occur by inductance. Keep wires as short as possible to minimize inductance. 8. Reverse voltages at the input If reverse voltages are present at the input terminals, for example, connect a schottky barrier diode in reverse parallel across the input terminals and keep the reverse voltages below the reverse breakdown voltage. Typical circuit is shown below. 1 4 2 3 9. Ripple in the input power supply If ripple is present in the input power supply, observe the following: 1) Please maintain the input voltage at least 3V for Emin. 2) Please make sure the input voltage for Emax. is no higher than 5.5V. 3) Please keep amplitude voltage of ripple within ±0.5V. within ±0.5V Set voltage Emax. Emin. within ±0.5V –8– ASCTB359E 201505-T CC TSON C×R (AQY2) 9. Soldering • When soldering surface-mount terminals, TSON package, the following conditions are recommended. (1) IR (Infrared reflow) soldering method T3 T2 T1 t1 t2 T1 = 150 to 180°C 302 to 356°F T2 = 230°C 446°F T3 = 245°C 473°F or less t1 = 60 to 120 s or less t2 = 30 s or less (2) Soldering iron method Tip temperature: 350 to 400°C 662 to 752°F Wattage: 30 to 60 W Soldering time: within 3 s (3) Others Check mounting conditions before using other soldering methods (DWS, VPS, hotair, hot plate, laser, pulse heater, etc.) • When using lead-free solder, we recommend a type with an alloy composition of Sn 3.0 Ag 0.5 Cu. Please inquire about soldering conditions and other details. • The temperature profile indicates the temperature of the soldered terminal on the surface of the PC board. The ambient temperature may increase excessively. Check the temperature under mounting conditions. 10. Notes for mounting 1) If many different packages are combined on a single substrate, then lead temperature rise is highly dependent on package size. For this reason, please make sure that the temperature of the terminal solder area of the PhotoMOS® falls within the temperature conditions of item “9. Soldering” before mounting. 2) If the mounting conditions exceed the recommended solder conditions in item “9. Soldering”, resin strength will fall and the nonconformity of the heat expansion coefficient of each constituent material will increase markedly, possibly causing cracks in the package, severed bonding wires, and the like. For this reason, please inquire with us about whether this use is possible. 11. Cleaning solvents compatibility We recommend cleaning with an organic solvent. If you cannot avoid using ultrasonic cleansing, please ensure that the following conditions are met, and check beforehand for defects. • Frequency: 27 to 29 kHz • Ultrasonic output: No greater than 0.25W/cm2 • Cleaning time: No longer than 30 s • Cleanser used: Asahiklin AK-225 • Other: Submerge in solvent in order to prevent the PCB and elements from being contacted directly by the ultrasonic vibrations. 12. Transportation and storage 1) Extreme vibration during transport will damage the PhotoMOS®. 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. • Atmosphere: No harmful gasses such as sulfurous acid gas, minimal dust. 3) This PhotoMOS® implemented in TSON is sensitive to moisture and come in sealed moisture-proof package. 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 45°C 113°F/70%R.H.). • 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). Note: Applies to unit area ultrasonic output for ultrasonic baths. –9– ASCTB359E 201505-T CC TSON C×R (AQY2) 13. Packaging format 1) Tape and reel (Unit: mm inch) Tape dimensions 0.2±0.05 .008±.002 Tractor feed holes 1.5+0.5 −0 dia. .059+.020 dia. −0 2.2±0.2 .087±.008 2.4±0.2 .094±.008 Device mounted on tape 1.2±0.3 .047±.012 Dimensions of tape reel 21±0.8 .827±.031 Direction of picking 4±0.1 .157±.004 1.75±0.1 .069±.004 2±0.5 .079±.020 180±3 dia. 7.087±.118 dia. 60 dia. 2.362±.118 dia. 12±0.3 .472±.012 1.05±0.1 dia. .041±.004 dia. 4±0.1 .157±.004 ±3 2±0.1 .079±.004 ±0.1 5.5 .217±.004 13±0.5 dia. .512±.020 dia. (1) When picked from 1/2-pin side: Part No. AQY2C1R❍PX (Shown above) (2) When picked from 3/4-pin side: Part No. AQY2C1R❍PZ –10– 13±1.5 .512±.059 1.2±0.5 .047±.020 ASCTB359E 201505-T