USB Power Delivery Advanced protection solutions Fundamentals Is this presentation suited for you? Where do you stand with USB Power Delivery? Beginner? Intermediate? Advanced? I am not familiar with this subject. I am in the discovery phase and would like an overview and a basic understanding of the technology. I have a basic understanding of this subject. I would like to go deeper in details and tackle more aspects of this subject. I am very familiar with this subject. I would like to deepen my knowledge and become an expert. Click here to continue to next slide Click here to continue to next slide Click here to continue to next slide Overview Fundamentals In depth 2 Power over USB • The success of the USB Battery Charging standard for mobile devices demonstrated the need for a standardized connector to power small devices. • To power up bigger devices like SSD/HDD, laptops or even screens, it is necessary to reach power up to 100 W. 3 A new specification • The USB Power Delivery specification V1.1 was released on May 7, 2015 to address these needs. • This specification is an extension to the existing USB 2.0, USB 3.1, USB Type-C and Battery Charging specifications covering only the elements required to implement USB Power Delivery. 4 Profiles • 6 power profiles are defined extending the supply voltages (profile 0 is reserved) • This requires new cables withstanding voltages higher than 5 V and currents higher than 1.5 A. • Profile 4 is the limit for the micro-B/AB connector. Profile 5V 12 V 20 V 1 2 3 4 5 1.5 A, 18 W 2.0 A, 10 W 3.0 A, 36 W 5.0 A, 60 W 3.0 A, 60 W 5.0 A, 100 W 5 VBUS voltage and current • Sources with 100 W operation capability must meet various worldwide safety standards. As such, the continuous output power cannot exceed 100 W and the continuous output current cannot exceed 5 A. Interpretation of the safety requirements imposed by IEC/UL 60950 5 3 1 2 4 Profile 1 : up to 1 Profile 2: up to 1 2 Profile 3: up to 1 3 Profile 4: up to 1 3 4 Profile 5: up to 1 3 5 6 More power means more protection • With USB power capability increasing, the risks of surges and transients must be properly mitigated. • Portable devices often implement miniature ICs using the thinnest - and more vulnerable technologies. • The power sources are not controlled by the portable device manufacturers, so the need to protect power ports is obvious. Two types of hazards: • ESD hazards • Lightning and industrial surges 7 ESD protection needed … Advanced technology with very thin lithography and gate oxide highly vulnerable to ESD Integrated electronics systems with high component-density PCBs facilitating ESD coupling and propagation USB transceivers, controllers … IC manufacturers reluctant to use robust embedded ESD protection diodes that would require a significant active area of their advanced and expensive technology. 8 And surge protection too Experiments and measurements have demonstrated that the current waveform of a lightning strike or switching noise has a rise time close of 8 µs to reach the peak. ==> The IEC/UL 61000-4-5 has provided a standardized current waveform called 8/20 µs waveform modeling lightning stresses or switching noise. The key performance factor for a VBUS protection is the clamping voltage versus 8/20 µs surges (IEC/UL 61000-4-5 standard) 9 A wide portfolio ESD PROTECTION IEC/UL 61000-4-2 Level 4 (+8 kV contact) VBUS SMALLEST 10 ESD & EOS PROTECTION + EN 55024 / CISPR 24 (IPP 8/20µs > 59 A) + IEC/UL 61000-4-5 HIGH POWER DENSITY STRONGEST Typ. 20 V ESDALC20-1BF4 SMM4F24A VCL @ 30 ns = 37 V IPP = 2.4 A, PPP = 90 W VCL 8/20 µs = 58 V IPP = 60 A, PPP = 2300 W SMM4F13A 12 V VCL 8/20 µs = 24 V IPP = 85 A, PPP = 2300 W ESDALC14-1BF4 9V VCL @ 30 ns = 18 V IPP = 5 A, PPP = 100 W ESDA5-1BF4 5V VCL @ 30 ns = 11 V IPP = 10 A, PPP = 110 W 0201 ESDA13P70-1U1M VCL 8/20 µs = 20 V IPP = 70 A, PPP = 1300 W ESDA7P60-1U1M VCL 8/20 µs = 12 V IPP = 60 A, PPP = 700 W VCL 8/20 µs = 20 V IPP = 100 A, PPP = 2200 W SMM4F6.0A VCL 8/20 µs = 10 V IPP = 170 A, PPP = 2300 W STmiteFLAT 1610 0.3 mm SMM4F12AVCL 0.55 mm Package & Size 0.85 mm Zoom on ESDA7P60-1U1M Small but robust • • 100 IPP (A) Can withstand 30 kV contact discharge ESD strikes A high transient current (IPP 60 A for 8/20 µs) in a small 1.6 mm² package . Low VCL 10 Max clamping voltage VCL 1 11.6 V at 60A USB transceiver is safe! • This product is able to keep the overvoltage at 11.6 V while shunting 60 A to the GND. 1610 package VCL(V) 0.1 6 10 12 Constant PPP guaranteed over T° Strong even at high temperature • 8 Peak pulse power guaranteed up to 150 °C. 1000 PPP (W) 750 Electrical parameters Symbol Test Condition 8/20 µs Min PPP= 700 W 500 Min. Typ. Max. Units 6.4 6.8 7.2 200 V 250 VBR IR = 1 mA IRM VRM = 5 V nA Tj( C) 0 25 50 75 100 125 150 175 11 Let’s go further Overview information Fundamentals In-depth information Selection & sampling 12 USB type-C™ advanced protection quick start guide USB2.0 protection and IPADTM solutions presentation USB type-C™ dataline advanced protection presentation IEC 61000-4-5 standard overview Application note #AN4275 ESD - IEC 61000-4-2 standard testing Application note #AN3353 TVS short pulse dynamic resistance measurement ... Application note #AN4022 Protection devices & integrated EMI filtering selection guide USB port protection web product selector USB IPAD™ (including ECMF™) web product selector Thank you