[{"data":1,"prerenderedAt":1543},["ShallowReactive",2],{"latest-content-es":3},{"news":4,"blogs":561},[5,262],{"id":6,"title":7,"author":8,"body":9,"cover":22,"date":251,"description":252,"excerpt":253,"extension":254,"meta":255,"navigation":256,"path":257,"seo":258,"stem":259,"__hash__":260,"slug":261},"news\u002Flocales\u002Fes\u002Fnews\u002Fmurata-1250v-c0g-mlcc-for-sic.md","Murata lanza el primer MLCC C0G 1,25kV en formato 1210 — condensador cerámico 15nF para diseños SiC MOSFET","Movthing Technical Team",{"type":10,"value":11,"toc":248},"minimark",[12,23,57,98,129,154,243],[13,14,15],"images",{},[16,17,18],"p",{},[19,20],"img",{"alt":21,"src":22},"Murata MLCC C0G Alta Tensión","\u002Fimages\u002Fnews\u002Fmurata-1250v-c0g-mlcc-for-sic\u002Fheader.webp",[24,25,26,29],"paragraph",{},[16,27,28],{},"Descripción del Producto",[30,31,33,48],"template",{"v-slot:description":32},"",[34,35,36],"card",{},[16,37,38,39,43,44,47],{},"El 2 de diciembre de 2025, ",[40,41,42],"strong",{},"Murata Manufacturing Co., Ltd."," anunció el desarrollo e inicio de producción del primer ",[40,45,46],{},"MLCC de 1210inch (3,2×2,5mm) con tensión nominal de 1,25kV, característica C0G y 15nF de capacidad"," del mundo. Diseñado específicamente para cargadores embarcados (OBC) y circuitos de potencia de alto rendimiento, este MLCC está optimizado para topologías de conmutación de alta tensión basadas en SiC MOSFET.",[34,49,50],{},[16,51,52,53,56],{},"Es la primera vez que Murata combina 1,25kV con característica C0G en un encapsulado 1210. Anteriormente, productos C0G de alta tensión comparables requerían encapsulados más grandes como 1812 o 2220. El dispositivo 1210 de 15nF reduce significativamente la huella en PCB. La línea cubre ",[40,54,55],{},"4,7nF a 15nF"," con tolerancia de ±1% a ±5% y rango de temperatura de -55°C a +125°C.",[24,58,59,62],{},[16,60,61],{},"Análisis Técnico — Por qué los SiC MOSFET necesitan este condensador",[30,63,64,77,89],{"v-slot:description":32},[34,65,66],{},[16,67,68,69,72,73,76],{},"En OBCs y convertidores DC-DC de alta tensión, los interruptores de potencia están migrando de Si MOSFET tradicionales a ",[40,70,71],{},"SiC MOSFET",". Los dispositivos SiC conmutan más rápido (dV\u002Fdt superior a 100V\u002Fns) con menores pérdidas de conducción, pero exigen condensadores resonantes y snubber capaces de soportar tensiones superiores a ",[40,74,75],{},"1,2kV"," manteniendo capacidad estable y baja ESR a temperaturas elevadas.",[34,78,79],{},[16,80,81,84,85,88],{},[40,82,83],{},"C0G (NP0)"," es el dieléctrico MLCC más estable disponible, con un coeficiente de temperatura de solo ±30ppm\u002F°C — la capacidad permanece prácticamente constante ante variaciones de temperatura y tensión. Esto es crítico para circuitos resonantes: la frecuencia de un convertidor LLC depende de una capacidad resonante precisa, y cualquier deriva causa pérdida de eficiencia y aumento de EMI. La ",[40,86,87],{},"bajísima pérdida"," (DF \u003C 0,1%) de C0G ofrece ventajas significativas en aplicaciones de conmutación de alta frecuencia.",[34,90,91],{},[16,92,93,94,97],{},"Murata logró este avance mediante su tecnología patentada de ",[40,95,96],{},"adelgazamiento de cuerpo cerámico y electrodos internos",", colocando suficientes capas de electrodos en el encapsulado 1210 para alcanzar 15nF manteniendo 1,25kV de tensión de ruptura — una hazaña de fabricación excepcionalmente exigente.",[24,99,100,103],{},[16,101,102],{},"Análisis de Aplicaciones",[30,104,105,113,121],{"v-slot:description":32},[34,106,107],{},[16,108,109,112],{},[40,110,111],{},"Circuitos resonantes OBC",": Los OBC de 6,6kW y 11kW utilizan topologías resonantes LLC o CLLC. El condensador resonante debe soportar altas tensiones y corrientes de pico manteniendo una capacidad precisa. El MLCC C0G de 1,25kV\u002F15nF puede reemplazar condensadores de película tradicionales con menor tamaño y mayor fiabilidad.",[34,114,115],{},[16,116,117,120],{},[40,118,119],{},"Circuitos snubber SiC",": El apagado de SiC MOSFET genera di\u002Fdt extremadamente alto con picos de tensión de drenaje superiores a 1kV. Los condensadores snubber deben satisfacer simultáneamente alta tensión, bajas pérdidas y estabilidad térmica. Los MLCC C0G con ESR ultra-bajo y alta capacidad dV\u002Fdt son ideales para snubbers RCD.",[34,122,123],{},[16,124,125,128],{},[40,126,127],{},"Convertidores DC-DC de alta tensión",": En plataformas de batería de 800V, los módulos DC-DC requieren condensadores de alta tensión para filtrado y resonancia. La característica C0G asegura capacidad estable en todo el rango de -55°C a +125°C.",[24,130,131,134],{},[16,132,133],{},"Impacto en la Cadena de Suministro",[30,135,136,145],{"v-slot:description":32},[34,137,138],{},[16,139,140,141,144],{},"Los MLCC C0G de alta tensión son productos de alto valor y alta barrera tecnológica. El dispositivo C0G 1,25kV en 1210 es ",[40,142,143],{},"actualmente exclusivo de Murata",", por lo que el suministro inicial será limitado. Los equipos de compras con proyectos OBC y DC-DC deben establecer canales de comunicación con Murata o distribuidores autorizados.",[34,146,147],{},[16,148,149,150,153],{},"Como alternativas, si el tamaño 1210 no es obligatorio, considere la serie C de alta tensión C0G de TDK (generalmente en 1812 o mayor) o la serie CL de alta tensión de Samsung. Sin embargo, actualmente ",[40,151,152],{},"no hay competidor directo"," para el 1,25kV C0G 15nF en 1210 — las alternativas requerirán rediseño de layout PCB.",[24,155,156,159],{},[16,157,158],{},"Especificaciones Clave",[30,160,161,238],{"v-slot:description":32},[34,162,163],{},[164,165,166,179],"table",{},[167,168,169],"thead",{},[170,171,172,176],"tr",{},[173,174,175],"th",{},"Parámetro",[173,177,178],{},"Especificación",[180,181,182,191,199,207,214,222,230],"tbody",{},[170,183,184,188],{},[185,186,187],"td",{},"Tamaño",[185,189,190],{},"1210inch (3,2×2,5mm)",[170,192,193,196],{},[185,194,195],{},"Característica Térmica",[185,197,198],{},"C0G (estándar EIA)",[170,200,201,204],{},[185,202,203],{},"Temperatura Operación",[185,205,206],{},"-55°C a +125°C",[170,208,209,212],{},[185,210,211],{},"Rango de Capacidad",[185,213,55],{},[170,215,216,219],{},[185,217,218],{},"Tolerancia",[185,220,221],{},"±1% a ±5%",[170,223,224,227],{},[185,225,226],{},"Tensión Nominal (DC)",[185,228,229],{},"1.250Vdc",[170,231,232,235],{},[185,233,234],{},"Aplicaciones",[185,236,237],{},"OBC resonante, snubber SiC, DC-DC AT",[34,239,240],{},[16,241,242],{},"C0G significa que este dispositivo ofrece estabilidad excepcional en temperatura, DC bias y tiempo. A diferencia de X7R\u002FX5R, la capacidad C0G prácticamente no experimenta derating por DC bias — los ingenieros pueden usar el valor nominal sin aplicar factores de reducción.",[34,244,245],{},[16,246,247],{},"El primer MLCC C0G 1,25kV en 1210 de Murata llena un vacío de miniaturización en condensadores resonantes de alta tensión para OBCs de media potencia. Con la aceleración de plataformas 800V y dispositivos SiC, los MLCC C0G de alta tensión serán componentes esenciales en OBCs y convertidores DC-DC. Movthing sigue las tendencias tecnológicas y la dinámica de suministro de MLCC de alta tensión. Contacte a nuestro equipo de ingeniería para muestras o soporte técnico.",{"title":32,"searchDepth":249,"depth":249,"links":250},2,[],"2026-04-29","Murata inicia la producción del primer MLCC 1210 (3,2×2,5mm) 1,25kV C0G 15nF de la industria, diseñado para circuitos resonantes OBC y convertidores SiC.",null,"md",{},true,"\u002Flocales\u002Fes\u002Fnews\u002Fmurata-1250v-c0g-mlcc-for-sic",{"title":7,"description":252},"locales\u002Fes\u002Fnews\u002Fmurata-1250v-c0g-mlcc-for-sic","Yd_GBD4A9n29X79uFyD2dqZsL85gqG2BiBHjj2fOSec","murata-1250v-c0g-mlcc-for-sic",{"id":263,"title":264,"author":8,"body":265,"cover":274,"date":251,"description":554,"excerpt":253,"extension":254,"meta":555,"navigation":256,"path":556,"seo":557,"stem":558,"__hash__":559,"slug":560},"news\u002Flocales\u002Fes\u002Fnews\u002Fmurata-expands-automotive-mlcc-2026.md","Murata amplía su gama de MLCC automotrices — 7 nuevos modelos para la miniaturización de AD\u002FADAS",{"type":10,"value":266,"toc":552},[267,275,332,357,374,402,547],[13,268,269],{},[16,270,271],{},[19,272],{"alt":273,"src":274},"Murata MLCC Automotriz","\u002Fimages\u002Fnews\u002Fmurata-expands-automotive-mlcc-2026\u002Fheader.webp",[24,276,277,280],{},[16,278,279],{},"Descripción General del Producto",[30,281,282,302,315],{"v-slot:description":32},[34,283,284],{},[16,285,286,287,289,290,293,294,297,298,301],{},"El 8 de abril de 2026, ",[40,288,42],{}," anunció el inicio de la producción en masa de ",[40,291,292],{},"7 nuevos modelos de MLCC automotrices",". Se dividen en dos categorías: ",[40,295,296],{},"MLCC de baja tensión nominal"," (2,5–4Vdc) para circuitos periféricos de IC AD\u002FADAS, y ",[40,299,300],{},"MLCC de media tensión nominal"," (25Vdc) para líneas de alimentación, en tamaños desde 0201inch (0603mm) hasta 1210inch (3225mm).",[34,303,304],{},[16,305,306,307,310,311,314],{},"El modelo insignia de baja tensión ",[40,308,309],{},"GCM32ED70G227MEC4"," alcanza 220μF en encapsulado 1210 a 4Vdc, mientras que la versión de 100μF se ha reducido de 1210 a 1206 (GCM31CD70G107ME36), con una ",[40,312,313],{},"reducción de huella del 36%",". El modelo 0201 duplica la capacidad de 1μF a 2,2μF (GCM035D70E225ME02).",[34,316,317],{},[16,318,319,320,323,324,327,328,331],{},"La serie de media tensión también destaca: ",[40,321,322],{},"GCM155D71E105KE36"," ofrece 25V\u002F1μF en 0402 — ",[40,325,326],{},"61% menos área"," que la solución anterior en 0603. El modelo 1206 de 22μF (GCM31CC71E226ME36) proporciona desacoplo compacto para buses de alimentación. Todos los modelos están certificados ",[40,329,330],{},"AEC-Q200",".",[24,333,334,337],{},[16,335,336],{},"Análisis Técnico",[30,338,339,348],{"v-slot:description":32},[34,340,341],{},[16,342,343,344,347],{},"La clave de estos logros de capacidad es la tecnología patentada de ",[40,345,346],{},"micronización y homogeneización de material cerámico"," de Murata. Polvos dieléctricos más finos con distribución uniforme permiten capas más delgadas manteniendo fiabilidad automotriz. Esto es especialmente crítico para dispositivos 0201 — alojar 2,2μF en 0,6×0,3mm exige una uniformidad de espesor excepcional.",[34,349,350],{},[16,351,352,353,356],{},"Los dieléctricos X7T\u002FX7S utilizados aún presentan derating por DC bias — los ingenieros deben revisar las ",[40,354,355],{},"curvas de capacidad efectiva vs. DC bias"," para asegurar un margen adecuado a la tensión de operación real del sistema.",[24,358,359,362],{},[16,360,361],{},"Aplicaciones AD\u002FADAS",[30,363,364,369],{"v-slot:description":32},[34,365,366],{},[16,367,368],{},"Con la evolución de la conducción autónoma de L2 a L3+, el número y consumo de SoCs, MCUs e ICs SerDes en sistemas AD\u002FADAS continúa aumentando. Un SoC ADAS de gama alta puede demandar decenas de amperios de pico, requiriendo numerosos MLCC para desacoplo transitorio. La tensión nominal de 2,5–4V se alinea con los rieles de alimentación de núcleo digital (0,8–3,3V).",[34,370,371],{},[16,372,373],{},"El condensador de desacoplo 0201 2,2μF puede colocarse directamente en la parte posterior del IC o entre pads BGA, minimizando la inductancia parásita. El dispositivo 0402 1μF\u002F25V es ideal para filtrado de entrada en módulos de sensores.",[24,375,376,378],{},[16,377,133],{},[30,379,380,385,397],{"v-slot:description":32},[34,381,382],{},[16,383,384],{},"La expansión de Murata tiene implicaciones directas en la cadena de suministro. La penetración de vehículos eléctricos sigue aumentando en 2026, con una utilización de capacidad superior al 85% para MLCC automotrices. Estos 7 nuevos modelos apuntan al segmento AD\u002FADAS de alto crecimiento — el suministro inicial priorizará clientes Tier-1.",[34,386,387],{},[16,388,389,390,393,394,331],{},"Para volúmenes pequeños y medianos, recomendamos ",[40,391,392],{},"calificación temprana de alternativas",": TDK serie CGA, Samsung CL31\u002FCL32, Yageo serie AC y Walsin serie WF. Para MLCC ultra-pequeños con alta concentración de proveedores, se recomienda ",[40,395,396],{},"asegurar contratos de 6–12 meses",[34,398,399],{},[16,400,401],{},"Movthing mantiene alianzas estrechas con Murata, TDK, Samsung, Yageo y otros fabricantes líderes de MLCC, ofreciendo muestras, interpretación de hojas de datos y recomendaciones de piezas alternativas.",[24,403,404,407],{},[16,405,406],{},"Referencia Rápida",[30,408,409,542],{"v-slot:description":32},[34,410,411],{},[164,412,413,432],{},[167,414,415],{},[170,416,417,420,423,426,429],{},[173,418,419],{},"Número de Pieza",[173,421,422],{},"Tensión Nominal",[173,424,425],{},"Encapsulado",[173,427,428],{},"Capacidad",[173,430,431],{},"Aplicación",[180,433,434,451,467,482,496,511,527],{},[170,435,436,439,442,445,448],{},[185,437,438],{},"GCM035D70E225ME02",[185,440,441],{},"2,5Vdc",[185,443,444],{},"0201inch",[185,446,447],{},"2,2μF",[185,449,450],{},"Desacoplo IC AD\u002FADAS",[170,452,453,456,458,461,464],{},[185,454,455],{},"GCM31CD70E107ME36",[185,457,441],{},[185,459,460],{},"1206inch",[185,462,463],{},"100μF",[185,465,466],{},"Buses de alimentación",[170,468,469,472,475,477,479],{},[185,470,471],{},"GCM035D70G225MEC2",[185,473,474],{},"4Vdc",[185,476,444],{},[185,478,447],{},[185,480,481],{},"Módulos de sensor",[170,483,484,487,489,491,493],{},[185,485,486],{},"GCM31CD70G107ME36",[185,488,474],{},[185,490,460],{},[185,492,463],{},[185,494,495],{},"Controladores de dominio",[170,497,498,500,502,505,508],{},[185,499,309],{},[185,501,474],{},[185,503,504],{},"1210inch",[185,506,507],{},"220μF",[185,509,510],{},"Rieles de alta corriente",[170,512,513,515,518,521,524],{},[185,514,322],{},[185,516,517],{},"25Vdc",[185,519,520],{},"0402inch",[185,522,523],{},"1μF",[185,525,526],{},"Filtrado de entrada",[170,528,529,532,534,536,539],{},[185,530,531],{},"GCM31CC71E226ME36",[185,533,517],{},[185,535,460],{},[185,537,538],{},"22μF",[185,540,541],{},"Desacoplo de línea",[34,543,544],{},[16,545,546],{},"Todos los modelos operan de -55°C a +125°C (X7T\u002FX7S) con certificación AEC-Q200. Consulte las características de DC bias, especialmente en modelos de baja tensión.",[34,548,549],{},[16,550,551],{},"Los 7 nuevos MLCC automotrices de Murata cubren desde desacoplo ultra-compacto hasta filtrado de alta capacidad. Movthing monitorea continuamente la capacidad y los nuevos productos de los fabricantes de MLCC. Contacte a nuestro equipo de ingeniería para hojas de datos o muestras.",{"title":32,"searchDepth":249,"depth":249,"links":553},[],"Murata inicia la producción en masa de 7 MLCC automotrices (2,5V–25V, 0201–1210). Análisis de cadena de suministro y selección para ingenieros de hardware.",{},"\u002Flocales\u002Fes\u002Fnews\u002Fmurata-expands-automotive-mlcc-2026",{"title":264,"description":554},"locales\u002Fes\u002Fnews\u002Fmurata-expands-automotive-mlcc-2026","x-fsTFnbGko9mOPkPA3vQJVViMMGn7QEwIk1nZBf8oI","murata-expands-automotive-mlcc-2026",[562,1178],{"id":563,"title":564,"author":8,"body":565,"category":1169,"cover":574,"date":1170,"description":1171,"excerpt":253,"extension":254,"meta":1172,"navigation":256,"path":1173,"seo":1174,"stem":1175,"__hash__":1176,"slug":1177},"blog\u002Flocales\u002Fes\u002Fblog\u002Fmlcc-selection-smartphones-tablets-laptops.md","MLCC Selection Guide for Smartphones, Tablets & Laptops — Decoupling, Filtering & Power Management",{"type":10,"value":566,"toc":1167},[567,575,609,640,679,738,816,1057,1106],[13,568,569],{},[16,570,571],{},[19,572],{"alt":573,"src":574},"Smartphone MLCC Capacitor Selection","\u002Fimages\u002Fblog\u002Fmlcc-selection-smartphones-tablets-laptops\u002Fmlcc-selection-smartphones-tablets-laptops.webp",[24,576,577,580],{},[16,578,579],{},"The Consumer Electronics Landscape — Why Capacitor Selection Matters Here",[30,581,582,595,604],{"v-slot:description":32},[34,583,584],{},[16,585,586,587,590,591,594],{},"Smartphones, tablets, and laptops represent the highest-volume MLCC market in the world. A single flagship smartphone contains ",[40,588,589],{},"800–1,200 MLCCs",", while a laptop motherboard carries ",[40,592,593],{},"1,500–2,500",". These capacitors are packed into ever-shrinking PCB real estate, operating at low voltages (1V–20V) but under relentless pressure to be smaller, thinner, and cheaper — without sacrificing reliability.",[34,596,597],{},[16,598,599,600,603],{},"The defining challenge in consumer electronics is ",[40,601,602],{},"density",". With 0201 and 0402 packages occupying under 1 mm² of board space, placement, soldering, and thermal management all become more demanding. Yet the electrical requirements are no less strict: power rails on modern SoCs demand microsecond transient response, and MLCC decoupling is the first line of defense against voltage droop.",[34,605,606],{},[16,607,608],{},"This guide focuses on the three dominant consumer platforms — smartphones, tablets, and laptops — and provides a practical framework for selecting the right MLCC at each position in the design. We cover package selection, dielectric choice, DC bias derating, and the most commonly used part number series from major brands.",[24,610,611,614],{},[16,612,613],{},"Package Size Strategy — 0201, 0402, and 0603 in Consumer Design",[30,615,616,624,632],{"v-slot:description":32},[34,617,618],{},[16,619,620,623],{},[40,621,622],{},"0201 (0.25 × 0.125 mm)",": The smallest widely available MLCC package, now standard in flagship smartphones and high-end laptops. Used almost exclusively for high-speed digital decoupling where every fraction of a millimeter matters — think application processor core rails, LPDDR5 memory termination, and MIPI CSI\u002FDSI signal lines. Typical specs: X5R\u002FX6S, 4V–10V, 0.1 µF–2.2 µF. Note that 0201 placement requires precision pick-and-place and laser-based AOI — not every assembly house can handle them reliably.",[34,625,626],{},[16,627,628,631],{},[40,629,630],{},"0402 (0.4 × 0.2 mm)",": The sweet spot for most portable consumer designs. 0402 is small enough for dense layouts yet manufacturable with widely available SMT lines. Dominant use cases: PMIC input\u002Foutput decoupling, wireless charging TX\u002FRX resonance, Wi-Fi\u002FBluetooth module bypassing, and DDR termination. The 0402 footprint dominates the 16V\u002F25V\u002F50V range at 100 nF–10 µF and accounts for the majority of MLCC shipments into the wireless charging segment. If your design can accept the footprint, 0402 almost always offers the best cost-per-capacitance ratio in the sub-10 µF range.",[34,633,634],{},[16,635,636,639],{},[40,637,638],{},"0603 (0.6 × 0.3 mm)",": Used where higher capacitance or higher voltage is needed and the layout has room — bulk decoupling for battery rails, USB PD 20V input filtering, audio codec supply bypassing, and SSD power management in laptops. 0603 X5R\u002FX7R capacitors in the 10 µF–47 µF range at 4V–25V serve as the main storage reservoir after the battery buck converter. At 100V ratings, 0603 X7R also handles backlight LED driver output filtering in tablet and laptop LCD panels.",[24,641,642,645],{},[16,643,644],{},"Dielectric Selection — X5R, X6S, X7R, and When to Use C0G",[30,646,647,655,663,671],{"v-slot:description":32},[34,648,649],{},[16,650,651,654],{},[40,652,653],{},"X5R"," (-55°C to +85°C, ±15%): The default dielectric for consumer electronics. X5R delivers the highest capacitance density in small packages, making it ideal for decoupling processors, GPUs, PMICs, and memory rails. The 85°C upper limit is acceptable for all consumer devices — even laptops rarely exceed 70°C at the PCB surface. X5R at 4V and 6.3V ratings covers the majority of sub-5V digital rails.",[34,656,657],{},[16,658,659,662],{},[40,660,661],{},"X6S"," (-55°C to +105°C, ±22%): A newer dielectric that bridges the gap between X5R and X7R. X6S offers better temperature performance than X5R while maintaining higher capacitance density than X7R. Increasingly used in tablet and laptop power rails near the CPU\u002FGPU where board temperatures can spike during sustained workloads. Also common in fast-charging circuits where the USB PD controller area runs hotter.",[34,664,665],{},[16,666,667,670],{},[40,668,669],{},"X7R"," (-55°C to +125°C, ±15%): Used in consumer electronics where thermal margin is needed — wireless charging coils, display backlight drivers, and any circuit near the battery charging path. X7R costs slightly more than X5R but provides peace of mind in thermally challenging locations. Strongly recommended for all 0603 power decoupling above 10 µF.",[34,672,673],{},[16,674,675,678],{},[40,676,677],{},"C0G\u002FNP0"," (±30 ppm\u002F°C, near-zero drift): Reserved for precision timing, RF matching, and clock oscillator circuits. In smartphones, C0G 0402 capacitors at 1 pF–100 pF are critical in the RF front-end (antenna matching, bandpass filters) and in the crystal oscillator circuits for Wi-Fi, Bluetooth, and cellular modems. C0G capacitance is limited to the pF–low nF range, so it cannot replace X5R\u002FX7R for power decoupling.",[24,680,681,684],{},[16,682,683],{},"Voltage Derating & DC Bias — The Consumer Electronics Trap",[30,685,686,699,711],{"v-slot:description":32},[34,687,688],{},[16,689,690,691,694,695,698],{},"The most common mistake in consumer electronics MLCC selection is ",[40,692,693],{},"insufficient DC bias derating",". X5R and X6S dielectrics can lose 50–70% of their rated capacitance under DC bias approaching the rated voltage. A 10 µF, 6.3V, 0402 X5R capacitor may deliver only ",[40,696,697],{},"3–4 µF"," of actual capacitance on a 5V rail. Designers must check the manufacturer's DC bias curve for every capacitor on every rail — never assume the nominal value.",[34,700,701],{},[16,702,703,706,707,710],{},[40,704,705],{},"Rule of thumb for consumer designs",": For power rail decoupling, size your MLCC so the nominal rating is ",[40,708,709],{},"2–3×"," the actual rail voltage. A 1.8V core rail should use 6.3V rated capacitors. A 5V USB rail should use 10V or 16V rated capacitors. This provides adequate effective capacitance after derating and margin for voltage transients.",[34,712,713,719],{},[16,714,715,718],{},[40,716,717],{},"Voltage rating table for common consumer rails",":",[720,721,722,726,729,732,735],"ul",{},[723,724,725],"li",{},"0.8V–1.2V (SoC core): 4V or 6.3V X5R",[723,727,728],{},"1.8V–3.3V (I\u002FO, memory): 6.3V or 10V X5R",[723,730,731],{},"5V (USB, audio): 10V or 16V X5R\u002FX7R",[723,733,734],{},"12V–20V (USB PD, charging): 25V or 35V X7R",[723,736,737],{},"Display backlight (20V–40V): 50V or 100V X7R",[24,739,740,743],{},[16,741,742],{},"Recommended Brands & Part Number Series for Consumer Electronics",[30,744,745,765,781,801],{"v-slot:description":32},[34,746,747],{},[16,748,749,752,753,756,757,760,761,764],{},[40,750,751],{},"Murata",": The market leader in small-case MLCCs. The ",[40,754,755],{},"GRM"," series (general-purpose X5R\u002FX7R) is the de facto standard for 0201\u002F0402 decoupling in smartphones. For ultra-thin designs, Murata's ",[40,758,759],{},"GRT"," series offers low-profile packages. The ",[40,762,763],{},"GCM"," series provides automotive-grade quality at near-commercial pricing — worth considering for premium laptop designs where reliability is a brand differentiator.",[34,766,767],{},[16,768,769,772,773,776,777,780],{},[40,770,771],{},"TDK",": The ",[40,774,775],{},"C"," series (commercial grade) and ",[40,778,779],{},"CGA"," series (automotive grade) cover the full consumer spectrum. TDK's strength is in the 0402\u002F0603 X7R range at 25V–100V — ideal for USB PD and display backlight filtering. TDK C-series 0201 capacitors are widely second-sourced alongside Murata in flagship phone designs.",[34,782,783],{},[16,784,785,788,789,792,793,796,797,800],{},[40,786,787],{},"WALSIN (华新科)"," and ",[40,790,791],{},"YAGEO (国巨)",": Taiwanese manufacturers offering competitive pricing for high-volume consumer designs. WALSIN's ",[40,794,795],{},"0201\u002F0402 X5R"," and YAGEO's ",[40,798,799],{},"CC"," series are popular choices for cost-sensitive tablet and mid-range smartphone designs where every cent of BOM cost matters. Both offer performance comparable to Murata\u002FTDK for standard decoupling applications.",[34,802,803],{},[16,804,805,788,808,811,812,815],{},[40,806,807],{},"FH (风华)",[40,809,810],{},"Samsung",": FH is a leading Chinese brand with strong cost competitiveness in 0402\u002F0603 X5R — widely used in domestic tablet and laptop ODM designs. Samsung's ",[40,813,814],{},"CL"," series offers a middle ground between Japanese quality and Taiwanese pricing, particularly strong in the 0603 10 µF–22 µF range used for laptop power management.",[24,817,818,821],{},[16,819,820],{},"Quick-Reference Part Number Table — Consumer Electronics",[30,822,823],{"v-slot:description":32},[164,824,825,847],{},[167,826,827],{},[170,828,829,832,835,838,841,844],{},[173,830,831],{},"Application",[173,833,834],{},"Package",[173,836,837],{},"Voltage",[173,839,840],{},"Capacitance",[173,842,843],{},"Dielectric",[173,845,846],{},"Recommended Series",[180,848,849,868,883,902,919,936,954,973,989,1006,1022,1040],{},[170,850,851,854,857,860,863,865],{},[185,852,853],{},"SoC Core Decoupling",[185,855,856],{},"0201",[185,858,859],{},"4V",[185,861,862],{},"0.1 µF",[185,864,653],{},[185,866,867],{},"Murata GRM, TDK C",[170,869,870,872,874,876,879,881],{},[185,871,853],{},[185,873,856],{},[185,875,859],{},[185,877,878],{},"1 µF",[185,880,661],{},[185,882,867],{},[170,884,885,888,891,894,897,899],{},[185,886,887],{},"PMIC Output",[185,889,890],{},"0402",[185,892,893],{},"6.3V",[185,895,896],{},"10 µF",[185,898,653],{},[185,900,901],{},"Murata GRM, WALSIN",[170,903,904,907,909,911,914,916],{},[185,905,906],{},"DDR5 Termination",[185,908,890],{},[185,910,859],{},[185,912,913],{},"0.22 µF",[185,915,653],{},[185,917,918],{},"Murata GRM, YAGEO CC",[170,920,921,924,926,929,932,934],{},[185,922,923],{},"Wireless Charger RX",[185,925,890],{},[185,927,928],{},"25V",[185,930,931],{},"100 nF",[185,933,669],{},[185,935,867],{},[170,937,938,941,943,946,949,951],{},[185,939,940],{},"USB PD 5V Rail",[185,942,890],{},[185,944,945],{},"16V",[185,947,948],{},"2.2 µF",[185,950,669],{},[185,952,953],{},"TDK C, Samsung CL",[170,955,956,959,962,965,968,970],{},[185,957,958],{},"Battery Rail Bulk",[185,960,961],{},"0603",[185,963,964],{},"10V",[185,966,967],{},"22 µF",[185,969,653],{},[185,971,972],{},"Murata GRM, Samsung CL",[170,974,975,978,980,982,985,987],{},[185,976,977],{},"Audio Codec Bypass",[185,979,890],{},[185,981,893],{},[185,983,984],{},"4.7 µF",[185,986,653],{},[185,988,901],{},[170,990,991,994,996,999,1001,1003],{},[185,992,993],{},"LCD Backlight Output",[185,995,961],{},[185,997,998],{},"50V",[185,1000,931],{},[185,1002,669],{},[185,1004,1005],{},"TDK C, YAGEO CC",[170,1007,1008,1011,1013,1015,1018,1020],{},[185,1009,1010],{},"MIPI DSI Filtering",[185,1012,856],{},[185,1014,893],{},[185,1016,1017],{},"0.47 µF",[185,1019,653],{},[185,1021,867],{},[170,1023,1024,1027,1029,1031,1034,1037],{},[185,1025,1026],{},"Wi-Fi\u002FBT Antenna Match",[185,1028,890],{},[185,1030,928],{},[185,1032,1033],{},"1.5 pF",[185,1035,1036],{},"C0G",[185,1038,1039],{},"Murata GJM, TDK C",[170,1041,1042,1045,1047,1050,1052,1054],{},[185,1043,1044],{},"USB PD 20V Input",[185,1046,961],{},[185,1048,1049],{},"35V",[185,1051,896],{},[185,1053,669],{},[185,1055,1056],{},"TDK C, Murata GRM",[24,1058,1059,1062],{},[16,1060,1061],{},"Common Design Pitfalls & Real-World Cases",[30,1063,1064,1076,1087,1095],{"v-slot:description":32},[34,1065,1066],{},[16,1067,1068,1071,1072,1075],{},[40,1069,1070],{},"Pitfall 1 — Ignoring DC Bias in PMIC Decoupling",": A hardware team selected 4.7 µF, 6.3V, 0402 X5R capacitors for the output of a PMIC buck converter on a tablet SoC rail (1.1V). With the low DC bias at 1.1V, the effective capacitance was close to nominal — but on the 3.3V rail using the same capacitor, effective capacitance dropped to ~2.5 µF. The resulting higher ripple caused SoC stability issues that took weeks to debug. ",[40,1073,1074],{},"Lesson",": Always check the DC bias curve per rail, not just the capacitor datasheet front page.",[34,1077,1078],{},[16,1079,1080,1083,1084,1086],{},[40,1081,1082],{},"Pitfall 2 — 0201 Assembly Yield Without Proper Process Control",": A mid-range smartphone ODM switched from 0402 to 0201 for processor decoupling to save board area. The first production batch had 3% tombstoning defects because the pick-and-place machine hadn't been recalibrated for 0201, and the stencil aperture wasn't optimized for the smaller pad geometry. ",[40,1085,1074],{},": 0201 adoption requires process validation — don't treat it as just a smaller 0402.",[34,1088,1089],{},[16,1090,1091,1094],{},[40,1092,1093],{},"Pitfall 3 — Acoustic Noise in Tablet Displays",": A tablet design experienced audible buzzing from the LCD backlight circuit. Investigation revealed that the X7R MLCCs in the boost converter were exhibiting piezoelectric vibration at the PWM switching frequency. Switching to capacitors with soft-termination or adding a small series resistor damped the resonance. This is a well-known MLCC behavior — X7R's barium titanate ceramic is inherently piezoelectric, and in audio-frequency switching circuits, this can couple mechanically into the chassis.",[34,1096,1097],{},[16,1098,1099,1102,1103,1105],{},[40,1100,1101],{},"Pitfall 4 — Capacitor Count Reduction to Save BOM Cost",": A laptop motherboard design reduced the number of 0402 decoupling capacitors per rail from the reference design's recommended count to save $0.12 per board. The resulting higher power rail impedance led to intermittent DDR training failures at cold boot. The fix added back the capacitors and cost significantly more in re-spin and delayed launch than the original BOM savings. ",[40,1104,1074],{},": Decoupling capacitor count is set by impedance targets, not by BOM optimization.",[24,1107,1108,1111],{},[16,1109,1110],{},"Related Products & Further Reading",[30,1112,1113],{"v-slot:description":32},[34,1114,1115,1118,1156],{},[16,1116,1117],{},"Browse Movthing's capacitor catalog for consumer electronics parts:",[720,1119,1120,1128,1135,1142,1149],{},[723,1121,1122,1127],{},[1123,1124,1126],"a",{"href":1125},"\u002Fproducts\u002Fcapacitors\u002Fmurata","Murata MLCC Capacitors"," — GRM series for 0201\u002F0402\u002F0603",[723,1129,1130,1134],{},[1123,1131,1133],{"href":1132},"\u002Fproducts\u002Fcapacitors\u002Ftdk","TDK MLCC Capacitors"," — C series for consumer applications",[723,1136,1137,1141],{},[1123,1138,1140],{"href":1139},"\u002Fproducts\u002Fcapacitors\u002Fsamsung","Samsung MLCC Capacitors"," — CL series, strong in 0603",[723,1143,1144,1148],{},[1123,1145,1147],{"href":1146},"\u002Fproducts\u002Fcapacitors\u002Fwalsin","WALSIN MLCC Capacitors"," — Cost-competitive 0201–0603",[723,1150,1151,1155],{},[1123,1152,1154],{"href":1153},"\u002Fproducts\u002Fcapacitors\u002Fyageo","YAGEO MLCC Capacitors"," — CC series for consumer designs",[16,1157,1158,1161,1162,1166],{},[40,1159,1160],{},"Next in this series",": ",[1123,1163,1165],{"href":1164},"\u002Fblog\u002Fmlcc-selection-wearables-tws-iot","MLCC Selection for Wearables: TWS, Smartwatches & IoT Sensors"," — covering the unique challenges of ultra-compact, battery-powered wearable devices.",{"title":32,"searchDepth":249,"depth":249,"links":1168},[],"selection-guide","2026-04-30","A practical MLCC capacitor selection guide for consumer electronics covering smartphones, tablets, and laptops. Package sizes from 0201 to 0603, X5R\u002FX7R dielectrics, DC bias derating, and brand recommendations.",{},"\u002Flocales\u002Fes\u002Fblog\u002Fmlcc-selection-smartphones-tablets-laptops",{"title":564,"description":1171},"locales\u002Fes\u002Fblog\u002Fmlcc-selection-smartphones-tablets-laptops","ykR4UPtYrtlztiFmX38sKX2U0i8ajFs6qRvKPWEuSks","mlcc-selection-smartphones-tablets-laptops",{"id":1179,"title":1180,"author":8,"body":1181,"category":1169,"cover":1534,"date":1535,"description":1536,"excerpt":253,"extension":254,"meta":1537,"navigation":256,"path":1538,"seo":1539,"stem":1540,"__hash__":1541,"slug":1542},"blog\u002Flocales\u002Fes\u002Fblog\u002Fautomotive-mlcc-selection-guide.md","Guía de Selección de MLCC Automotriz – Cómo Elegir el Condensador SMD Adecuado para Electrónica del Vehículo",{"type":10,"value":1182,"toc":1532},[1183,1188,1228,1265,1306,1335,1374,1479,1504,1527],[13,1184,1185],{},[16,1186,1187],{},"![Guía de Selección MLCC Automotriz](\u002Fimages\u002Fblog\u002FAutomotive-Grade MLCC Selection Guide\u002Fcapacitors.webp)",[24,1189,1190,1193],{},[16,1191,1192],{},"Diferencias Clave: MLCC Automotrices vs. de Consumo",[30,1194,1195,1203,1215],{"v-slot:description":32},[34,1196,1197],{},[16,1198,1199,1200,1202],{},"El entorno de la electrónica automotriz impone requisitos mucho más estrictos a los MLCC que la electrónica de consumo. Los MLCC de grado automotriz deben aprobar la calificación ",[40,1201,330],{}," — el estándar de pruebas de estrés para componentes pasivos que cubre ciclos de temperatura, envejecimiento por humedad, choque mecánico y más. Esta es la división fundamental entre productos automotrices y de consumo.",[34,1204,1205],{},[16,1206,1207,1208,1210,1211,1214],{},"Los MLCC automotrices deben operar típicamente de ",[40,1209,206],{},", con componentes cerca del motor que requieren hasta ",[40,1212,1213],{},"+150°C",". En contraste, los condensadores X5R de consumo solo están garantizados de -55°C a +85°C — totalmente inadecuado para uso automotriz.",[34,1216,1217],{},[16,1218,1219,1220,1223,1224,1227],{},"Además, los productos automotrices requieren ",[40,1221,1222],{},"trazabilidad completa de lote"," y documentación ",[40,1225,1226],{},"PPAP"," que los productos de consumo no ofrecen. Cada paso de producción debe ser rastreable hasta la materia prima.",[24,1229,1230,1233],{},[16,1231,1232],{},"Selección del Dieléctrico: X7R es el Caballo de Batalla, Pero No Siempre Suficiente",[30,1234,1235,1242,1250,1257],{"v-slot:description":32},[34,1236,1237],{},[16,1238,1239,1241],{},[40,1240,669],{}," (-55°C a +125°C, cambio de capacitancia ±15%) es el dieléctrico dominante para MLCC automotrices. Sirve para desacoplo y filtrado en infoentretenimiento, control de carrocería e iluminación LED. X7R representa más del 70% de todos los envíos de MLCC automotrices.",[34,1243,1244],{},[16,1245,1246,1249],{},[40,1247,1248],{},"X8L \u002F X8R"," (-55°C a +150°C) se requiere para módulos cerca del motor. Con la creciente integración de ECUs, la demanda de X8 crece significativamente más rápido que X7R. Los tipos X8 ofrecen rangos de capacitancia más estrechos y cuestan 30-50% más.",[34,1251,1252],{},[16,1253,1254,1256],{},[40,1255,677],{}," (±30ppm\u002F°C, deriva casi nula) es la opción para circuitos resonantes y acondicionamiento de señales. En radares ADAS y LiDAR, la estabilidad de temperatura de C0G es insustituible. Sin embargo, su límite de capacitancia está típicamente en el rango de nF.",[34,1258,1259],{},[16,1260,1261,1262],{},"Un error común es usar Y5V en escenarios de alta temperatura para ahorrar costes. Y5V puede perder más del 80% de su capacitancia a +85°C. ",[40,1263,1264],{},"Las aplicaciones automotrices deben evitar completamente los dieléctricos Y5V\u002FZ5U.",[24,1266,1267,1270],{},[16,1268,1269],{},"Comportamiento DC Bias – La Trampa Oculta en el Diseño de Potencia Automotriz",[30,1271,1272,1281,1301],{"v-slot:description":32},[34,1273,1274],{},[16,1275,1276,1277,1280],{},"Con plataformas de batería de 48V híbrido suave a 400V\u002F800V de alto voltaje, el derating por DC bias se vuelve un factor crítico. Un MLCC nominal de 10µF, 50V 1206 X7R puede entregar solo ",[40,1278,1279],{},"30-40%"," de su capacitancia nominal a 40V de polarización DC.",[34,1282,1283],{},[16,1284,1285,1288,1289,1292,1293,1296,1297,1300],{},[40,1286,1287],{},"Estrategias de mitigación",": Elija una ",[40,1290,1291],{},"tensión nominal más alta"," — p.ej., 100V o 250V para un sistema de 48V. Prefiera ",[40,1294,1295],{},"tamaños de encapsulado más grandes"," — 0805 tiene mejor estabilidad que 0603, 1206 es notablemente mejor. Use ",[40,1298,1299],{},"varios condensadores pequeños en paralelo"," en lugar de uno grande cuando el espacio lo permita.",[34,1302,1303],{},[16,1304,1305],{},"Para condensadores de tanque resonante en convertidores DC-DC y OBCs automotrices, las características de DC bias impactan directamente la eficiencia. Para estas aplicaciones, considere fuertemente el dieléctrico C0G.",[24,1307,1308,1311],{},[16,1309,1310],{},"Tecnología de Terminación Flexible – La Clave para Sobrevivir a la Vibración",[30,1312,1313,1318,1327],{"v-slot:description":32},[34,1314,1315],{},[16,1316,1317],{},"La vibración continua durante la conducción y la deformación del PCB por ciclos térmicos son la causa #1 de fallo de MLCC en vehículos. Los MLCC estándar desarrollan grietas fácilmente cuando el PCB se flexiona — las grietas por flexión son el modo de fallo más común.",[34,1319,1320],{},[16,1321,1322,1323,1326],{},"La tecnología de ",[40,1324,1325],{},"Terminación Flexible (Soft Termination)"," incorpora una capa conductora de plata-polímero en el electrodo terminal que absorbe tensiones mecánicas. Familias de fabricantes: TDK serie CGA, Murata serie GCJ, Yageo serie AC, Walsin serie WF, Samsung modelos AEC-Q200 en CL31\u002FCL32.",[34,1328,1329],{},[16,1330,1331,1334],{},[40,1332,1333],{},"Recomendación",": Use versiones de terminación flexible para condensadores cerca de bordes de PCB, conectores y para encapsulados grandes (1206+). El sobrecoste del 10-20% se compensa ampliamente con tasas de fallo de campo reducidas.",[24,1336,1337,1340],{},[16,1338,1339],{},"Estrategias de Selección por Aplicación",[30,1341,1342,1350,1358,1366],{"v-slot:description":32},[34,1343,1344],{},[16,1345,1346,1349],{},[40,1347,1348],{},"Tren Motriz y Propulsión Eléctrica",": X7R principal, X8L para zonas calientes. Encapsulado: 0805-1210. Tensión: 100V-630V. Clave: comportamiento DC bias, alta capacidad de corriente de rizado. Recomendado: terminación flexible + AEC-Q200.",[34,1351,1352],{},[16,1353,1354,1357],{},[40,1355,1356],{},"ADAS y Conducción Autónoma",": C0G para circuitos RF, X7R para desacoplo de potencia. Encapsulado: 0402-0603. Clave: fiabilidad ultra-alta, estabilidad de coeficiente térmico, bajo ESR\u002FESL. Cualquier fallo de condensador puede causar un fallo relevante para la seguridad.",[34,1359,1360],{},[16,1361,1362,1365],{},[40,1363,1364],{},"Infoentretenimiento y Electrónica de Carrocería",": X7R como opción principal. Encapsulado: 0402-0805. Tensión: 16V-50V. Clave: rentabilidad, estabilidad de suministro. Incluso los módulos \"no críticos\" requieren AEC-Q200.",[34,1367,1368],{},[16,1369,1370,1373],{},[40,1371,1372],{},"Sistema de Gestión de Batería (BMS)",": X7R + C0G para medición de tensión de precisión. Encapsulado: 0603-1206. Clave: resistencia de aislamiento extremadamente alta, baja corriente de fuga, estabilidad a largo plazo. Las fugas en circuitos de medición causan errores de estimación SOC.",[24,1375,1376,1379],{},[16,1377,1378],{},"Referencia Rápida de Encapsulados y Tensiones",[30,1380,1381,1470],{"v-slot:description":32},[34,1382,1383],{},[164,1384,1385,1400],{},[167,1386,1387],{},[170,1388,1389,1391,1394,1397],{},[173,1390,425],{},[173,1392,1393],{},"Cap. Máx. Típica (X7R)",[173,1395,1396],{},"Tensiones Comunes",[173,1398,1399],{},"Aplicaciones Automotrices",[180,1401,1402,1415,1428,1442,1456],{},[170,1403,1404,1406,1409,1412],{},[185,1405,890],{},[185,1407,1408],{},"1µF",[185,1410,1411],{},"16V, 25V, 50V",[185,1413,1414],{},"Sensores ADAS, módulos RF",[170,1416,1417,1419,1422,1425],{},[185,1418,961],{},[185,1420,1421],{},"22µF",[185,1423,1424],{},"25V, 50V, 100V",[185,1426,1427],{},"ECUs generales, infoentretenimiento",[170,1429,1430,1433,1436,1439],{},[185,1431,1432],{},"0805",[185,1434,1435],{},"47µF",[185,1437,1438],{},"50V, 100V",[185,1440,1441],{},"Control de carrocería",[170,1443,1444,1447,1450,1453],{},[185,1445,1446],{},"1206",[185,1448,1449],{},"100µF",[185,1451,1452],{},"100V, 250V, 630V",[185,1454,1455],{},"Tren motriz, DC-DC",[170,1457,1458,1461,1464,1467],{},[185,1459,1460],{},"1210+",[185,1462,1463],{},"220µF+",[185,1465,1466],{},"250V, 500V, 630V",[185,1468,1469],{},"OBC, bus de alta tensión",[34,1471,1472],{},[16,1473,1474,1475,1478],{},"En aplicaciones automotrices, ",[40,1476,1477],{},"evite encapsulados 0201 y menores",". Los datos de fiabilidad para estos encapsulados ultraminiatura bajo ciclos térmicos y estrés mecánico son insuficientes. Si el espacio es extremadamente limitado, considere 0402 verificando su estado AEC-Q200.",[24,1480,1481,1484],{},[16,1482,1483],{},"Consideraciones de Cadena de Suministro",[30,1485,1486,1495],{"v-slot:description":32},[34,1487,1488],{},[16,1489,1490,1491,1494],{},"Los plazos de entrega de MLCC automotrices son típicamente 4-8 semanas más largos que los de consumo, alcanzando 16-20 semanas para tipos de alta capacitancia. Prefiera combinaciones con ",[40,1492,1493],{},"múltiples fuentes",". Para piezas especiales de fuente única, cierre acuerdos de suministro de 12+ meses.",[34,1496,1497],{},[16,1498,1499,1500,1503],{},"En 2026, el mercado de MLCC automotrices está en suministro ajustado. Los X7R\u002FX8L de alta capacitancia en 0805-1206 operan cerca del 85% de utilización. Se recomienda comenzar la validación de BOM de condensadores ",[40,1501,1502],{},"6-9 meses antes"," del lanzamiento de nuevos proyectos automotrices.",[24,1505,1506,1509],{},[16,1507,1508],{},"Lista de Verificación de Selección",[30,1510,1511,1519],{"v-slot:description":32},[34,1512,1513],{},[16,1514,1515,1518],{},[40,1516,1517],{},"Requisitos básicos",": □ ¿Calificado AEC-Q200? □ ¿Rango de temperatura cubre el entorno objetivo? □ ¿Margen de tensión adecuado? (mín. 1,5× tensión de operación) □ ¿PPAP disponible?",[34,1520,1521],{},[16,1522,1523,1526],{},[40,1524,1525],{},"Evaluación avanzada",": □ ¿Capacitancia efectiva a máximo DC bias suficiente? □ ¿Necesita terminación flexible? □ ¿Corriente de rizado cubierta? □ ¿Trazabilidad de lote y procesos PCN establecidos? □ ¿Segunda fuente identificada?",[34,1528,1529],{},[16,1530,1531],{},"La selección de MLCC automotrices requiere equilibrar rendimiento eléctrico, fiabilidad mecánica y gestión de la cadena de suministro. El equipo de Movthing mantiene estrechas alianzas con TDK, Murata, Samsung, Yageo, Walsin y otros fabricantes líderes. Contacte a nuestro equipo de ingeniería para soporte personalizado.",{"title":32,"searchDepth":249,"depth":249,"links":1533},[],"\u002Fimages\u002Fblog\u002FAutomotive-Grade MLCC Selection Guide\u002Fcapacitors.webp","2026-04-28","Una guía completa para la selección de MLCC de grado automotriz cubriendo la certificación AEC-Q200, selección de dieléctrico, tecnología de terminación flexible y estrategias por aplicación.",{},"\u002Flocales\u002Fes\u002Fblog\u002Fautomotive-mlcc-selection-guide",{"title":1180,"description":1536},"locales\u002Fes\u002Fblog\u002Fautomotive-mlcc-selection-guide","Wm7JrQeD_kFfHAQoMc9_zg-fxNqNskCVszygZ9PcCR4","automotive-mlcc-selection-guide",1778570622249]