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NCV887601BSTGEVB - Evaluation Board Test Designer https://explore.partquest.com/node/87851 <iframe allowfullscreen="true" referrerpolicy="origin-when-cross-origin" frameborder="0" width="100%" height="720" scrolling="no" src="https://explore.partquest.com/node/87851"></iframe> Title Description <p>This design is a “Virtual Evaluation Board”. It represents the physical evaluation board for the NCV8876 Automotive Start-Stop Boost Controller IC, which is available from ON Semiconductor here:</p><p>http://www.onsemi.com/PowerSolutions/evalBoard.do?id=NCV887601BSTGEVB,</p><p>The schematic includes all of the components on the evaluation board, as well as user specified external test apparatus. The user can perform virtual testing on the NCV8876 component, to gain a better understanding of its features and behavior. Please see the related blog article, which describes this component's application and benefits:</p><p>https://www.systemvision.com/blog/automotive-start-stop-%E2%80%A6-keep-lights-june-13-2016</p><p>Simulation results show the output to the load during a fast battery drop-out and recovery. Note that in this particular test set-up, the output voltage (red waveform) is maintained above 6.3V during the drop-out transient, and regulates at 6.8V during sustained low voltage operation (2.6V, blue waveform).</p><p>Also shown are the current in the N-channel Power MOSFET (brown waveform), and the current in the Vishay-Dale soft-saturation inductor (purple waveform). For this boost application, the soft-saturation behavior helps prevent inductance collapse during brief over-current conditions. The datasheet for the IHLP5050FDER2R2M01 can be found here: </p><p>http://www.vishay.com/docs/34123/ihlp5050fd01.pdf</p><p>Note that the user can move the waveform probes around to see the voltage waveform on any other nets (i.e. “wires”), or the current, power and other signals inside any component. The user can also make a copy of this design and freely change any of the component values, then rerun the simulation and see the effect of those changes.</p> About text formats Tags Start-StopboostSoft SaturationNCV8876Evaluation BoardNCV887601BSTGEVB Select a tag from the list or create your own.Drag to re-order taxonomy terms. License - None -
NCV8876 - Overcurrent Protection Designer https://explore.partquest.com/node/79321 <iframe allowfullscreen="true" referrerpolicy="origin-when-cross-origin" frameborder="0" width="100%" height="720" scrolling="no" src="https://explore.partquest.com/node/79321"></iframe> Title Description <p>This example demonstrates the overcurrent protection capabilities of the ON Semiconductor NCV8876. It complements the design: https://www.systemvision.com/design/ncv8876-automotive-start-stop-boost-controller, which shows the performance of the device in normal operation. But in this design, the inductor element proves inadequate for boost operation under a heavy load condition. Inductance collapse, caused by core saturation, could lead to damaging peak current levels in multiple electronic components, were it not for the “hiccup-mode” overcurrent protection feature of the NCV8876.</p><p>Simulation results show that the boost output voltage (dark blue waveform) falls to approximately 5V when the battery voltage (orange waveform) drops to 6V. This is in contrast to the nominal circuit operation, in which the NCV8876 would enter boost control mode and maintains a 6.8V boost output level. But because of the low drop-out voltage of the NCV59302 VLDO, the 5V regulated output voltage is only slightly reduced. The current through the 2.3 Ohm load resistor is maintained at just under 2.2A throughout the entire operation.</p><p>While this load level is within the current rating of the inductor (2.3A RMS Max.), it is approaching the saturation inductance “cliff” for this traditional (i.e. non-soft-saturating) part. So when the NCV8876 activates boost control, it switches on the Power MOSFET briefly, effectively grounding the low side of the inductor through the small current sense resistance (0.03 Ohms). With the nominal 3.3uH inductance value, this would result in a slow current build-up (V/L = di/dt = 6V/3.3uH = 1.8A/us). But in this case the inductance collapses with further current increase, and the di/dt value becomes very large. The inductor current spikes to well over 10A (light blue waveform), and the corresponding inductance crashes to a small fraction of its nominal value (green waveform).</p><p>The current spikes could have gone much higher, possibly resulting in damage to the NVGS3130 Power MOSFET, which has a rated pulse current maximum of 19A. If you zoom in on the magenta waveform, you'll see the Ids current rising, slowly at first while the inductance is intact, but then rapidly rising to over 11A as the inductance collapses, all in just 100ns! Fortunately the gate voltage (brown waveform) is cut off to prevent further current rise. This is thanks to the overcurrent protection feature of the NCV8876. When an overcurrent condition is detected, the device immediately goes into “hiccup-mode”, in which the gate drive is turned off and remains off for a count of 1024 clock cycles. After the mandatory hiccup period, the NCV8876 reattempts boost operation, but with continued overcurrent monitoring. Note that the current spikes are repeated with just over a 2ms period, because the clock is programmed to just over 2 us period (450 kHz switching frequency) in this design.</p><p>To learn more about the capabilities of the ON Semiconductor NCV8876, click here: http://www.onsemi.com/pub_link/Collateral/NCV8876-D.PDF</p><p>To learn more about the benefits of Coilcraft's molded core soft saturation technology for reducing problems with current spikes, see page 4 of this document: http://www.coilcraft.com/pdfs/Doc1140_Beyond_the_data_sheet_Part1.pdf</p> About text formats Tags Start-StopboostSoft SaturationNCV8876overcurrenthiccup mode Select a tag from the list or create your own.Drag to re-order taxonomy terms. License - None -
