Tighten Supply Regulation for 2A USB Devices by Dynamically Compensating for Voltage Drops in Wiring and Connectors Design Note 1029 Tom Hack Introduction These days, the Universal Serial Bus (USB) is commonly used to power tablet computers and high rate cell phone battery chargers—applications never envisioned at the inception of the USB standard in the mid-1990s. The USB standard has changed significantly over this time. For instance, USB 3.0 requires up to 900mA (six, 150mA unit loads) during high bandwidth communication. A dedicated charging port can supply as much as 1.8A. of 12V. To simplify the schematic, the protection circuitry for load dump, reverse battery, 2-battery jump, spikes and noise are not shown (consult Linear Technology’s “Automotive Electronics Solutions” brochure for further information.) The nominal switching frequency is set above 455kHz to avoid interference in the IF of various RF devices. It can be raised to 2MHz to avoid interfering with AM and Travelers Information Station broadcasts, but at the expense of some power supply efficiency. Such high, and highly variable, load currents can produce significant and unpredictable voltage drops in wiring and connectors, lowering the performance of the device. Virtual remote sensing senses losses in the line in real time, automatically adapting to changes in load current, line resistance, connector aging and temperature variation. The result is improved voltage regulation and increased device reliability. This design corrects for total wiring and connector resistances of 0.1Ω to 0.4Ω and load currents from zero to 2A. Thirty randomly selected LT4180 virtual remote sense devices were tested in this design with wiring and connector resistances of 0.1Ω, 0.2Ω, and 0.4Ω, and zero to 2A load currents. With 0.1Ω USB cable and connector resistance, none of the thirty devices exhibited more than ±3% variation from nominal output voltage. For total resistances of 0.2Ω and 0.4Ω, the worst-case variation in output voltage for all load current and devices never exceeded ±3.4% and ±4.6%, respectively. Virtual Remote Sensing (VRS) Power Supply Figure 1 shows a 2A USB power supply for automotive applications using a buck switching regulator and the LT4180 virtual remote sense controller. The power supply produces a 5V, 2A output from a nominal input voltage L, LT, LTC, LTM, Linear Technology, the Linear logo and µModule are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. USB CABLE AND CONNECTORS VIN 12V + 4.7µF 50V 22µF 50V GND 100k RUN ON JP1 OFF 0.47µF 3 2 1 0.1µF 50V INTVCC 30.1k 1% 10k 1% 0.033Ω 1% VIN BD BOOST SW RUN/SD PG FB RT 68.1k 1% 47µF 10V UI LT3693EDD SYNC 6.8µH 47µF 10V INTVCC VC CMDSH-3 100k RUN VIN SENSE 2.15k 1% DIV2 DIV1 1µF 100k VPP DIV0 INTVCC SPREAD 47pF TP1 OSC OV OSC DRAIN COMP GND CHOLD1 GUARD2 CHOLD2 GUARD3 CHOLD3 GUARD4 CHOLD4 COSC ROSC 47nF 470pF 330pF 470pF 4.7nF Figure 1. A 2A USB Automotive Power Supply Using Virtual Remote Sensing 02/13/1029 470µF USB 10V POWERED DEVICE LT4180EGN 1k 23.2k 1% + INTVCC 1.87k 1% 5.36k 1% 470µF 10V 1µF 21.5k 1% FB MBRA340T3G + RWIRE = 0.1Ω TO 0.4Ω 22.1k 1% 47nF dn F01 RCOMP improves load regulation to approximately ±3.2%. 2 Results vary depending on how well RCOMP matches the resistance of the cable between the USB power device and the decoupling network (RCOMP/CLOAD). Any capacitance internal to the USB powered device (if it becomes a significant fraction of CLOAD) may also degrade the results. 1 0 –1 RANGE OF REGULATION OVER 30 PARTS –2 –3 0.5 0 1.0 1.5 LOAD CURRENT (A) 2.0 dn F02 Figure 2. Worst-Case Load Regulation with RWIRE = 0.1Ω % DEVIATION (VOUT) 4 2 0 RANGE OF REGULATION OVER 30 PARTS –2 –4 One final note: adding RCOMP reduces the filtering effectiveness of CLOAD, resulting in increased power supply ripple. Conclusions Virtual remote sensing significantly improves load regulation in USB products where unknown wiring resistances would otherwise degrade regulation at the device. By dynamically adapting to changes in load current, line resistance, connector aging and temperature variation, voltage tolerances are improved, ensuring consistent and reliable operation. VRS POWER SUPPLY 0 0.5 1.0 1.5 LOAD CURRENT (A) USB A USB A RECEPTACLE PLUG CONNECTOR DECOUPLING CAPACITOR IN USB RECEPTACLE 2.0 dn F03 Figure 3. Worst-Case Load Regulation with RWIRE = 0.2Ω Adding VRS to Existing Devices and Designs Virtual remote sensing requires an AC short at the regulation point for best results, which may not be feasible in some existing designs. For example, in Figure 4, a typical USB device is connected directly to the power supply shown in Figure 1. In this case, regulation is maintained up to the USB A receptacle, but the supply cannot correct for additional voltage drops beyond this point. Fortunately, the simple trick shown in Figure 5 removes most of this error. By adding a resistor, RCOMP, in series with the decoupling capacitor, CLOAD, the voltage at the USB A receptacle rises with increasing load current, thus compensating for any additional voltage drop in the USB device caused by increasing load current. Figure 6 shows typical results with 0.2Ω USB cable resistance, and 0.1Ω USB device cable resistance. The connector uses two 470µF capacitors (for a total CLOAD equal to 940µF) in series with RCOMP = 0.1Ω. Without RCOMP, load regulation would be about ±5.2%. Adding Data Sheet Download www.linear.com/4180 Linear Technology Corporation USB POWERED DEVICE USB CABLE dn F04 CANNOT CORRECT THIS VOLTAGE DROP Figure 4. Incomplete Wiring Drop Correction CONNECTOR WITH USB USB CABLE BUILT-IN DECOUPLING DEVICE CABLE POWER SUPPLY + RCOMP USB POWERED DEVICE CLOAD dn F05 Figure 5. Correcting for Downstream Wiring Voltage Drops 4 % DEVIATION (VOUT) % DEVIATION (VOUT) 3 2 0 –2 –4 0 0.5 1.0 1.5 LOAD CURRENT (A) 2.0 dn F06 Figure 6. Typical Load Regulation at the USB Powered Device Depicted in Figure 5 For applications help, call (408) 432-1900, Ext. 3231 dn1029f LT 0213 • PRINTED IN THE USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com LINEAR TECHNOLOGY CORPORATION 2013