REC15-1215SRW中文资料

1215ms材料标准
1215MS材料标准是一种易切削钢的标准，其化学成分和力学性能都有一定的要求。

这种材料具有良好的切削性能，适合用于自动车床加工、五金冲压件加工等领域。

同时，它也是一种环保材料，不含铅等有害物质。

具体来说，1215MS材料的化学成分应符合以下要求：
1.碳含量范围：0.09%-0.16%
2.硅含量范围：0.10%-0.40%
3.锰含量范围：0.75%-1.00%
4.磷含量不超过0.04%
5.硫含量范围：0.26%-0.35%
此外，1215MS材料的力学性能也应符合一定的要求，包括抗拉强度、屈服强度、伸长率、断面收缩率、硬度和硬度分布等。

这些性能指标可以反映材料在不同条件下的力学行为，对于材料的加工和使用都有重要的指导意义。

1. General descriptionThe ADC1215S is a single channel 12-bit Analog-to-Digital Converter (ADC) optimized forhigh dynamic performance and low power consumption at sample rates up to 125Msps. Pipelined architecture and output error correction ensure the ADC1215S is accurateenough to guarantee zero missing codes over the entire operating range. Supplied from a single 3 V source, it can handle output logic levels from 1.8V to 3.3V in CMOS mode because of a separate digital output supply.The ADC1215S supports the Low Voltage Differential Signalling (LVDS) Double Data Rate (DDR) output standard. An integrated Serial Peripheral Interface (SPI) allows the user to easily configure the ADC.The device also includes a SPI programmable full-scale to allow flexible input voltage range from 1V to 2V (peak-to-peak). With excellent dynamic performance from the baseband to input frequencies of 170MHz or more, the ADC1215S is ideal for use in communications, imaging and medical applications - especially in high Intermediate Frequency (IF) applications because of the integrated input buffer. The input buffer ensures that the input impedance remains constant and low and the performance consistent over a wide frequency range.2. Features and benefitsADC1215S seriesSingle 12-bit ADC; 65 Msps, 80 Msps, 105 Msps or 125 Msps with input buffer; CMOS or LVDS DDR digital outputsRev. 2 — 13 January 2011Product data sheetSNR, 70 dBFS / SFDR, 86 dBc Input bandwidth, 600MHzSample rate up to 125 MspsPower dissipation, 635mW at 80Msps,including analog input buffer 12-bit pipelined ADC coreSPIClock input divided by 2 for less jittercontributionDuty cycle stabilizerIntegrated input bufferFast OuT-of-Range (OTR) detection Flexible input voltage range: 1V (p-p) to2V (p-p)Offset binary, two’s complement, graycodeCMOS or LVDS DDR digital outputs Power-down and Sleep modes Pin compatible with the ADC1415Sseries, the ADC1015S series and the ADC1115S125HVQFN40 package3. Applications4. Ordering informationWireless and wired broadbandcommunicationsSpectral analysis Portable instrumentation Ultrasound equipment Imaging systemsSoftware defined radioDigital predistortion loop, poweramplifier linearizationTable 1.Ordering informationType numberf s (Msps)PackageNameDescriptionVersion ADC1215S125HN/C1125HVQFN40plastic thermal enhanced very thin quad flat package; noleads; 40 terminals; body 6×6×0.85mm SOT618-6ADC1215S105HN/C1105HVQFN40plastic thermal enhanced very thin quad flat package; noleads; 40 terminals; body 6×6×0.85mm SOT618-6ADC1215S080HN/C180HVQFN40plastic thermal enhanced very thin quad flat package; noleads; 40 terminals; body 6×6×0.85mm SOT618-6ADC1215S065HN/C165HVQFN40plastic thermal enhanced very thin quad flat package; noleads; 40 terminals; body 6×6×0.85mmSOT618-65. Block diagram6. Pinning information6.1Pinning6.2Pin descriptionTable 2.Pin description (CMOS digital outputs)Symbol Pin Type[1]DescriptionREFB1O bottom referenceREFT2O top referenceAGND3G analog groundVCM4O common-mode output voltageVDDA5V5P 5 V analog power supplyAGND6G analog groundINM7I complementary analog inputINP8I analog inputAGND9G analog groundVDDA3V10P 3 V analog power supplyVDDA3V11P 3 V analog power supplyCLKP12I clock inputCLKM13I complementary clock inputDEC14O regulator decoupling nodeOE15I output enable, active LOWPWD16I power down, active HIGHTable 2.Pin description (CMOS digital outputs) …continuedSymbol Pin Type[1]DescriptionD1117O data output bit 11 (Most Significant Bit (MSB))D1018O data output bit 10D919O data output bit 9D820O data output bit 8D721O data output bit 7D622O data output bit 6D523O data output bit 5D424O data output bit 4D325O data output bit 3D226O data output bit 2D127O data output bit 1D028O data output bit 0 (Least Significant Bit (LSB))n.c.29-not connectedn.c.30-not connectedDAV31O data valid output clockn.c.32-not connectedVDDO33P output power supplyOGND34G output groundOTR35O out of rangeSCLK/DFS36I SPI clock / data format selectSDIO/ODS37I/O SPI data IO / output data standardCS38I SPI chip selectSENSE39I reference programming pinVREF40I/O voltage reference input/output[1]P: power supply; G: ground; I: input; O: output; I/O: input/output.Table 3.Pin description (LVDS/DDR) digital outputs)Symbol Pin[1]Type[2]DescriptionD10_D11_M17O differential output data D10 and D11 multiplexed, complement D10_D11_P18O differential output data D10 and D11 multiplexed, trueD8_D9_M19O differential output data D8 and D9 multiplexed, complement D8_D9_P20O differential output data D8 and D9 multiplexed, trueD6_D7_M21O differential output data D6 and D7 multiplexed, complement D6_D7_P22O differential output data D6 and D7 multiplexed, trueD4_D5_M23O differential output data D4 and D5 multiplexed, complement D4_D5_P24O differential output data D4 and D5 multiplexed, trueD2_D3_M25O differential output data D2 and D3 multiplexed, complement D2_D3_P26O differential output data D2 and D3 multiplexed, trueD0_D1_M27O differential output data D0 and D1 multiplexed, complement D0_D1_P28O differential output data D0 and D1 multiplexed, truen.c.29-not connected[1]Pins 1 to 16 and pins 33 to 40 are the same for both CMOS and LVDS DDR outputs (see Table 2)[2]P: power supply; G: ground; I: input; O: output; I/O: input/output.7. Limiting values8. Thermal characteristics[1]Value for 6 layers board in still air with a minimum of 25 thermal vias.n.c.30-not connectedDAVM 31O data valid output clock, complement DAVP32Odata valid output clock, trueTable 3.Pin description …continued (LVDS/DDR) digital outputs)Symbol Pin [1]Type [2]Description Table 4.Limiting valuesIn accordance with the Absolute Maximum Rating System (IEC 60134).Symbol Parameter ConditionsMin Max Unit V Ooutput voltagepins D11 to D0 orpins D10_D11_P to D0_D1_P and D10_D11_M to D0_D1_M −0.4+3.9VV DDA(3V)analog supply voltage3V on pin VDDA3V −0.5+4.6V V DDA(5V)analog supply voltage5V on pin VDDA5V−0.5+6.0V V DDO output supply voltage −0.5+4.6V T stg storage temperature −55+125°C T amb ambient temperature −40+85°C T jjunction temperature-125°CTable 5.Thermal characteristics Symbol ParameterConditionsTyp Unit R th(j-a)thermal resistance from junction to ambient [1]30.5K/W R th(j-c)thermal resistance from junction to case[1]13.3K/W9. Static characteristicsTable 6.Static characteristics[1]Symbol Parameter Conditions Min Typ Max Unit SuppliesV DDA(5V)analog supply voltage 5 V 4.75 5.0 5.25VV DDA(3V)analog supply voltage 3 V 2.85 3.0 3.4VV DDO output supply voltage CMOS mode 1.65 1.8 3.6VLVDS DDR mode 2.85 3.0 3.6VI DDA(5V)analog supply current 5 V f clk=125Msps;-46-mAf i=70MHz-205-mA I DDA(3V)analog supply current 3 V f clk=125Msps;f i=70MHzI DDO output supply current CMOS mode;-12-mAf clk=125Msps;f i=70MHz-39-mALVDS DDR mode:f clk=125Msps;f i=70MHzP power dissipation ADC1215S125;-840-mWanalog supply only-770-mWADC1215S105;analog supply onlyADC1215S080;-635-mWanalog supply only-580-mWADC1215S065;analog supply onlyPower-down mode-2-mWStandby mode-40-mW Clock inputs: pins CLKP and CLKMLVPECLV i(clk)dif differential clock input voltage peak-to-peak- 1.6-V SINE waveV i(clk)dif differential clock input voltage peak-±3.0-V LVCMOSV IL LOW-level input voltage--0.3V DDA(3V)VV IH HIGH-level input voltage0.7V DDA(3V)--V Logic inputs: pins PWD and OEV IL LOW-level input voltage0-0.8VV IH HIGH-level input voltage2-V DDA(3V)VI IL LOW-level input current-55-μA I IH HIGH-level input current-65-μA Serial peripheral interface: pins CS, SDIO/ODS, SCLK/DFSV IL LOW-level input voltage0-0.3V DDA(3V)VV IH HIGH-level input voltage0.7V DDA(3V)-V DDA(3V)VI IL LOW-level input current −10-+10μA I IH HIGH-level input current −50-+50μA C Iinput capacitance-4-pFDigital outputs, CMOS mode: pins D11 to D0, OTR, DAV Output levels, V DDO =3V V OL LOW-level output voltage OGND -0.2V DDO V V OH HIGH-level output voltage 0.8V DDO -V DDO V C Ooutput capacitancehigh impedance; OE =HIGH-3-pFOutput levels, V DDO =1.8V V OL LOW-level output voltage OGND -0.2V DDO V V OHHIGH-level output voltage0.8V DDO-V DDOVDigital outputs, LVDS mode: pins D10_D11_P to D0_D1_P , D10_D11_M to D0_D1_M, DAVP and DAVM Output levels, V DDO =3V only, R load =100ΩV O(offset)output offset voltage output buffer current set to 3.5mA - 1.2-V V O(dif)differential output voltage output buffer current set to 3.5mA-350-mV C O output capacitance -3-pF Analog inputs: pins INP and INMI I input current −5-+5μA R I input resistance -550-ΩC I input capacitance- 1.3-pF V I(cm)common-mode input voltage V INP =V INM0.9 1.52V B i input bandwidth -600-MHz V I(dif)differential input voltage peak-to-peak 1-2V Common mode output voltage: pin VCMV O(cm)common-mode output voltage -0.5V DDA(3V)-V I O(cm)common-mode output current -4-mA I/O reference voltage: pin VREFV VREFvoltage on pin VREFoutput -0.5 to 1-V input 0.5-1VTable 6.Static characteristics [1] …continuedSymbol ParameterConditionsMin Typ Max Unit[1]Typical values measured at V DDA(3V)=3V, V DDO =1.8V, V DDA(5V)=5V;T amb =25°C and C L =5pF; minimum and maximum values are across the full temperature range T amb =−40°C to +85°C at V DDA(3V)=3V,V DDO =1.8V, V DDA(5V)=5V,V INP −V INM =−1dBFS; internal reference mode; applied to CMOS and LVDS interface; unless otherwise specified.Accuracy INL integral non-linearity −1.25±0.25+1.25LSB DNL differential non-linearity guaranteed no missing codes −0.25±0.12+0.25LSB E offset offset error -±2-mV E G gain error-±0.5-%FS Supply PSRRpower supply rejection ratio200mV (p-p) on V DDA(3V)-−54-dBcTable 6.Static characteristics [1] …continuedSymbol ParameterConditionsMin Typ Max UnitADC1215S_SER All information provided in this document is subject to legal disclaimers.© NXP B.V. 2011. All rights reserved.Product data sheet Rev. 2 — 13 January 2011 10 of 42NXP SemiconductorsADC1215S seriesSingle 12-bit ADC; input buffer; CMOS or LVDS DDR digital output10.Dynamic characteristics10.1Dynamic characteristicsTable 7.Dynamic characteristics [1]SymbolParameter Conditions ADC1215S065ADC1215S080ADC1215S105ADC1215S125UnitMinTyp MaxMinTyp MaxMinTyp MaxMinTyp MaxAnalog signal processing α2Hsecondharmonic levelf i =3MHz -87--87--86--88-dBc f i =30MHz -86--86--86--87-dBc f i =70MHz -85--85--84--85-dBc f i =170MHz-82--82--81--83-dBc α3Hthird harmonic levelf i =3MHz -86--86--85--87-dBc f i =30MHz -85--85--85--86-dBc f i =70MHz -84--84--83--84-dBc f i =170MHz-81--81--80--82-dBc THDtotal harmonic distortionf i =3MHz -83--83--82--84-dBc f i =30MHz -82--82--82--83-dBc f i =70MHz -81--81--80--81-dBc f i =170MHz-78--78--77--79-dBc ENOBeffectivenumber of bitsf i =3MHz -11.3--11.3--11.3--11.3-bits f i =30MHz -11.3--11.3--11.3--11.2-bits f i =70MHz -11.2--11.2--11.2--11.2-bits f i =170MHz-11.1--11.1--11.1--11.1-bits SNRsignal-to-noise ratiof i =3MHz -70.0--69.9--69.8--69.6-dBFS f i =30MHz -69.5--69.5--69.5--69.4-dBFS f i =70MHz -69.2--69.2--69.1--69.0-dBFS f i =170MHz-68.8--68.8--68.7--68.6-dBFS SFDRspurious-free dynamic rangef i =3MHz -86--86--85--87-dBc f i =30MHz -85--85--85--86-dBc f i =70MHz -84--84--83--84-dBc f i =170MHz-81--81--80--82-dBch t t p ://o n e i c .c o m /分销商库存信息:NXPADC1215S065HN/C1,5ADC1215S080HN/C1:5ADC1215S065HN/C1:5 ADC1215S105HN/C1,5ADC1215S080HN/C1,5ADC1215S105HN/C1:5 ADC1215S125HN/C1,5ADC1215S125HN/C1:5。

1800 OCEAN A VE., FRNTRONKONKOMA, NY 11779TEL 800-9HV-POWER TEL 631-471-4444FAX 631-471-4696“Making High Voltage Easier!”®Isolated up to 15kVDC leakage current of <10nA AC leakage capacitance of <40pF 3 regulated floating LV power outputsIsolated digital I/O to and from floating hot deck Isolated analog I/O to and from floating hot deck UL, CUL, IEC-60950-1, and Demko RecognizedGENERAL INFORMATION:The “FL” Series of floating-hot-deck, low-voltage power supplies offers an integrated solution for systems requiring LV power & controls with high-voltage isolation. Combining a highly isolated, DC-to-DC, multi-output low-voltage power supply (LVPS) with an advanced isolated digital & analog I/O topology,the “FL” sub-system provides both power and controls to floating-hot-deck circuitry. This solution, when combined with one or more UV HVPS or other circuitry, can provide high-performance solutions for applications such as:Floating/Stacked Ion- or E-Beam Biases Floating Filament Bias Floating Pulsers & Gated Grids Floating Capacitance Meters Floating High Side Current Monitors Floating Leakage TestersPlease contact UltraVolt's customer service department for an analysis of your requirements.DESIGN METHODOLOGY:The “FL” Series utilizes a dual-ended forward converter topology with a nominal switching frequency of <100 kHz. Once input voltage stabilizes, under-voltage lockout is released. When the LVPS enable is raised above a TTL 1, the converter begins to switch. The soft-start circuit brings the converter to full power over a 1mS period, reducing surges on the source supply. A constant-frequency PWM regulation system with optically isolated feed back controls the MOSFET push-pull power stage, driving a highly isolated transformer. This isolated power ultimately provides 3 separate LV floating outputs at >80% efficiency. The power stage is protected from intermittent output-current overloads or short circuits via a primary current limit circuit. The isolated digital I/O channel(s) are optically transmitted directly to the floating hot deck with a schmitt trigger buffer providing glitch-free output on the floating hot deck. The isolated analog I/O channel(s) are converted to digital data and optically transmitted directly to the floating hot deck for conversion back to analog.COMPATIBILITY:The “FL” Series works directly with any UltraVolt “A” or “C”Series DC-to-DC HVPS from 0 to 62V through 0 to 35kV @ 0to 4 watts through 0 to 20 watts. By providing isolated power,TTL enable/disable, and voltage programming, UV HVPS can be floated or stacked on one another.ISOLATED POWER OUTPUTS:The “15FL12-12W” provides floating +12VDC @ 1 Amp, -12VDC @ 10 mA, and +5VDC @ 10 mA from a single ground side +12VDC input. The “15FL24-24W” provides floating +24VDC @ 1 Amp, -12VDC @ 10 mA, and +5VDC @ 10 mA from a single ground side +24VDC input. The main output is typically used to drive a floating HVPS, or filament switching regulator, etc. The -12VDC is for use with the +DC in providing bias to floated Op-Amps, DACs & ADCs. The +5 VDC can run floating micro-controllers or watchdog reset circuits.ISOLATED CONTROLS: DIGITAL CHANNELSThe “-I/O” option provides isolated digital I/O channel(s)from the grounded system side to the floating hot deck. The TTL bit is inverted. The output, a schmitt trigger TTL buffer,sources up to 0.8mA and sinks up to 13 mA. This bit is typically used to enable/disable a floated UV HVPS. It can also be used at up to 300kHz to drive a pulser, gate, sample-and-hold multiplexer or to communicate with a floated micro controller.The “-R/B” option provides one additional down channel.ISOLATED CONTROLS: ANALOG CHANNELSThe “-I/O” option provides isolated analog I/O channel(s)from the grounded system side to the floating hot deck. The analog signal is converted to digital and translated back to analog at the floating hot deck. The output is buffered with a source impedance of 1.5K Ω. This signal is typically used to remote program a floated UV HVPS. It can be used at up to 30 Hz to drive an amplifier, sample-and-hold, or to program other devices such as a floating filament regulator. The “-R/B”option provides one additional down channel.STANDBY MODE:All “FL” models feature an LVPS enable/disable function.When the enable is TTL 0 (< +0.7 VDC +/-0.2 Isink=1mA), the floating LVPS is in standby mode. All isolated outputs go to 0VDC; input current drops to < 90 mA; and all functions are shut down except the +5 Volt reference, which is always operational.If the LVPS enable pin is left unconnected, TTL 1 or at greater voltages up to +32VDC the converter operates normally.MECHANICAL:“FL” Series units are in PCB-mountable plastic cases requiring a footprint of 8.5 in 2and only 10 in 3of volume. Mounting plates and brackets are available for chassis mounting. See Application Note AP-6 for thermal considerations and for mounting configurations.ENVIRONMENTAL:The “FL” Series provides full power operation at case temperatures from -20 to +55o C. All units receive a 24-hour burn-in prior to final testing. Extended temperature range is available along with other enhanced capabilities. Please contact the factory.FLOATING HOT DECK LVPS WITH ISOLATED DIGITAL AND ANALOG I/O41Specifications subject to change without noticeFLOATING HOT DECK LVPS WITH ISOLATED DIGITAL AND ANALOG I/OTEL 800-9HV-POWER or 800-948-7693 or 631-471-4444 FAX 631-471-46961800 Ocean Ave., Frnt, Ronkonkoma, NY 11779“Making High Voltage Easier!”®42TEL 800-9HV-POWER or 800-948-7693 or 631-471-4444 FAX 631-471-46961800 Ocean Ave., Frnt, Ronkonkoma, NY 11779“Making High Voltage Easier!”®FLOATING HOT DECK LVPS WITH ISOLATED DIGITAL AND ANALOG I/O43Ordering Information1 - Input Power Ground Return2 - Positive Power Input3 - LVPS Enable/Disable Input4 - TTL Up/HVPS Enable/Disable (-I/O Only)5 - Signal Ground Return6 - Analog Up/ HVPS Remote Programming Input (-I/O Only)7 - +5V Reference Output1 - Floating +Iout monitor input (Analog Down Channel 1)2 - Floating -Iout monitor input (Analog Down Channel 1)3 - Floating +Eout monitor input (Analog Down Channel 2)4 - Floating -Eout monitor input (Analog Down Channel 2)Local ConnectionsTypeOption Power5 - N/C (reserved for future use)7 - Floating TTL input (Digital Down Channel 1)6 - N/C (reserved for future use)Additional Isolated Connections (-R/B only)Example:15FL12-12W-I/OIsolation Model Input8 - +Iout monitor output (Analog Down Channel 1)9 - -Iout monitor output (Analog Down Channel 1)10- +Eout monitor output (Analog Down Channel 2)11- -Eout monitor output (Analog Down Channel 2)12 - N/C (reserved for future use)13 - N/C (reserved for future use)14 - TTL output (Digital Down Channel 1)Additional Local Connections (-R/B option)8 - Floating PWR Ground Return 9 - Floating +12VDC or +24VDC Output 10 - Floating -12VDC Output11 - Floating TTL Up/HVPS Enable/Disable (-I/O Only)12 - Floating Signal Ground Return13 - Floating Analog Up/ HVPS Remote Programming Input (-I/O Only)14 - Floating +5.6V Reference OutputIsolated/Floating ConnectionsCopyright 1991-2006, UltraVolt, Inc.Rev. G 10/061800 Ocean Ave., Frnt, Ronkonkoma, NY 11779“Making High Voltage Easier!”®44IEC-60950-1All units are RoHS-5 compliant.Models with -RB option are not yet certified withUL, CUL, IEC-60950-1, or Demko.。

15 Watt Single &Dual Output●Ultraminiature 25.4 x25.4x9.9mm Package ●15 Watts Output Power ●Single or Dual Outputs●Wide 4:1 Input Voltage Range ●1.6kVDC Isolation●Fixed Operating Frequency ●Six-Sided Continuous Shield ●Industry Standard Pinout ●Remote On/Off and Trim pins ●Efficiency to 87%FeaturesSelection Guide 24V and 48V Input TypesPart NumberInput Output Output Input (1)Efficiency (2)Capacitive (3)Range Voltage Current Current Load max.VDC VDC mA mA %RP15-243.3SAW**9-36 3.3400050/688861000µF RP15-2405SAW**9-365300070/762861000µF RP15-2412SAW**9-3612130020/78387330µF RP15-2415SAW**9-3615100020/75387220µF RP15-483.3SAW**18-75 3.3400040/336861000µF RP15-4805SAW**18-755300040/382861000µF RP15-4812SAW**18-7512130015/39287330µF RP15-4815SAW**18-7515100015/37787220µF RP15-2405DAW**9-36±5±150020/77285±500µF RP15-2412DAW**9-36±12±62525/75387±150µF RP15-2415DAW**9-36±15±50025/74488±100µF RP15-4805DAW**18-75±5±150015/38685±500µF RP15-4812DAW**18-75±12±62515/38286±150µF RP15-4815DAW**18-75±15±50015/37787±100µF** Standard part is without suffixes and Trim and CTRL pins are not fitted.* add suffix /P for CTRL function with positive logic (1=ON, 0=OFF) including trim pin for single output * add suffix /N for CTRL function with negative logic (0=ON, 1=OFF) including trim pin f or single output * add suffix -HC for premounted heatsink and clips Ordering ExamplesRP15-2405SAW/P = 24V 4:1 Input, 5V Output, Positive Logic CTRL pin and Trim pin fitted.RP15-4805DAW-HC = 48V 4:1 Input, ±5V Output, Premounted Heatsink RP15-483.3DAW/N = 48V 4:1 Input, ±5V Output, Negative Logic CTRL pin(no trim pin with dual output)The RP15-SAW series are ultraminiature wide input voltage range power DC/DC converters in a case half the size of industry standard 15W converters. Despite their small size, the RP15-SAW converters are fully specified devices with output currents up to 4 Amps, no minimum load, 1600VDC isolation and low ripple/noise figures.The outputs are also fully protected against short circuits, overcurrent and overvoltage. The RP15-SAW series will find many uses in applications where board space and/or board height is at a premium.DescriptionPlease Read Application NotesUL-60950-1 Certified E196683REV:1/2010P-45 RP15-AWPOWERLINEDC/DC-Converterwith 3 year WarrantyRoHS2002/95/EC6/6/Input Voltage Range 24V nominal input 9-36VDC 48V nominal input18-75VDC Input FilterPi Type Input Surge Voltage (100 ms max.)24V Input 50VDC 48V Input 100VDC Input Reflected Ripple (nominal Vin and full load) (see Note 4)30mAp-p Start Up Time (nominal Vin and constant resistor load)30ms max.Optional Remote ON/OFF (See Note 5)DC-DC ON Short or 0V < Vr < 1.2V (Negative logic)DC-DC OFF Open or 3.0V < Vr < 12VRemote Pin drive current Nominal Vin -0.5mA~1.0mARemote OFF input currentNominal Vin 2.5mAOutput Voltage Accuracy (full Load and nominal Vin)±1%Optional Output Trim (see Note 5)±10%Minimum Load0%Line Regulation (low line, high line at full load)Single ±0.2%Dual ±0.5%Load Regulation (0% to full load)Single ±0.2%Dual ±1%Cross Regulation (Asymmetrical 25% <> 100% load)Dual Output ±5%Ripple and Noise (20MHz bandwith) 3.3, 5V Outputs 75mVp-p Others100mVp-p Temperature Coefficient±0.02%/°C max.Transient Response (25% load step change)250µs Over Voltage Protection3.3V 3.7-5.4V Zener diode clamp (only single)5V 5.4-7.0V 12V 13.5-19.6V 15V16.8-20.5V Over Load Protection (% of full load at nominal Vin)150% typUndervoltage Lockout See Application Notes Short Circuit Protection Hiccup, automatic recovery Efficiencysee …Selection Guide“ tableIsolation Voltage (rated for one minute)1600VDC Isolation Resistance 1 G Ωmin.Isolation Capacitance1000pF max.continued on next pageSpecifications (typical at nominal input and 25°C unless otherwise noted)Typical CharacteristicsDerating graphs are valid only for the shown part numbers. If you need detailed derating-information about a part-number not shown here please contact our technical support service at info@recom-development.at125755025100Ambient Temperature Range (°C)-40-10050708090100O u t p u t P o w e r (%)60Natural Convection-25125755025100Ambient Temperature Range (°C)-40-10050608090100O u t p u t P o w e r (%)66Natural Convection-2570RP15-4805SAWRP15-4805SAW With Heat SinkR P 15-A WREV: 1/2010P-46/Specifications (typical at nominal input and 25°C unless otherwise noted)Operating Frequency 400kHz typOperating Temperature Range -40°C to +85°C(with derating)Maximum Case Temperature +105°CStorage Temperature Range -55°C to +125°CThermal Impedance Natural convection18.2°C/Watt (see Note 6)Natural convection with Heat Sink15.8°C/Watt Thermal Shock MIL-STD-810FVibration 10-55Hz, 10G, 30 Min. along X, Y and ZRelative Humidity 5% to 95% RH Case Material Nickel plated copperBase Material FR4 PCB Potting MaterialEpoxy (UL94-V0)Conducted Emissions (see Note 7)EN55022Class A Radiated Emissions EN55022Class A ESDEN61000-4-2Perf. Criteria A Radiated Immunity EN61000-4-3Perf. Criteria A Fast Transient EN61000-4-4Perf. Criteria A Surge (see note 8)EN61000-4-5Perf. Criteria A Conducted Immunity EN61000-4-6Perf. Criteria AWeight 15gPacking Quantity Refer to App Notes for tube dimensions8 pcs per Tube Dimensions 25.4 x 25.4 x 9.9mmMTBF (see Note 9)Bellcore TR-NWT-0003321330 x 103hours MIL-HDBK 217F 563 x 103hours1. Values at nominal input voltage and no load/full load.2. Typical Value at nominal input voltage and full load.3.Test by minimum Vin and constant resistor load.4.Simulated source impedance of 12µH. 12µH inductor in series with +Vin.5.The ON/OFF control function can be positive or negative logic. The pin voltage is referenced to negative input.Positive logic ON/OFF is marked with suffix-P (eg. RP15-2405SAW/P)Negative logic ON/OFF is marked with suffix-N (eg. RP15-2405SAW/N).If no suffix is specified, the control pin will be omitted.6.Optional Heat-sink P/N is 7G-0047-C. Powerline DC/DC Converters can be ordered with pre-mounted heatsinks including antivibration fixing clips (add suffix -HC). See Application Notes for heatsink details.7. Meets Class A with external input capacitors shown below. Will meet Class B with external common mode filter (see Application Notes)8.Requires external capacitor to meet EN61000-4-5: 220µF/100V, low ESR (48mOhm)9.BELLCORE TR-NWT-000332. Case l: 50% Stress, Temperature at 40°C.MIL-HDBK 217F Notice 2. Ta = 25°C, full load, (Ground Benign, controlled environment).Notes :Trim UpRUTrim DownR D5654External Output Trimming (optional)With /CTRL suffix, output can be externally trimmed by using the method shown here. See Application Notes for details.REV:1/2010P-47 RP15-AW/Package Style and Pinning (mm)1.0 dia3rd angle projectionEMC Filtering - For Class B filter suggestion, see Application NotesClass A FilterVin=24V: C1=6.8µF/50V 1812 MLCC, C2 omitted.Vin=48V: C1, C2 = 2.2µF/100V 1812 MLCCTypical CharacteristicsPin Connections Pin #Single Single/Dual Dual/P or /N P or /N 1+Vin +Vin +Vin +Vin 2-Vin -Vin -Vin -Vin 3no pin CTRL no pin CTRL 4+Vout +Vout +Vout +Vout 5no pin Trim Com Com 6-Vout-Vout-Vout-VoutCase Tolerance ±0.5 mm Pin Pitch Tolerance ±0.25 mm301848Efficiency VS Input Voltage3642245460667072747678808284868890E f f i c i e n c y (%)Input Voltage (V)7225075Efficiency VS Output load 501004045505560657075808590Output Load (%)E f f i c i e n c y (%)RP15-4805SAWRP15-4805SAWR P 15-A WREV: 1/P-48/分销商库存信息:RECOM-POWERRP15-2412SAW RP15-2405SAW RP15-4812SAWRP15-483.3SAW RP15-243.3SAW RP15-4805SAWRP15-2415DAW RP15-4815DAW RP15-4812DAWRP15-2415SAW RP15-4815SAW RP15-2405SAW-HC RP15-2412SAW-HC RP15-2415SAW-HC RP15-243.3SAW-HC RP15-4805SAW-HC RP15-4812SAW-HC RP15-4815SAW-HC RP15-483.3SAW-HC RP15-2405SAW/N RP15-2405SAW/PRP15-2412SAW/N RP15-2412SAW/P RP15-2415SAW/NRP15-2415SAW/P RP15-243.3SAW/N RP15-243.3SAW/PRP15-4805SAW/N RP15-4805SAW/P RP15-4812SAW/NRP15-4812SAW/P RP15-4815SAW/N RP15-4815SAW/PRP15-483.3SAW/N RP15-483.3SAW/P RP15-2405DAWRP15-4805DAW RP15-2412DAW RP15-2405SAW/N-HC RP15-2405SAW/P-HC RP15-2412SAW/N-HC RP15-2412SAW/P-HC RP15-2415SAW/N-HC RP15-2415SAW/P-HC RP15-243.3SAW/N-HC RP15-243.3SAW/P-HC RP15-4805SAW/N-HC RP15-4805SAW/P-HC RP15-4812SAW/N-HC RP15-4812SAW/P-HC RP15-4815SAW/N-HC RP15-4815SAW/P-HC RP15-483.3SAW/N-HC RP15-483.3SAW/P-HC RP15-2405DAW-HC RP15-2412DAW-HC RP15-2415DAW-HC RP15-4805DAW-HC RP15-4812DAW-HC RP15-4815DAW-HC RP15-2405DAW/N RP15-2405DAW/P RP15-2412DAW/NRP15-2412DAW/P RP15-2415DAW/N RP15-2415DAW/PRP15-4805DAW/N RP15-4805DAW/P RP15-4812DAW/NRP15-4812DAW/P RP15-4815DAW/N RP15-4815DAW/PRP15-2405DAW/N-HC RP15-2405DAW/P-HC RP15-2412DAW/N-HC RP15-2412DAW/P-HC RP15-2415DAW/N-HC RP15-2415DAW/P-HC RP15-4805DAW/N-HC RP15-4805DAW/P-HC RP15-4812DAW/N-HC RP15-4812DAW/P-HC RP15-4815DAW/N-HC RP15-4815DAW/P-HC。

SPECIFICATIONMODELDC VOLTAGE RATED CURRENT CURRENT RANGE RATED POWEROUTPUTVOLTAGE ADJ. RANGE LINE REGULATION LOAD REGULATION SETUP, RISE TIME HOLD UP TIME (Typ.)VOLTAGE RANGE FREQUENCY RANGEEFFICIENCY (Typ.)INPUTINRUSH CURRENT (Typ.)WITHSTAND VOLTAGEISOLATION RESISTANCEWORKING HUMIDITYWORKING TEMP.STORAGE TEMP., HUMIDITYTEMP. COEFFICIENT VIBRATIONMTBFDIMENSION OTHERSNOTEPACKINGOVERLOADOVER VOLTAGEOVER TEMPERATURE Note.5AC CURRENT (Typ.)1000ms, 20ms/230VAC 1000ms, 20ms/115VAC at full load 100ms/230VAC 24ms/115VAC at full load 85 ~ 264VAC 120 ~ 370VDC 47 ~ 440Hz 76%73%78%13.8 ~ 16.2V 79%17.25 ~ 20.25V81%27.6 ~ 32.4V0.35A/115VAC 0.2A/230VACCOLD START 30A/115VAC 50A/230VACAbove 105%rated output power5.75 ~6.75V3.8 ~4.95V Protection type :Hiccup mode, recovers automatically after fault condition is removed Protection type :Shut down o/p voltage, recovers automatically after temperature goes down I/P-O/P:4KVACI/P-O/P:100M Ohms/500VDC20 ~ 90% RH non-condensing -20 ~ +70(Refer to output load derating curve)-40 ~ +85, 10 ~ 95% RH0.03%/(0 ~ 5010 ~ 500Hz, 2G 10min./1cycle, period for 60min.each along X,Y, Z axes 499.7Khrs min. MIL-HDBK-217F (25)70*48*22mm (L*W*H)0.065Kg; 120pcs/8.8Kg/0.97CUFT0.5%0.5%0.5%0.5%0.5%0.5%1.0%1.0%1.0%1.0%2.0%2.0% 1.0% 1.0% 1.0%80mVp-p 80mVp-p150mVp-p 150mVp-p 240mVp-p 5V 3.3V 12V 15V 24V 3A 3.5A 1.25A 1A 0.63A 0 ~ 3A 0 ~ 3.5A 0 ~ 1.25A 0 ~ 1A 0 ~ 0.63A 15W 11.55W 15W 15W 15.12W NFM-15-5NFM-15-12NFM-15-15NFM-15-24NFM-15-3.3SAFETY STANDARDS Features :RIPPLE & NOISE (max.)Note.2VOLTAGE TOLERANCE Note.3EMI CONDUCTION & RADIATION 1. All parameters NOT specially mentioned are measured at 230VAC input, rated load and 25of ambient temperature.2. Ripple & noise are measured at 20MHz of bandwidth by using a 12" twisted pair-wire terminated with a 0.1uf & 47uf parallel capacitor.3. Tolerance : includes set up tolerance, line regulation and load regulation.4. The power supply is considered a component which will be installed into a final equipment. The final equipment must be re-confirmed that it still meets EMC directives.5. The over temperature protection (OTP) is the built-in function of the control IC (U1). The activating level described above is based on the specification provided by the IC manufacturer.ENVIRONMENT SAFETY &EMC(Note 4)PROTECTION Tj 140typically (U1) detect on main control ICProtection type :Shut off o/p voltage, clamping by zener diode 10.8 ~ 13.2V 13.5 ~ 16.5V 21.6 ~ 26.4V 4.5 ~ 5.5V 3 ~ 3.63V Compliance to EN55011,EN55022 (CISPR22) Class B(CISPR11)HARMONIC CURRENT EMS IMMUNITY Compliance to EN61000-3-2,-3Compliance to EN61000-4-2,3,4,5,6,8,11; ENV50204, EN55024, EN60601-1-2, EN61204-3, medical level, criteria A Universal AC input / Full rangeProtections: Short circuit / Over load / Over voltage / Over temperatureUltra-miniature size, light weight Cooling by free air convection Isolation classUL60601-1/IEC60601-1/EN60601-1 medical safety approved No load power consumption<0.5W 100% full load burn-in testFixed switching frequency at 67KHz High reliability 3 years warrantyUL60950-1,UL60601-1,TUV EN60601-1, IEC60601-1 approved EN60601-1IEC60601-1fosc : 67KHzBlock DiagramMechanical SpecificationFILTERI/PEMI FILTER RECTIFIERS&RECTIFIERSCONTROLSWITCH-PWM ING POWER DETECTION CIRCUIT&FILTER+V -VAC INPUTAC/L 0.788"(20m m )1.89"(48m m )AC/N+V-VDC OUTPUT0.906"(23.01m m )0.492"(12.5m m )0.157"(4mm)0.157"(4m m )2.441"(62mm)T2A/250V2.75"(69.85mm)AMBIENT TEMPERATURE ()L O A D (%)(HORIZONTAL)-201020304050607020406080100Output Derating VS Input VoltageINPUT VOLTAGE (VAC) 60Hz8510095120115160140200180240220264L O A D (%)Ta=259010080706050400.87"(22m m )0.041"(1.05mm)0.07"(1.8mm)0.177"(4.5mm)0.138"(3.5mm)Derating Curve Unit:inch(mm)。

PA-20REV:0/2011R A C 15-APlease Read Application Notes POWERLINEAC/DC-Converterwith 3 year WarrantyRAC15-AUL-60950-1 Certified15 Watt Single/Dual & Triple Output●Compact AC-DC Power Supply ●15 Watt PCB Mount Package ●Universal Input Voltage Range ●3000VAC Isolation●Low Output Ripple and Noise ●Short Circuit Protected ●UL Certified, CE MarkedFeaturesRegulated ConvertersSelection GuidePart Input Output Output Efficiency Max.Number Range Voltage Current Capacitive (VAC)(VDC)(mA)(%)Load RAC15-05SA 90-264530007431000µF RAC15-12SA 90-264121250794500µF RAC15-15SA 90-264151000782700µF RAC15-24SA 90-2642462580900µF RAC15-05DA 90-264±5±150076±13500µF RAC15-12DA 90-264±12±65079±2700µF RAC15-15DA 90-264±15±50077±1400µF RAC15-0512TA 90-2645/±122000/±2007314000/±900µF RAC15-0515TA90-2645/±152000/±1507314000/±680µF*add suffix “-E” for extended temperature range, e.g. RAC15-05SA-E*add suffix "-ST” for screw terminal module e.g. RAC15-05DA-ST, RAC10-0512TA-E-STInput Voltage Range 90-264VAC or 120-370VDCRated Power15 Watts max.Input Frequency Range (for AC Input)47-440HzInput Current (full load)115VAC/230VAC 310mA / 170mA max. No Load Power Consumption 115VAC/230VAC 1.37W max.Inrush Current (<2ms)115VAC 10A max. (-E = 23A max.)230VAC 20A max. (-E = 46A max.)Leakage Current 0.75mA max.Output Voltage Accuracy (Full load)±2%Line Voltage Regul. (low line, high line at full load)Single, Dual ±0.5% typ.Triple ±1%/±5% typ.Load Voltage Regulation (5% to 100% full load)Single ±0.5% typ.Dual ±3% typ.Triple ±2%/±5% typ.Output Ripple and Noise (20MHz limited)Noise 0.5% Vout + 50mVp-p max.Ripple <0.2% Vout + 40mVp-p max.Operating Frequency 100kHz typ.Efficiency at Full Load see table RMS Isolation Voltage (input to output)3kVAC / 1minute Temperature Coefficient ±0.02%/°C typ.Isolation Resistance 100 M Ωmax.Short Circuit Protection Hiccup, Automatic Restart Operating Temperature Range Standard -25°C to +70°C (free air convection, with derating)Suffix -E -40°C to +70°C Storage Temperature Range -40°C to +85°C Humidity 95% RH max.Case Material Epoxy with Fibreglass (UL94V-0)Package Weight 114g Packing Quantity 3 pcs (-ST Version: 1 pc)EMC EN 55022 Class B / EN 55024MTBF (+25°C)using MIL-HDBK-217F 200 x 103hours Specifications (typical at 25°C and after warm up time unless otherwise specified )Derating Graph(Ambient T emperature)DescriptionCompact UL certified switching AC/DC power module for PCB, screw-terminal connection or DIN-rail mounting.RoHS2002/95/EC6/6E196683/RAC15-A PA-21REV:0/2011Standard Package Style and PinningXX.X ± 0.5 mm XX.XX ± 0.25 mmPin Connections Pin #Single Out Dual Out Triple Out 1FG FG FG 2VAC in (N)VAC in (N)VAC in (N)3VAC in (L)VAC in (L)VAC in (L)4No Pin No Pin -VDC Out 5-VDC Out -VDC Out Com 6No Pin Com + VDC Out 7+ VDC Out + VDC Out + 5V Rtn (Com)8No PinNo Pin+ 5V Out3rd angleprojectionRAC15-S_D_TA SeriesPOWERLINEAC/DC-ConverterScrew Terminal Module Option (suffix -ST)123FuseRemovable DIN-Rail Pin Connections Pin #Single Out Dual Out Triple Out 1FG FG FG 2VAC in (N)VAC in (N)VAC in (N)3VAC in (L)VAC in (L)VAC in (L)4NC NC -VDC Out 5-VDC Out -VDC Out Com 6NC Com + VDC Out 7+ VDC Out + VDC Out + 5V Rtn (Com)8NCNC+ 5V OutNC = No Connection3rd angle projectionStandard Application CircuitSuggested fuse rating 2A Slow Blow/分销商库存信息:RECOM-POWERRAC15-05SA RAC15-24SA RAC15-15DA RAC15-12DA RAC15-12SA RAC15-15SA RAC15-05DA RAC15-05SA-E RAC15-12SA-E RAC15-15SA-E RAC15-24SA-E RAC15-05DA-E RAC15-12DA-E RAC15-15DA-E RAC15-0512TA RAC15-0515TA RAC15-0512TA-E RAC15-0515TA-E RAC15-05SA-ST RAC15-12SA-ST RAC15-15SA-ST RAC15-24SA-ST RAC15-05DA-ST RAC15-12DA-ST RAC15-15DA-ST RAC15-05SA-E-ST。

XGN15-12箱型固定式户内交流金属封闭开关设备1.概述XGN15-12 户内SF6环网柜是我公司引进国外先进技术并按照国内农电及城网改造之要求而生产的新一代高压电器产品。

适合国内农电及城网改造，用于交流50Hz 12kV 的电力网络中，特别适用于二次变电站，开闭所等，作为电能的接收和分配之用。

本设备可用于发电厂、变电站、大型建筑、高层楼宇、机场、医院、剧院、体育场、港口、地下设备、工矿企业等。

2.产品特点z可扩展式SF6环网柜组合的随意性优于SF6充气环网单元，体积小、安全可靠；z应用SF6气体作绝缘和灭弧介质，恒定磁场旋弧方式使其灭弧能力强，开断性能好、过电压小、电气寿命长、灭弧室免维护；z柜体结构采用敷铝锌板经多重折弯成形，采用插接式拼装，坚固牢靠；z结构紧凑简单、外形美观、布局合理，加上现代传感技术和最新保护继电器，以及先进的技术性能和轻便灵活的组装方案更加适应市场的变化；z柜壳密度高，防止设备受杂物和动物侵入，防护等级IP3X；z安装方便、操作灵活、具有多重可靠的机械联锁和防止误操作功能；z可选配上电动机构、PT、CT、UPS、FTU等可用于配电自动化。

3.正常使用条件z周围空气温度：上限+40℃，下限-25℃；z相对湿度：日平均不大于95%，月平均不大于90%；z海拔高度：不超过1000m；z没有火灾、爆炸危险、严重污秽及剧烈震动的场所。

（注：超出以上使用条件时，用户应与制造厂协商。

）z地震烈度不超过８度。

4.符合标准z GB 3906 《3～35kV交流金属封闭开关设备 》z GB/T 11022 《高压开关设备和控制设备的共同技术要求》z DL/T 404 《户内交流高压开关柜订货技术条件 》z IEC 60298 《额定电压1kV以上52kV及以下交流金属封闭开关设备和控制设备》 z IEC420 《交流高压负荷开关-熔断器组合电器》5.型号含义X G N 15 - 12额定电压(kV)设计序号 户内装置 固定式箱型开关设备6.技术参数表一.开关柜技术参数序号名称单位数据1额定电压 kV12 2额定频率 Hz 50/601min 工频耐受电压42（隔离断口：48） 3额定绝缘水平雷电冲击耐受电压kV75（隔离断口：85）4额定电流 A630 5额定短时耐受电流（3S ） 256额定峰值耐受电流 kA637配用最大高压熔断器 A125 8额定电流开断次数 1009机械寿命 次500010 防护等级IP3X11外形尺寸（宽*深*高） kA 375(500)*940*1635(1885)表二.熔断器的选择熔断器的选择应根据受保护变压器容量和系统短路容量计算确定：选择原则可“IEC787――用于变压器回路的高压熔断器熔丝的选择使用导则”。

© 2004 Fairchild Semiconductor Corporation DS500876October 2003Revised October 2004FIN1217 • FIN1218 • FIN1215 • FIN1216 LVDS 21-Bit Serializers/De-SerializersFIN1217 • FIN1218 •FIN1215 • FIN1216LVDS 21-Bit Serializers/De-SerializersGeneral DescriptionThe FIN1217 and FIN1215 transform 21-bit wide parallel LVTTL (Low Voltage TTL) data into 3 serial LVDS (Low Voltage Differential Signaling) data streams. A phase-locked transmit clock is transmitted in parallel with the data stream over a separate LVDS link. Every cycle of transmit clock 21 bits of input LVTTL data are sampled and trans-mitted.The FIN1218 and FIN1216 receive and convert the 3 serial LVDS data streams back into 21 bits of LVTTL data. Refer to Table 1 for a matrix summary of the Serializers and De-serializers available. For the FIN1217, at a transmit clock frequency of 85 MHz, 21 bits of LVTTL data are transmitted at a rate of 595 Mbps per LVDS channel.These chipsets are an ideal solution to solve EMI and cable size problems associated with wide and high-speed TTL interfaces.Featuress Low power consumptions 20 MHz to 85 MHz shift clock support s 50% duty cycle on the clock output of receiver s ±1V common-mode range around 1.2V s Narrow bus reduces cable size and cost s High throughput (up to 1.785 Gbps throughput)s Up to 595 Mbps per channels Internal PLL with no external component s Compatible with TIA/EIA-644 specification s Devices are offered in 48-lead TSSOP packagesOrdering Code:Devices also available in T ape and Reel. Specify by appending suffix letter “X” to the ordering code.Order Number Package NumberPackage DescriptionFIN1215MTD MTD4848-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide FIN1216MTD MTD4848-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide FIN1217MTD MTD4848-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide FIN1218MTDMTD4848-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm Wide 2F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216TABLE 1. Serializers/De-Serializers Chip MatrixBlock DiagramsTransmitter Functional Diagram for FIN1217 and FIN1215Receiver Functional Diagram for FIN1218 and FIN1216Part CLK FrequencyLVTTL INLVDS OUTLVDS INLVTTL OUTPackage FIN12178521348 TSSOP FIN12188532148 TSSOP FIN12156621348 TSSOP FIN12166632148 TSSOPFIN1217 • FIN1218 • FIN1215 • FIN1216TransmittersPin DescriptionsConnection DiagramFIN1217 and FIN1215 (21:3 Transmitter)Pin Assignment for TSSOPPin NamesI/O Type Number of PinsDescription of SignalsTxIn I 21LVTTL Level InputsTxCLKIn I 1LVTTL Level Clock InputThe rising edge is for data strobe.TxOut +O 3Positive LVDS Differential Data Output TxOut −O 3Negative LVDS Differential Data Output TxCLKOut +O 1Positive LVDS Differential Clock Output TxCLKOut −O 1Negative LVDS Differential Clock OutputPwrDn I 1LVTTL Level Power-Down InputAssertion (LOW) puts the outputs in high-impedance state.PLL V CC I 1Power Supply Pin for PLL PLL GND I 2Ground Pins for PLLLVDS V CC I 1Power Supply Pin for LVDS Outputs LVDS GNDI 3Ground Pins for LVDS Outputs V CC I 4Power Supply Pins for LVTTL Inputs GND I5Ground pins for LVTTL Inputs NCNo Connect 4F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216ReceiversPin DescriptionsConnection DiagramFIN1218 and FIN1216 (3:21 Receiver)Pin Assignment for TSSOPPin NamesI/O TypeNumber of PinsDescription of SignalsRxIn I 3Negative LVDS Differential Data Inputs RxIn +I 3Positive LVDS Differential Data Inputs RxCLKIn −I 1Negative LVDS Differential Clock Input RxCLKIn +I 1Positive LVDS Differential Clock Input RxOut O 21LVTTL Level Data Outputs Goes HIGH for PwrDn LOW RxCLKOut O 1LVTTL Clock OutputPwrDn I 1LVTTL Level InputRefer to Transmitter and Receiver Power-Up and Power-Down Operation Truth Table PLL V CC I 1Power Supply Pin for PLL PLL GND I 2Ground Pins for PLLLVDS V CC I 1Power Supply Pin for LVDS Inputs LVDS GNDI 3Ground Pins for LVDS Inputs V CC I 4Power Supply for LVTTL Outputs GND I5Ground Pins for LVTTL Outputs NCNo ConnectFIN1217 • FIN1218 • FIN1215 • FIN1216Truth TablesTransmitter Truth TableH = HIGH Logic Level L = LOW Logic Level X = Don’t CareZ = High Impedance F = FloatingNote 1: The outputs of the transmitter or receiver will remain in a High Impedance state until V CC reaches 2V.Note 2: TxCLKOut ± will settle at a free running frequency when the part is powered up, PwrDn is HIGH and the TxCLKIn is a steady logic level (L/H/Z).Receiver Truth TableH = HIGH Logic Level L = LOW Logic Level P = Last Valid State X = Don’t CareZ = High Impedance F = Failsafe ConditionNote 3: The outputs of the transmitter or receiver will remain in a High Impedance state until V CC reaches 2V.Note 4: Failsafe condition is defined as the input being terminated and un-driven (Z) or shorted or open.Note 5: If RxCLKIn ± is removed prior to the RxIn ± data being removed, RxOut will be the last valid state. If RxIn ± data is removed prior to RxCLKIn ± being removed, RxOut will be HIGH.InputsOutputsTxIn TxCLKIn PwrDn (Note 1)TxOut ±TxCLKOut ±Active Active H L/H L/H Active L/H/Z H L/H X (Note 2)F Active H L L/H F F H L X (Note 2)XXLZZInputsOutputsRxIn ±RxCLKIn ±PwrDn (Note 3)RxOut RxCLKOutActive Active H L/H L/H Active F (Note 4)H P H F (Note 4)Active H H L/H F (Note 4)F (Note 4)H P (Note 5)H XXLLH 6F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216Absolute Maximum Ratings (Note 6)Recommended Operating ConditionsNote 6: Absolute maximum ratings are DC values beyond which the device may be damaged or have its useful life impaired. The datasheet specifica-tions should be met, without exception, to ensure that the system design is reliable over its power supply, temperature, and output/input loading vari-ables. Fairchild does not recommend operation outside datasheet specifi-cations.Note 7: 100mV V CC noise should be tested for frequency at least up to 2 MHz. All the specification below should be met under such a noise.Transmitter DC Electrical CharacteristicsOver supply voltage and operating temperature ranges, unless otherwise specified. (Note 8)Note 8: All Typical values are at T A = 25°C and with V CC = 3.3V.Note 9: Positive current values refer to the current flowing into device and negative values means current flowing out of pins. Voltage are referenced toground unless otherwise specified (except ∆V OD and V OD ).Note 10: The power supply current for both transmitter and receiver can be different with the number of active I/O channels.Note 11: The 16-grayscale test pattern tests device power consumption for a “typical ” LCD display pattern. The test pattern approximates signal switching needed to produce groups of 16 vertical strips across the display.Power Supply Voltage (V CC )-0.3V to +4.6VTTL/CMOS Input/Output Voltage −0.5V to +4.6V LVDS Input/Output Voltage-0.3V to +4.6V LVDS Output Short Circuit Current (I OSD )ContinuousStorage Temperature Range (T STG )−65°C to +150°CMaximum Junction Temperature (T J )150°CLead Temperature (T L )(Soldering, 4 seconds)260°CESD Rating (HBM, 1.5 k Ω, 100 pF)LVDS I/O to GND>10.0 kV All Pins (FIN1215, FIN1217 only)>6.5 kV ESD Rating (MM, 0Ω, 200 pF)(FIN1215, FIN1217 only)>400VSupply Voltage (V CC )3.0V to 3.6VOperating Temperature (T A )(Note 6)−40°C to +85°CMaximum Supply Noise Voltage (V CCNPP )100 mV P-P (Note 7)Symbol ParameterTest ConditionsMin TypMax Units Transmitter LVTTL Input CharacteristicsV IH Input High Voltage 2.0V CC V V IL Input Low Voltage GND0.8V V IK Input Clamp Voltage I IK = −18 mA −0.79−1.5V I INInput CurrentV IN = 0.4V to 4.6V 1.810.0µAV IN = GND−10.00Transmitter LVDS Output Characteristics (Note 9) V OD Output Differential VoltageR L = 100 Ω, See Figure 1250450mV ∆V OD V OD Magnitude Change from Differential LOW-to-HIGH 35.0mV V OS Offset Voltage1.1251.251.375V ∆V OS Offset Magnitude Change from Differential LOW-to-HIGH mV I OS Short Circuit Output Current V OUT = 0V−3.5−5.0mA I OZ Disabled Output Leakage Current DO = 0V to 4.6V, PwrDn = 0V±1.0±10.0µATransmitter Supply CurrentI CCWT21:3 Transmitter Power Supply Current 33.0 MHz28.046.2mAfor Worst Case Pattern (With Load)R L = 100 Ω, 40.0 MHz29.051.7(Note 10), (Note 11)See Figure 365.0 MHz 34.057.2(85.0 MHz Specification for FIN1217 only)85.0 MHz39.062.7I CCPDTPowered Down Supply CurrentPwrDn = 0.8V 10.055.0µAFIN1217 • FIN1218 • FIN1215 • FIN1216Transmitter AC Electrical CharacteristicsOver supply voltage and operating temperature ranges, unless otherwise specified.Note 12: Outputs of all transmitters stay in 3-STATE until power reaches 2V. Both clock and data output begins to toggle 10ms after V CC reaches 3V andPower-Down pin is above 1.5V.Note 13: This output data pulse position works for both transmitter with 21 TTL inputs except the LVDS output bit mapping difference (see Figure 15). Figure 16 shows the skew between the first data bit and clock output. Also 2-bit cycle delay is guaranteed when the MSB is output from transmitter.Note 14: This jitter specification is based on the assumption that PLL has a ref clock with cycle-to-cycle input jitter less than 2ns.Symbol ParameterTest ConditionsMin Typ Max Units t TCP Transmit Clock PeriodSee Figure 611.76T 50.0ns t TCH Transmit Clock (TxCLKIn) HIGH Time 0.350.50.65T t TCL Transmit Clock Low Time0.350.50.65T t CLKT TxCLKIn Transition Time (Rising and Failing)(10% to 90%) See Figure 7 1.06.0ns t JIT TxCLKIn Cycle-to-Cycle Jitter 3.0ns t XIT TxIn Transition Time1.56.0ns LVDS Transmitter Timing Characteristicst TLH Differential Output Rise Time (20% to 80%)See Figure 40.75 1.5ns t THL Differential Output Fall Time (80% to 20%)0.751.5ns t STC TxIn Setup to TxCLNIn See Figure 62.5ns t HTC TxIn Holds to TCLKIn(f = 85 MHz) (FIN1217 only)0ns t TPDD Transmitter Power-Down DelaySee Figure 13, (Note 12)100ns t TCCDTransmitter Clock Input to Clock Output Delay See Figure 95.5nsTransmitter Clock Input to Clock Output Delay(T A = 25°C and with V CC = 3.3V)2.86.8Transmitter Output Data Jitter (f = 40 MHz) (Note 13)t TPPB0Transmitter Output Pulse Position of Bit 0See Figure 16−0.2500.25ns t TPPB1Transmitter Output Pulse Position of Bit 1a −0.25a a +0.25ns t TPPB2Transmitter Output Pulse Position of Bit 2 a =12a −0.252a 2a +0.25ns t TPPB3Transmitter Output Pulse Position of Bit 3 f x 73a −0.253a 3a +0.25ns t TPPB4Transmitter Output Pulse Position of Bit 44a −0.254a 4a +0.25ns t TPPB5Transmitter Output Pulse Position of Bit 55a −0.255a 5a +0.25ns t TPPB6Transmitter Output Pulse Position of Bit 66a −0.256a 6a +0.25ns Transmitter Output Data Jitter (f = 65 MHz) (Note 13)t TPPB0Transmitter Output Pulse Position of Bit 0See Figure 16−0.200.2ns t TPPB1Transmitter Output Pulse Position of Bit 1a −0.2a a +0.2ns t TPPB2Transmitter Output Pulse Position of Bit 2 a =12a −0.22a 2a +0.2ns t TPPB3Transmitter Output Pulse Position of Bit 3 f x 73a −0.23a 3a +0.2ns t TPPB4Transmitter Output Pulse Position of Bit 44a −0.24a 4a +0.2ns t TPPB5Transmitter Output Pulse Position of Bit 55a −0.25a 5a +0.2ns t TPPB6Transmitter Output Pulse Position of Bit 66a −0.26a 6a +0.2ns Transmitter Output Data Jitter (f = 85 MHz) (FIN1217 only) (Note 13)t TPPB0Transmitter Output Pulse Position of Bit 0See Figure 16−0.200.2ns t TPPB1Transmitter Output Pulse Position of Bit 1a −0.2a a +0.2ns t TPPB2Transmitter Output Pulse Position of Bit 2 a =12a −0.22a 2a +0.2ns t TPPB3Transmitter Output Pulse Position of Bit 3 f x 73a −0.23a 3a +0.2ns t TPPB4Transmitter Output Pulse Position of Bit 44a −0.24a 4a +0.2ns t TPPB5Transmitter Output Pulse Position of Bit 55a −0.25a 5a +0.2ns t TPPB6Transmitter Output Pulse Position of Bit 66a −0.26a 6a +0.2nst JCCFIN1217 Transmitter Clock Out Jitter f = 40 MHz350370ps (Cycle-to-Cycle) f = 65 MHz210230See Figure 19f = 85 MHz (FIN1217 only)110150t TPLLSTransmitter Phase Lock Loop Set Time (Note 14)See Figure 11, (Note 13)10.0ms 8F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216Receiver DC Electrical CharacteristicsOver supply voltage and operating temperature ranges, unless otherwise specified. (Note 15)Note 15: All Typical Values are at T A = 25°C and with V CC = 3.3V. Positive current values refer to the current flowing into device and negative values means current flowing out of pins. Voltage are referenced to ground unless otherwise specified (except ∆V OD and V OD ).Note 16: The power supply current for the receiver can be different with the number of active I/O channels.Symbol ParameterTest ConditionsMin TypMax Units LVTTL/CMOS DC CharacteristicsV IH Input High Voltage 2.0V CC V V IL Input Low Voltage GND 0.8V V OH Output High Voltage I OH = −0.4 mA 2.73.3V V OL Output Low Voltage I OL = 2 mA 0.3V V IK Input Clamp Voltage I IK = −18 mA −1.5V I IN Input CurrentV IN = 0V to 4.6V −10.010.0µA I OFF Input/Output Power Off Leakage Current V CC = 0V,±10.0µA All LVTTL Inputs/Outputs 0V to 4.6V I OS Output Short Circuit Current V OUT = 0V −60.0−120mAReceiver LVDS Input CharacteristicsV TH Differential Input Threshold HIGH Figure 2, Table 2100mV V TL Differential Input Threshold LOW Figure 2, Table 2−100mV V ICM Input Common Mode Range Figure 2, Table 20.052.35V I INInput CurrentV IN = 2.4V, V CC = 3.6V or 0V ±10.0µA V IN = 0V, V CC = 3.6V or 0V±10.0µAReceiver Supply Current I CCWR3:21 Receiver Power Supply Current 33.0 MHz 66.0mAfor Worst Case Pattern (With Load)C L = 8 pF, 40.0 MHz 56.074.0(Note 16)See Figure 365.0 MHz 75.0102(85.0 MHz Specification for FIN1218 only)85.0 MHz92.0125I CCPDRPowered Down Supply CurrentPwrDn = 0.8V (RxOut stays LOW)NA400µAFIN1217 • FIN1218 • FIN1215 • FIN1216Receiver AC Electrical CharacteristicsOver supply voltage and operating temperatures, unless otherwise specifiedNote 17: Receiver skew margin is defined as the valid sampling window after considering potential setup/hold time and minimum/maximum bit position.Note 18: Total channel latency from serializer to deserializer is (T + t TCCD ) + (2*T + t RCCD ). There is the clock period.Symbol ParameterTest ConditionsMin Typ MaxUnits t RCOL RxCLKOut LOW Time 10.011.0ns t RCOH RxCLKOut HIGH Time See Figure 810.012.2ns t RSRC RxOut Valid Prior to RxCLKOut (Rising Edge Strobe) 6.511.6ns t RHRC RxOut Valid After RxCLKOut(f = 40 MHz)6.011.6ns t RCOP Receiver Clock Output (RxCLKOut) Period 15.0T 50.0ns t RCOL RxCLKOut LOW Time See Figure 8 5.07.89.0ns t RCOH RxCLKOut HIGH Time (Rising Edge Strobe) 5.07.39.0ns t RSRC RxOut Valid Prior to RxCLKOut (f = 65 MHz) 4.57.7ns t RHRC RxOut Valid After RxCLKOut4.08.4ns t RCOP Receiver Clock Output (RxCLKOut) Period 11.76T 50.0ns t RCOL RxCLKOut LOW Time See Figure 8 4.0 6.3 6.0ns t RCOH RxCLKOut HIGH Time (Rising Edge Strobe) 4.55.46.5ns t RSRC RxOut Valid Prior to RxCLKOut (f = 85 MHz) (FIN1218 only) 3.5 6.3ns t RHRC RxOut Valid After RxCLKOut 3.56.5ns t ROLH Output Rise Time (20% to 80%)C L = 8 pF 2.2 5.0ns t ROHL Output Fall Time (80% to 20%)See Figure 52.1 5.0ns t RCCD Receiver Clock Input to Clock Output Delay See Figure 10 (Note 18)3.56.97.5ns T A = 25°C and V CC = 3.3V t RPDD Receiver Power-Down DelaySee Figure 141.0µs t RSPB0Receiver Input Strobe Position of Bit 0 1.02.15ns t RSPB1Receiver Input Strobe Position of Bit 1 4.5 5.8ns t RSPB2Receiver Input Strobe Position of Bit 2See Figure 178.19.15ns t RSPB3Receiver Input Strobe Position of Bit 3(f = 40 MHz)11.612.6ns t RSPB4Receiver Input Strobe Position of Bit 415.116.3ns t RSPB5Receiver Input Strobe Position of Bit 518.819.9ns t RSPB6Receiver Input Strobe Position of Bit 622.523.6ns t RSPB0Receiver Input Strobe Position of Bit 00.7 1.4ns t RSPB1Receiver Input Strobe Position of Bit 1 2.9 3.6ns t RSPB2Receiver Input Strobe Position of Bit 2See Figure 17 5.1 5.8ns t RSPB3Receiver Input Strobe Position of Bit 3(f = 65 MHz)7.38.0ns t RSPB4Receiver Input Strobe Position of Bit 49.510.2ns t RSPB5Receiver Input Strobe Position of Bit 511.712.4ns t RSPB6Receiver Input Strobe Position of Bit 613.914.6ns t RSPB0Receiver Input Strobe Position of Bit 00.49 1.19ns t RSPB1Receiver Input Strobe Position of Bit 1 2.17 2.87ns t RSPB2Receiver Input Strobe Position of Bit 2 3.85 4.55ns t RSPB3Receiver Input Strobe Position of Bit 3See Figure 175.536.23ns t RSPB4Receiver Input Strobe Position of Bit 4(f = 85 MHz) (FIN1218 only)7.217.91ns t RSPB5Receiver Input Strobe Position of Bit 58.899.59ns t RSPB6Receiver Input Strobe Position of Bit 610.5711.27nst RSKMRxIn Skew Margin f = 40 MHz; See Figure 18490ps(Note 17)f = 65 MHz; See Figure 18400f = 85 MHz (FIN1218 only);252See Figure 18t RPLLSReceiver Phase Lock Loop Set TimeSee Figure 1210.0ms 10F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216FIGURE 1. Differential LVDS Output DC Test CircuitNote A: For all input pulses, t R or t F < = 1 ns.Note B: C L includes all probe and jig capacitance.FIGURE 2. Differential Receiver Voltage Definitions and Propagation Delay and Transition Time Test CircuitTABLE 2. Receiver Minimum and Maximum Input Threshold Test VoltagesApplied VoltagesResulting Differential Input Voltage Resulting Common Mode Input Voltage(V)(mV)(V)V IA V IB V ID V IC 1.25 1.151001.21.15 1.25−100 1.22.4 2.31002.352.3 2.4−100 2.350.101000.0500.1−1000.051.50.96001.20.9 1.5−600 1.22.4 1.86002.11.8 2.4−600 2.10.606000.300.6−6000.3FIN1217 • FIN1218 • FIN1215 • FIN1216AC Loading and WaveformsNote: The worst case test pattern produces a maximum toggling of digital circuits, LVDS I/O and LVTTL/CMOS I/O. Depending on the valid strobe edge of transmitter, the TxCLKIn can be either rising or falling edge data strobe.FIGURE 3. “Worst Case ” Test PatternFIGURE 4. Transmitter LVDS Output Load and Transition TimesFIGURE 5. Receiver LVTTL/CMOS Output Load and Transition TimesFIGURE 6. Transmitter Setup/Hold and HIGH/LOW Times (Rising Edge Strobe)FIGURE 7. Transmitter Input Clock Transition Time 12F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216AC Loading and Waveforms (Continued)FIGURE 8. Receiver Setup/Hold and HIGH/LOW TimesFIGURE 9. Transmitter Clock In to Clock Out Delay (Rising Edge Strobe)FIGURE 10. Receiver Clock In to Clock Out Delay (Falling Edge Strobe)FIN1217 • FIN1218 • FIN1215 • FIN1216AC Loading and Waveforms(Continued)FIGURE 11. Transmitter Phase Lock Loop Set TimeFIGURE 12. Receiver Phase Lock Loop Set TimeFIGURE 13. Transmitter Power-Down Delay 14F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216AC Loading and Waveforms(Continued)FIGURE 14. Receiver Power-Down DelayNote: This output data pulse position works for both transmitter with 21 TTL inputs except the LVDS output bit mapping difference. All the information in this diagram tells that the skew between the first data bit and clock output. Also 2-bit cycle delay is guaranteed when the MSB is output from transmitter.FIGURE 15. 21 Parallel LVTTL Inputs Mapped to 3 Serial LVDS OutputsFIGURE 16. Transmitter Output Pulse Bit PositionFIN1217 • FIN1218 • FIN1215 • FIN1216AC Loading and Waveforms (Continued)FIGURE 17. Receiver Input Strobe Bit PositionNote: t RSKM is the budget for the cable skew and source clock skew plus ISI (Inter-Symbol Interference).Note: The minimum and maximum pulse position values are based on the bit position of each of the 7 bits within the LVDS data stream across PVT (Process, Voltage Supply, and Temperature).FIGURE 18. Receiver LVDS Input Skew Margin 16F I N 1217 • F I N 1218 • F I N 1215 • F I N 1216AC Loading and Waveforms(Continued)Note: This jitter pattern is used to test the jitter response (Clock Out) of the device over the power supply range with worst jitter ±3ns (cycle-to-cycle) clock input. The specific test methodology is as follows:•Switching input data TxIn0 to TxIn20 at 0.5 MHz, and the input clock is shifted to left −3ns and to the right +when data is HIGH (by switching between CLK1 and CLK2 in Figure 11)•The ±3ns cycle-to-cycle input jitter is the static phase error between the two clock sources. Jumping between two clock sources to simulate the worst case of clock edge jump (3 ns) from graphical controllers. Cycle-to-cycle jitter at TxCLK out pin should be measured cross V CC range with 100mV noise (V CC noise frequency <2 MHz).FIGURE 19.17FIN1217 • FIN1218 • FIN1215 • FIN1216 LVDS 21-Bit Serializers/De-SerializersPhysical Dimensions inches (millimeters) unless otherwise noted48-Lead Thin Shrink Small Outline Package (TSSOP), JEDEC MO-153, 6.1mm WidePackage Number MTD48Fairchild does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and Fairchild reserves the right at any time without notice to change said circuitry and specifications.LIFE SUPPORT POLICYFAIRCHILD ’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION. As used herein:1.Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and (c) whose failure to perform when properly used in accordance with instructions for use provided in the labeling, can be rea-sonably expected to result in a significant injury to the user.2. A critical component in any component of a life support device or system whose failure to perform can be rea-sonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.。

史上最全的塑料牌号熔指对照表牌号熔指g/10min 牌号熔指g/10min牌号熔指g/10minLDPE－普通膜类LD100ACLD1001.7-2.3 2102TN26 2.1-2.9 LD160BW 2LD155 1.7-2 2436H 2 LD160 LD160AS3-5LD662 1.9 2426H 2 FD0274 2.4LD600 2 2426K 4 3026H 1.7-2.2 LD617 2LDPE－透明膜类LD104 1.7-2.3 200GG 2 F222 2LD105 2 F210-6 2 FB3000 3QLT-04 2.4-3.6 530G 2.8 5320 2Q281 2.8 FD0474 4LDPE－收缩膜/重包装膜类LD163 0.3 2423D 0.3 1810E 0.5LD165 0.23-0.43 2420F 0.7 FB3003 0.3LD150 0.6-0.9 2426F 0.7 1810D 0.2-0.5 2100TN00 0.25-0.3 3020D 0.15-0.35 FB0300 0.3 2420D 0.3LDPE－注塑及薄膜类18D18D01.5 2420H 1.7-2.2 3026K3.4-4.6 1I2A 2 3020H 1.7-2.2 2420K 3.4-4.6 2420H 2 3020K 3.4-4.6 EB-853/72 2.7 2420K 4 1810H 1.3-1.8 1816H 1.3-1.8 3025K 2LDPE－高熔指注塑类LD615 12-18 1I50A 50 2410T 36 1810S 17-22 LD400 20-30 MG70 70 2410T 33-39LDPE－发泡类1F7B 7 15803 2-2.5 LD607/608 5-7LD605 4.5-7.5 10803 2-2.5LDPE－电缆料类2102-TN00 2.1-2.9 DJ200A 2 2220H 1.8-2.2 LD100BW 2.2 2210H 2 18E 1.8DJ210 2.1 LD200BW 2.2LDPE－涂层类1C10A 10 940 12 LB7500 7.51C7A 7 950 7.5 18G 7-81C7A-1 7.2 801YY 7 961 5.3 LLDPE－农地膜类7042 2 UF414 2 21HN 27042T 2 3224 2 7042N 29020 2 3305 2 7042K 21802 2 218W 2 9042 27050 1.9-2 218N 2 1002YB 20220KJ 2 0218D 2 7120B 20220AA 2 1002KW 2 FV149M 2QLLF-20 2LLDPE－棚膜类7047 1 0209KJ 0.9 1020CC 17085 1 6209AA 0.9 6208AF 0.75 9085 0.8 22010 1 7080 1.0 9086 1 FU149M 1 QLLP-01 11801 1 118N 1 9088 10209AA 0.8-1 21HS 1 0209AA 0.9 LLDPE－缠绕膜类9030 2 0220AA 2.4 QLLF-05 3.4±0.5 LLDPE－茂金属类18H27DX 2.7 SP1520 1.8 2045G 118H10AX 1 1520F 2LLDPE-高熔指类FB2230 22 JL210 20LLDPE－粉料类7042粉 2 1820粉 2 2650粉50 7047粉 1 1875粉0.75-1MDPE7149 4 3321C 0.1 3721C 0.1 7150 2.8HDPE－拉丝类5000S 0.9 E308 0.9 8010 15010 0.6-1 E808 0.9 EE52009 0.9 5410AA 0.9-1 HD53EA010 1 HM5000 14000F 0.6-1.6 E309 1 HF7740F2 0.8（5kg）6084A 1 3300 1 5000S 0.9 GF7750 0.36-0.54 Y910A 1 3300 0.8 5609AA 0.9 T10 1HDPE－注塑类2908 8 T60-800 6.5-10 5306J 6.32909 12 I3 8 6070UA 7.6 2911 20 3840UA 4 5218AA 18 2911FS 20 5740UA 3.9 5018L 20 1600J 18 8008 8 9018 18-20 5070 6-8 5226AA 26 M691 20 6070 6.5-8 2200J 5 ME9180 18 5218 16-20 3300J 2.5-3.0 60550 5-7 7260 6-9 8007 5-11 8007 7-8 HC7260 8HDPE－中空类5421B 0.05 5420AA *2 HM8255 0.354261A 0.05 5502AA 0.2 HM6255 2.2（21.6kg ）5200B 0.35 5502FA 0.2 0855S1 0.45-0.6 1158 *1.4-2.8 5403AA 0.25 60-70 0.76145 *12-21 9001 0.05 5401AA 2（21.6）6147 *7-14 B303 0.33 6007 0.70 5300B 0.2-0.5 BE0400 0.25 TR-512 5.55420GA 2.1 5021D 0.2 5621D 0.25502 0.25-0.45HDPE－薄膜类6098 0.08 TR168 7.5-11 9455F 0.25 6093 F600 0.05 TR144 0.16-0.22 9255F TR144 0.18 EX5 0.28 5121B 0.05 8800 0.04 961 0.17000F 0.035-0.055640UF 0.04 9001 0.055301AA 0.08 7000F 0.04 7007 0.04HM9450F 0.28（5kg）F120A 0.04 HM9450F10.22（5kg）HDPE－电缆料类5300E 0.8 QHJ-01 0.8 HDPE－管材/管道专用料类6360M 0.22-0.3 HM5010T2N 0.45（5kg）PN-049-030-122 0.36380M 0.13 HM5010T3N 0.43（5kg）5135B0.4（D1238）6100M 0.15 HMCRP100N 0.22（5kg）TR480 0.11QHE16A 3.5 041 0.17-0.34 C100S 0.23（5kg）QHE16B 5.5 4401 0.11 P110A 0.23 2480 10-15 4801EX 11 9398 *10K44-08-122 8.75 2630 0.1 P600 0.12K38-20 0.85 P301E 0.12 P502 0.15 2480H 0.12-0.15管道包覆料类PE胶 1.5 BP0900WH 0.4 P601KUBL 0.3BFPE 0.3HDPE－交联聚乙烯类（PEX）P300X 0.03-0.04 J0253P 1.5-2.5 2300XM 0.12-0.15 PERT(耐热聚乙烯)DX-800 0.64EVA－膜类EVA 14-2 14 V5110F 16.6-19.4 EF443 12EVA 14-0.7 14 V4110J 12.6-15.4 7140F 14-0.7 EVA9-0.7 9 V4110F 8-10 V4110D 12.6-15.4 V3110F 0.7 EF321 9 V3110F 4-6EVA－发泡类EVA18-3 18 7350M 18 V3510K 11.6-14.4 V5110J 18 EVAE180F 18 1316 19-1.8V5110K MI:4,22 VS430 26 V4610H 16.6-19.4 均聚聚丙烯 PP－注塑类1300 1.5 V2400G 17 T50G 3.21400 3 V2401G 17 C30G 6K1003 3 X30G 9 J700 12K1008 10 F37G 11 J701 16C1008 10HA840R20 F30G 10-141700 11 Z30G 25 F30G 12K1003 3 H32GA 35 V30G 16-20K1215 15 ADXP770 45 V30G 16K1514 13.5 S30G 1.8 T30G 3.2HP500N 12PP－纤维类T30S 2.5-3.5 Z30S 25 S2040 38T30S 3.2 Z21S 25 HP565S 38C30S 6 Z69S 25 H7700 39F401 2.5-3 F30S 12 HP563S 38PP022 3 C30G 6 RPP1200 1200±100 S1003 3.2 HOXP817 25 Z30S 22-27 5004 2.6-4.4 H561S 35 Z30S 11-20 HP550J 3.2 HP551M 9.5 Z30S 25F501 3 H561R 25 Z30S 20 H0305G 3 HY525 35 Z30S 22-28H5300 3.5 H30S-1 25 71735 355014 3.5 S900 35 H30S 35S30S 1.8 H39S 35 H30S-2 36Y-130 3.5 F79S 12 YS835 35-38 6531M 2 V79S 18 3365 3H730F 3.5 YF39S 12 HP450J 3SY130 3.5 H22S 38 HP502N 12H430 3.5 71740 40 HP550R 25PP－粉料类T30S粉2-3 PP粉2-3 PP粉045 2-3T30S粉2-3 PP粉2-3 PP粉045 2-3T30S粉2-3 Z30S粉16-20 C30S粉16-20 T30S粉2-3 V30S粉16-20PP－BOPP膜类F1002 1.7-2.8 T38FE 2.6 T36F 3YX37F 9 T38CA 3.1 T36F 2.6T28F 3 PH384 3 F280Q 3.5S28F 2 HP523J 3 T38F 3S38F 2 YC37F 6 T38F 3S38FA 2 ADXP856 7 T38FA 3S38CA 2.1 T28C 3.1 F1002B 2.8S28C 2.1 F280S 2.8 HP425J 3.1F1002A 2.8 LI28F 3 HP525J 3PP－其它薄膜类HP510M 9 EP3C37F 5.5 4540 10-12 T30SW 3.2 F1608 8 H4540 12C1007 7 1088B 11PP－涂膜类70126 20-32 670M 21 HPP100 33.63 H300 28.6 R680S 2.8PP－其他用途YD50G 0.3 HP648H 2.2 ADXP855 7D50S 0.3 T2101F 3.5 YS32S 2Q30P 0.7 ADX680 3.5共聚聚丙烯PP－低熔指类K8303 1.5 EP300H 1.8 T3401 0.3 1340 1.2 EP300K 3.5 F3002 2.2K8003 2.5 T8002 1.7 B4002 2K7002 1.4 J340 1.7 EPS31HP 1.3J340 0.98-2 J440 4 EPT30M 3.5 EPS30U 1.5 EPD60R 0.35 EPT30U 3.5 EPS30RA 2-2.2 EPQ30M 0.8 HEXP2085 2.1 EPT30R 3.5 EPQ30RF 0.8 JD803 1.5-2.2 P340 0.7-1.3 EPYS30RE 1.3 EPS30R 1.2-1.8 PP－中熔指类7708 8-10 EPC30R 7 EP2C30F 61647 8-10 EPC40R 7 EP2C37F 6 1847 15 EPF31H 12 EP3C37F 5SP179 7-11 EPF31HA 12 EP3X37F 8SP179 8 EPF31HR 12 EP3C39F 5 EPF30R 11-15 BA238G3 12 BJ300 5EP300M 7 EP445L 7 BJ500 10 EP300M 8 EP1X35F 8 AW564 8-10 C4008B 8 EP1X35AF 8 BJ500 8-9 AP3N 8-10 EP1X35HF 8 EPC31HR 6 EPC31H 6PP－高熔指类K9920 20 BJ750 30 EP380T 55K9020 20 EPH31RA 40 K9020 20K9026 26 EPYH31U 40 K9935 35 1947 28 EPH71HA 45 EP340S 40K7726 /K7726H29 EPL31UA 70 J640 18 9935 35 EPN31MA 100 HEXP280 18 9035 35 HEXP2019 100 EPV31RA 21K7760 50 J740 30 AZ564 29K7926 30 B38G 28 K8025 25K7930 30 AP03B 29 M1600 25-29 K8224 24透明聚丙烯PP类RP340S 42 GM160E 1.6 R370Y 20 RP340R 25 6019 19 560S 18 RP346R 25 K2925 25 M800E 8EP2X32G 8.05（2.16）K2328 28 M1600E 16.5B4902 2.2 RP340N 10 EP2S29B 1.8 4912 12 RJ760 22 EP2X49GA 10T4802 2.5 EP2S12B 1.8 EP2YX29GA 10B4808 11 EP2S30B 1.8 EP2Z29G 25B4818 20 K4912 12 RP1085 42K4812 12PPR（热水管）4220 0.3 Q802 0.1-0.5 R200P 0.28 4101 0.29 RP2400 0.25 14D 0.3-05 PPB（冷水管）2K0640P 0.36 Q803 0.1-0.5 240 0.3-0.5 C180 0.35 HB240P 0.3 Q801 0.1-0.5 8101 0.45 BP2000 0.3 EP332C 0.3-0.5 B8101 0.45 M910 0.33 B8001 0.5 4228 0.3-0.5透明聚苯乙烯GPPS666D 8 251P 2.5 PG-383M 2.2 525 7-9 158K 3 123P 10200D 6-10 GP-500 3.5-6.5 232P 3.8 206 14 GP5000 10 MC3100 3.0 PG-33 8高抗冲聚苯乙烯HIPS825 2.5 H690 3-5 466F 4PH-88HT 4 514P 10 476F 5PH-88H 4.7 532 4.6 H650 3-5 PH-888G 4 622P 4.8 641 2.5 PH-88S 2.6 632E 3.6 MA5210 4苯乙烯－丙烯腈ASAS HF 5 118L100 3 138H 1127 1.5 118L150 3 127H 1.5 128 3 127-L200 1.5 PN-118 3128H 1.5 117C 5 D-178 1.8D-178L200 2.5ABS－通用级0215A 20 757K 4.2 8434CH510 2.5 707K 1.9 8391CH520 2.5 15A1 1.6 757 1.8 750A 4.5 15E1 1.8 D-180 1.7 301 1.3-2.3 GP-22 13-23 D-190 1.82 301W 1.5 121H 20 D-178 1.8 750 4.5 GR2000 15 756S 70SD-0150 1.8 D-150 1.6 727 1.8 ABS－挤出级747原白0.8 D-120 0.7 717C ＊15 747磁白 1.2 L862 ＊10 709 ＊6 ABS-阻燃级FABS-01 －765B 4.2 L853 ＊60 ABS－耐热级777D *6 L840 *7 D-168 0.7 777B *6.5ABS－透明级758 3 TR558 *22K树脂 (苯乙烯-丁二烯共聚物)K树脂0.94 5910 9.5-10 5903 9.0-10 GH62聚甲醛POMM270 27 F20-02 9 F30-03 27M90 9 F20-03 9 F20-03 9M90-01 9 F20-02 9 100P 2.3 M270-44 27 F20-33 8.5-10.5 500P 7M90-44 9聚碳酸酯PCPK2870 2.5 143R-111 10.5 201-10 10 110 10 OQ1020 70 IR2200 12 K-1300Y 3 OQ1050-112 80 144R-111 10.5 1250Y 8 945 10 1220R 21.7 101R-111 7 201-15 10.5 1100R 10.1 141R-111 10.5 241R-111 10.5 HF1140 25牌号粘度Pa·s 牌号粘度Pa·s牌号粘度Pa·s聚酯切片PET普粘切片0.6-0.65 80K 0.785-0.815CZ-318 0.835高粘切片0.80以上尼龙6 （PA6）70G33 1.39 尼龙6切片 2.9±0.03223D 2.3 1013B 2.7尼龙66 （PA66）1300S 2.6-2.7FYR27 2.70±0.03 FYR26H2.60±0.03A3K 2.5-2.7FYR27B 2.75±0.05 FYR27T032.67±0.05FYR25T03CL 2.55±0.02 FYR25T15CL2.58±0.05尼龙12 （PA12）1010 1.75-1.95聚甲基丙烯酸甲酯（压克力） PMMA850 12.5 207 8 205 1.8211 16牌号B/S比例牌号B/S比例牌号B/S比例塑料改性用SBS1401 40/60 501P 31/69 T161B792 40/60 501S 31/69 475P 40/60T172牌号熔融色度牌号熔融色度牌号熔融色度增塑剂苯酐苯酐（齐鲁石化）20苯酐（吉林化学）20牌号聚合度牌号聚合度牌号聚合度PVC－乙烯法S-1000 1000-1100 DG-700 700 WS-1300 1250-1350S-700 650-750 DG-800 800 M-1000 1000S-800 750-850 TK1000 1000 SR-800 800S-1300 1250-1350 P-1000 1000-1100 QS-800F 780QS-1000F 1010 LS-100 1030 DG-1300 1300QS-1050P 1030 SLP-1000 1030 DG-1000K 1000QS-650 650 SLK-1000 1030 WS-1000 1000SE-700 650-750 WS-800 750-850 SR-1000 1000 PVC－电石法SG-3 1300 SG-7 750 SG-5 1050糊树脂P1069 1800±300P455 850±120P450 1000±150 P440 1450±200。

1215钢材1215易切削钢为环保料,与12L14相比不含铅及不含有对环境有害物质,切削性良好.适合一般电镀轴心、切削用料及一般零件.1215由于精度准确,表面状况良好,易削切钢产品可直接使用,如喷涂,打砂,打弯,钻孔,也可按实际要求精拉之后直接电镀,免去了大量机加工时间及节省配置加工机械的费用.1215钢材用途主要用于制作受力较小而对尺寸和光洁度要求严格的仪器仪表、手表零件、汽车、机床和其他各种机器上使用的，对尺寸精度和光洁度要求严格，而对机械性能要求相对较低的标准件，如齿轮、轴、螺栓、阀门、衬套、销钉、管接头、弹簧座垫及机床丝杠、塑料成型模具、外科和牙科手续用具等。

1215钢材化学成份(%):C :≤0.09Mn :0.75-1.05P :0.04-0.09S :026-0.351215钢材力学性能1215易切钢的抗拉强度σb (MPa)：(热轧)390～540; 1215易切钢(冷拉)钢材厚度或直径8～20时:530～755; >20～30时:510～735; >30时:490～685，1215易切钢的伸长率δ5 (%)：(热轧)≥22; (冷轧)≥7.0，1215易切钢的面收缩率ψ (%)：(热轧)≥36 1215钢材交货状态：钢厂出厂直接交货为圆钢黑棒也叫热轧钢。

1215易切钢冷拉光棒:硬度可达160~190HB,省去热处理费用,可直接加工。

磨光棒:表面精糙度正负0.05 1215钢材优点及使用范围：1215易切钢硫含量高，切削加工性能好，塑性高，强度更高。

1215易切削钢产品具有以下优点： a.形状规格多样性：通过设计不同形状的模具，冷拉出不同截面形状、不同规格公差的易切削钢。

角度可成直角或圆角。

b.高精确度：使用高质量的硬质合金模具，确保公差准确、统一。

c.表面光滑：先进的冷挤压工艺使得易切削钢产品表面光滑明亮。

e.材料大量节省：冷拉工艺是将原材料冷挤压变形达致所需的形状、规格及公差，原材料的耗损极少，相对利用传统车床机加工切削所耗损的材料，易切削钢所节省的材料和时间是非常可观的，特别当材料用量大，材料成本的节约更为显著。

1215是什么材料
1215是一种特殊的铝合金材料，也被称为铝镁合金。

它的主要成分是铝和镁，其中铝含量达到了85%，镁含量达到了15%。

这种材料具有很高的强度和硬度，同时还具有良好的耐腐蚀性能，因此在工业领域得到了广泛的应用。

首先，1215铝合金具有很高的强度，这使得它在工程结构中可以承受较大的载荷。

在航空航天、汽车制造、船舶建造等领域，1215铝合金常常被用来制造各种零部件，如车身结构、发动机零部件、船体结构等。

其高强度可以有效地保证这些零部件在工作过程中不会发生变形或破损，从而保证了整个机械设备的安全可靠运行。

其次，1215铝合金还具有良好的硬度，这使得它在加工过程中不容易变形或损坏。

在制造工业中，1215铝合金常被用来制造各种模具、工装以及工件，其硬度可以有效地保证这些零部件在使用过程中不会出现变形或磨损，从而保证了生产过程的稳定性和产品的质量。

另外，1215铝合金还具有良好的耐腐蚀性能，这使得它在一些特殊环境下也能够发挥很好的作用。

在海洋工程、化工设备、食品加工等领域，1215铝合金常被用来制造各种设备和零部件，其耐腐蚀性能可以有效地延长这些设备和零部件的使用寿命，降低了维护成本和更换频率。

总的来说，1215铝合金作为一种特殊的铝合金材料，具有很高的强度和硬度，同时还具有良好的耐腐蚀性能，因此在工业生产中得到了广泛的应用。

它不仅可以保证工程结构的安全可靠，还可以保证生产设备的稳定运行，降低了生产成本，提高了生产效率。

可以说，1215铝合金在工业生产中发挥着重要的作用，对于推动工业的发展起到了积极的作用。

NCP1215Low Cost Variable OFF Time Switched Mode Power Supply ControllerThe NCP1215 is a controller for low power off−line flyback Switchemode Power Supplies (SMPS) featuring low size, weight and cost constraints together with a good low standby power performance. The operating principle uses switching frequency reduction at light load by increasing the OFF Time. Also, when OFF Time expands, thepeak current is gradually reduced down to approximately 1/4 of the maximum peak current to prevent from exciting the transformer mechanical resonances. The risk of acoustic noise is thus greatly diminished while keeping good standby power performance.A low power internal supply block also ensures very low current consumption at startup without hampering the standby power performance.A special primary current sensing technique minimizes the impact of SMPS switching on control IC operation. The choice of peak voltage across the current sense resistor allows dissipation to be further reduced. The negative current sensing technique offers advantages over a traditional approach by avoiding the voltage drop incurred by traditional MOSFET source sensing. Thus, the IC drive capability is greatly improved.Finally, the bulk input ripple ensures a natural frequency dithering which smooths the EMI signature.Features•Variable OFF Time Control Method•Very Low Current Consumption at Startup•Natural Frequency Dithering for Improved EMI Signature •Current Mode Control Operation•Peak Current Compression Reduces Transformer Noise •Programmable Current Sense Resistor Peak V oltage •Undervoltage Lockout•These are Pb−Free DevicesTypical Applications•Auxiliary Power Supply•Standby Power Supply•AC−DC Adapter•Off−line Battery Charger8SOIC−8D SUFFIXCASE 75118534(Top View)FBCSNCPIN CONNECTIONS762NCCTGND GateV CCMARKINGDIAGRAMSFAA= Specific Device CodeA= Assembly LocationL= Wafer LotY= YearW= Work WeekG= Pb−Free Package6TSOP−6(SOT23−6, SC59−6)SN SUFFIXCASE 318GFAAYW GG16SOIC−813FBCS2GNDCT4Gate6(Top View)5V CCTSOP−6ORDERING INFORMATIONDevice Package Shipping†NCP1215SNT1G TSOP−6(Pb−Free)3000 Tape & Reel†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our T ape and Reel Packaging Specifications Brochure, BRD8011/D.NCP1215DR2G SOIC−8(Pb−Free)2500 Tape & ReelFigure 1. Typical ApplicationLineN+−*If your application requires a gate −source resistor, please refer to design guidelines in this document.Figure 2. Representative Block DiagramFBCTCSGNDGateV CCPIN FUNCTION DESCRIPTIONTSOP−6SOIC−8Symbol Description41FB The FB pin provides voltage feedback loop. The current injected into the pin determines theprimary switch OFF time interval. It also influences the peak value of the primary current.32CT Connection for an external timing programming capacitor.13CS The CS pin senses the power switch current.24GND Primary and internal ground.65Gate Output drive for an external power MOSFET.56Vcc Power supply voltage and Undervoltage Lockout.77NC Unconnected pin.88NC Unconnected pin.MAXIMUM RATINGSRating Symbol Value Unit Power Supply Voltage V cc18VFB Pins Voltage Range V FB−0.3 to 18V CS and CT Pin Voltage Range V in−0.3 to 10V Thermal Resistance, Junction−to−Air (SOIC−8 Version)R q JA178°C/W Junction Temperature T J150°C Storage Temperature Range T stg−60 to +150°C ESD Voltage Protection, Human Body Model (Except CT Pin)V ESD−HBM 2.0kV ESD Voltage Protection, Human Body Model for CT Pin V ESD−HBM−CT 1.5kV ESD Voltage Protection, Machine Model (Except CT Pin)V ESD−MM200V ESD Voltage Protection, Machine Model for CT Pin V ESD−MM−CT150V Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability.ELECTRICAL CHARACTERISTICS (V CC = 12 V, for typical values T j = 25°C, for min/max values T j = 0°C to +105°C, unless otherwise noted.)Characteristic Symbol Min Typ Max Unit VOLTAGE FEEDBACKOffset Voltage V offset 1.05 1.19 1.34V Maximum CT Pin Voltage at FB Current = 25 m A (Including V offset)V CT−25m A 2.4 3.1 4.3V Maximum CT Pin Voltage at FB Current = 50 m A (Including V offset)V CT−50m A 3.6 4.6 6.2V CT PIN − OFF TIME CONTROLSource Current (CT Pin Grounded)I CT8.09.811.5m A Source Current Maximum Voltage Capability V CT−max− 6.5−V Minimum CT Pin Voltage (Pin Unloaded, Discharge Switch Turned On)V CT−min−−20mV CURRENT SENSEMinimum Source Current (I FB = 180 m A, CT Pin Grounded)I CS−min8.012.516m A Maximum Source Current (I FB = 0 m A, CT Pin Grounded)I CS−max404958m A Comparator Threshold Voltage V th154280mV Propagation Delay (CS Falling Edge to Gate Output)t delay−215310ns GATE DRIVESink Resistance (I sink= 30 mA)R OL254090W Source Resistance (I source= 30 mA)R OH6080130W POWER SUPPLYV CC Startup Voltage V startup−12.514.2V Undervoltage Lockout Threshold Voltage V UVLO7.29.0−V Hysteresis (V startup− V UVLO)V hys 2.2 3.5−V V CC Startup Current Consumption (V CC= 8.0 V)I CC−start− 2.8 6.5m A V CC Steady State Current ConsumptionI CC−SW0.550.9 1.75mA(C GATE= 1.0 nF, f SW= 100 kHz, FB open)TYPICAL CHARACTERISTICS−2511.55011.2250V s t a r t u p , (V )11.0T J , JUNCTION TEMPERATURE (°C)11.6T J , JUNCTION TEMPERATURE (°C)11.111.311.4125V o f f s e t , (V )1.08Figure 3. V startup Threshold vs. JunctionTemperatureFigure 4. V UVLO Threshold vs. JunctionTemperatureFigure 5. Operating Current Consumption vs.Junction TemperatureFigure 6. Offset Voltage vs. JunctionTemperatureT J , JUNCTION TEMPERATURE (°C)Figure 7. Current Sense Source Current vs.Junction TemperatureT J , JUNCTION TEMPERATURE (°C)Figure 8. Current Sense Threshold vs.Junction TemperatureT J , JUNCTION TEMPERATURE (°C)1.121.001.161.2075100−258.7508.4250V U V L O , (V )8.28.88.38.58.612575100−250.985500.97025I C C −S W , (m A )0.9600.990T J , JUNCTION TEMPERATURE (°C)0.9650.9750.98012575100−2550250125751001.041.061.101.141.181.02−2548.05046.525I C S −m a x , (m A )45.549.046.047.047.51257510048.5−25555040250V C S −t h , (m V )30653545501257510060−259.9509.6250I C T, (m A )9.4T J, JUNCTION TEMPERATURE (°C)10.0T J , JUNCTION TEMPERATURE (°C)9.59.79.8125I C S , (m A )Figure 9. CT pin Source Current vs. JunctionTemperatureFigure 10. CT pin Threshold vs. JunctionTemperatureFigure 11. Drive Sink and Source Resistancevs. Junction Temperature Figure 12. Current Sense Source Current vs.Feedback CurrentI fb , FEEDBACK CURRENT (m A)75100−255010250V C T −m i n , (m V )616812141257510010040R s o u r c e −R s i n k , (W )0120T J , JUNCTION TEMPERATURE (°C)206080APPLICATION INFORMATIONThe NCP1215 implements a current mode SMPS with a variable OFF−time dependant upon output power demand. It can be seen from the typical application that NCP1215 is designed to operate with a minimum number of external component. The NCP1215 incorporates the following features:•Frequency Foldback: Since the switch−off time increases when power demand decreases, the switching frequency naturally diminishes in light load conditions. This helps to minimize switching losses and offers excellent standby power performance.•Very Low Startup Current: The patented internal supply block is specially designed to offer a very low current consumption during startup. It allows the use of a very high value external startup resistor, greatly reducing dissipation, improving efficiency and minimizing standby power consumption.•Natural Frequency Dithering: The quasi−fixed T on mode of operation improves the EMI signature since the switching frequency varies with the natural bulk ripple voltage.•Peak Current Compression: As the load becomes lighter, the frequency decreases and can enter the audible range. To avoid exciting transformer mechanical resonances, hence generating acoustic noise, the NCP1215 includes a patented technique, which reduces the peak current as power goes down. As such, inexpensive transformer can be used without having noise problems.•Negative Primary Current Sensing: By sensingthe total current, this technique does not modify the MOSFET driving voltage (Vgs) while switching. Furthermore, the programming resistor together with the pin capacitance, forms a residual noise filter which blanks spurious spikes. Also fixing primary current level to a maximum value sets the maximum power limit.•Programmable Primary Current Sense: It offers a second peak current adjustment variable which improves the design flexibility.•Secondary or Primary Regulation: The feedback loop arrangement allows simple secondary or primary side regulation without significant additional external components.A detailed description of each internal block within the IC is given in the following.Feedback Loop ControlThe main task of the Feedback Loop Block is to control the SMPS output voltage through the change of primary switch OFF time interval. It sets the peak voltage of the timing capacitor, which varies upon the output power demand. Figure 13 shows the simplified internal schematic: Figure 13. Feedback Loop − OFF Time ControlFBTo OFFTimeVThe voltage feedback signal is sensed as a current injected through the FB pin.Figure 14. FB Loop Transfer CharacteristicOFF−TimeComparatorInputVoltageV DDV offset0 mThe transfer characteristic (output voltage to input current) of the feedback loop control block can be seen in Figure 14. V DD refers to the internal stabilized supply whereas the offset value sets the maximum switching frequency in lack of optocoupler current (e.g. an output short−circuit).To keep the switching frequency above the audio range in light load condition the FB pin also regulates in certain range the peak primary current. The corresponding block diagram can be seen from Figure 15.Figure 15. Feedback Loop − Current Sense ControlFBCSThe resulting current sense regulation characteristic can be seen from Figure 16.Figure 16. Current Sense Regulation CharacteristicC S P i n S o u r c e C u r r e n t12.5 m 50 m 0 m FB Pin Sink CurrentWhen the load goes light, the compression circuitry decreases the peak current. This has the effect of slightly increasing the switching frequency but the compression ratio is selected to not hamper the standby power.OFF Time ControlThe loop signal together with the internal current source,via an external capacitor, controls the switch −off time. This is portrayed in Figure 17.Figure 17. OFF Time ControlFrom Feedback Loop BlockDuring the switch −ON time, the CT capacitor is kept discharged by a MOSFET switch. As soon as the latch output changes to a low state, the voltage across CT created by the internal current source, starts to ramp −up until its value reaches the threshold given by the feedback loop demand.Figure 18. CT Pin Voltage (P out 1 u P out 2 u P out 3)V offsetV DDVCT Pin Voltageoff −minThe voltage that can be observed on CT pin is shown in Figure 18. The bold waveform shows the maximum output power when the OFF time is at its minimum. The IC allows an OFF time of several seconds.Primary Current SensingThe primary current sensing circuit is shown in Figure 19.Figure 19. Primary Current SensingWhen the primary switch is ON, the transformer current flows through the sense resistor R cs . The current creates a voltage, V cs which is negative with respect to GND. Since the comparator connected to CS pin requires a positive voltage, the voltage V shift is developed across the resistor R shift by a current source which level −shifts the negative voltage V cs . The level −shift current is in range from 12.5 to 50 m A depending on the Feedback Loop Control block signal (see more details in the Feedback Loop Control section).The peak primary current is thus equal to:I pk +Rshift R CS·I CS(eq. 1)A typical CS pin voltage waveform is shown in Figure 20.Figure 20. CS Pin VoltageTurn −onVFigure 20 also shows the effect of the inductor current of differing output power demand.The primary current sensing method we described, brings the following benefits compared to the traditional approach:•Maximum peak voltage across the current sense resistor is determined and can be optimized by the value of the shift resistor.•CS pin is not exposed to negative voltage, which could induce a parasitic substrate current within the IC and distort the surrounding internal circuitry.•The gate drive capability is improved because the current sense resistor is located out of the gate driver loop and does not deteriorate the turn −on and also turn −off gate drive amplitude.Gate DriverThe Gate Driver consists of a CMOS buffer designed to directly drive a power MOSFET.It features an unbalanced source and sink capabilities to optimize turn ON and OFF performance without additional external components. Since the power MOSFET turns −off at high drain current, to minimize its turn −off losses the sink capability of the gate driver is increased for a faster turn −off.To the opposite, the source capability is lower to slow −down power MOSFET at turn −on in order to reduce the EMI noise.Whenever the IC supply voltage is lower than the undervoltage threshold, the Gate Driver is low, pulling down the gate to ground. It eliminates the need for an external resistor.Startup CircuitAn external startup resistor is connected between high voltage potential of the input bulk capacitor and Vcc supply capacitor. The value of the resistor can be calculated as follows:R startup +V bulk *V startupI startup(eq. 2)Where:V startupV cc voltage at which IC starts operation (see spec.)I startup Startup current V bulk Input bulk capacitor’s voltageSince the V bulk voltage has obviously much higher value than V startup the equation can be simplified in the following way:R startup +V bulkI startup (eq. 3)The startup current can be calculated as follows:I startup +C Vcc V startupt startup)I CC −start(eq. 4)Where:C Vcc Vcc capacitor value t startup Startup timeI CC −startIC current consumption (see spec.)If the IC current consumption is assumed constant during the startup phase, one can obtain resulting equation for startup resistor calculation:R startup +V bulkC VccV startup t startup)I CC −start(eq. 5)Switching FrequencyThe switching frequency varies with the output load and input voltage. The highest frequency appears at highest input voltage and maximum output power.Since the peak primary current is fixed, the on time portion of the switching period can be calculated:t on +L pI pkV bulk(eq. 6)Where:L p Transformer primary inductance I pk Peak primary currentUsing equation for peak primary current estimation the switch −on time is:t on +L p R shiftR cs ·V bulk50·10−6(eq. 7)Minimum switch −on time occurs at maximum input voltage:t on −min +L p R shiftR cs ·V bulk −max50·10−6(eq. 8)As it can be seen from the above equation, the switch −on time linearly depends on the input bulk capacitor voltage.Since this voltage has ripple due to AC input voltage and input rectifier, it allows natural frequency dithering to improve EMI signature of the SMPS.The switch −off time is determined by the charge of an external capacitor connected to the CT pin. The minimum Toff value can be computed by:t off −min +C T Voffset I Ct +C T 1.210−5(eq. 9)+0.12·106C TWhere:V offset Offset voltage (see spec.)I Ct CT pin source current (see spec.)The maximum switching frequency then can be evaluated by:(eq. 10)f sw −max +1t on −min )t off −min+1L p ·R shiftV bulk ·R cs·50·10−6)0.12·106·C TAs output power diminishes, the switching frequency decreases because the switch −off time prolongs upon feedback loop. The range of the frequency change is sufficient to keep output voltage regulation in any light load condition.Application Design ExampleAn example of the typical wall adapter application is described hereafter.As a wall adapter it should be able to operate properly with wide range of the input voltage from 90 V AC up to 265 V AC.The bulk capacitor voltage then can be calculated:(eq. 11)V bulk −min +V AC −min 2Ǹ+90·2Ǹ+127VDC(eq. 12)V bulk −max +V AC −max 2Ǹ+265·2Ǹ+375VDCThe requested output power is 5.2 Watts.Assuming 80% efficiency the input power is equal to:(eq. 13)P in +P out h +5.20.8+6.5WThe average value of input current at minimum input voltage is:(eq. 14)I in −avg +P inVbulk −min+6.5127+51.2mA The suitable reflected primary winding voltage for 600 Vrated MOSFET switch is:(eq. 15)V flbk +600V *V bulk −max *V spike+600*375*100+125VUsing calculated flyback voltage the maximum duty cycle can be calculated:(eq. 16)d max +V flbkV flbk )V bulk −min +125125)127+0.496+0.5Following equation determines peak primary current:(eq. 17)I ppk +2·I in −avg d max+2·51.2·10−30.5+204.7mAThe desired maximum switching frequency at minimum input voltage is 75 kHz.The highest switching frequency occurs at the highest input voltage and its value can be estimated as follows:(eq. 18)f max −high +f max −lowV bulk −maxV bulk −min dmax +75·1033751270.5+110.7kHzThis frequency is much below 150 kHz, so that the desired operating frequency can be exploited for further calculation of the primary inductance:(eq. 19)L p +V bulk −min ·d maxI ppk ·f sw −max +127·0.50.2047·75·103+4.14mH分销商库存信息:ONSEMINCP1215DR2NCP1215SNT1NCP1215DR2G。

1215材质证明1215材质是一种常见的铝合金材料，由铝、铜、镁和锌等元素组成。

它具有优良的机械性能、耐腐蚀性能和加工性能，广泛应用于航空航天、汽车制造、建筑工程等领域。

下面将从材质组成、机械性能、耐腐蚀性能和加工性能等方面进行详细阐述和证明。

首先，1215材质的主要成分是铝、铜、镁和锌等元素。

铝为主要元素，占总质量的90%以上，具有轻质、高强度、优良的导热性能和电导性能等特点。

铜为增强材料，能够提高材料的强度和硬度，并且具有良好的导热性和导电性。

镁和锌是合金元素，可以固溶在铝中，能够改善铝的机械性能和耐腐蚀性能。

因此，1215材质的成分设计合理，具有较好的综合性能。

其次，1215材质具有优良的机械性能。

它的抗拉强度在220-280MPa之间，屈服强度在170-200MPa之间，延伸率在9-12%之间。

这些机械性能使得1215材质在受力时不易发生塑性变形和断裂。

此外，1215材质的硬度较低，可通过热处理和冷变形等方法进行调整，以满足不同领域的需求。

第三，1215材质具有良好的耐腐蚀性能。

铝在空气中形成一层致密的氧化膜，能够有效防止进一步的氧化反应，从而具有良好的耐腐蚀性。

此外，镁和锌的加入能够形成间金属相，进一步提高材料的耐蚀性。

实验结果表明，1215材质在常见的酸碱溶液和腐蚀介质中具有良好的稳定性和耐蚀性。

最后，1215材质具有良好的加工性能。

由于铝具有优良的塑性，1215材质易于加工成各种形状，如板材、管材、型材等。

其低熔点、高热导性和良好的切削性能使得1215材质易于切削、冷加工和热成型等加工过程。

此外，1215材质还可以通过铸造和轧制等方法进行加工，并可根据需要进行热处理，以获得理想的性能。

综上所述，1215材质的成分设计合理，具有优良的机械性能、耐腐蚀性能和加工性能。

这些特点使得1215材质在航空航天、汽车制造、建筑工程等领域得到了广泛的应用和认可。