Infineon XMC4200F64K256BAXQSA1 XMC4000 MCU, LQFP64 Package for Industrial Automation & IoT Edge

Infineon XMC4200F64K256BAXQSA1 XMC4000 MCU Overview for Industrial Control & IoT Edge Nodes

The Infineon XMC4200F64K256BAXQSA1 is a rugged, low-latency Programmable System-on-Chip (XMC4000 series) MCU-engineered for B2B applications demanding industrial-grade reliability, real-time processing, and flexible connectivity for factory automation and IoT edge use cases. It targets Industrial Automation (precision motor drives, factory sensor nodes), Internet of Things (IoT) (remote smart grid peripherals, outdoor environmental sensors), and Energy and Power (small-scale inverter controls, battery management systems). Key integrations include: 120MHz ARM Cortex-M4 (with floating-point unit for math-intensive tasks), 256KB flash memory, 64KB RAM, embedded UART/SPI/I2C/EtherCAT-Lite (industrial Ethernet), 12-bit ADC (16 channels, 1MSPS), 2.7V?C5.5V supply range, LQFP64 (Low-Profile Quad Flat Package, 64-pin) surface-mount package, and -40??C to +105??C operating temperature-enabling secure, consistent performance in I/O-intensive, harsh-environment industrial systems.

With 120MHz Cortex-M4 real-time processing + LQFP64 debug-friendly packaging (tuned for industrial latency needs and easy maintenance), it balances speed with usability. This makes it ideal for engineers prioritizing low latency (for motor drives), harsh-environment resilience (for factory floors), and simplified debugging (for in-field repairs). As part of Infineon??s XMC4000 series-a lineup trusted by 180,000+ developers in industrial and energy sectors-it meets strict quality benchmarks: RoHS 3 compliance, IEC 61000-6-2 EMC compliance (industrial environments), ISO 9001 certification, and 12,000+ hours of reliability testing (thermal stability, signal integrity, power efficiency).

Senior engineers at a leading industrial automation firm endorse it: ??This XMC4000 MCU powers our factory motor drives. Its 120MHz M4 cuts latency to 7.5ms, and LQFP64 lets us debug on-site-we hit 99.97% drive uptime and 98% client satisfaction.?? For more industrial-grade, real-time MCUs for factory and IoT use, visit IC Manufacturer.

Technical Parameters of Infineon XMC4200F64K256BAXQSA1

Key Technical Features of XMC4200F64K256BAXQSA1 XMC4000 MCU

• 120MHz Cortex-M4 with FPU: Lowers industrial latency. An industrial motor firm noted: ??120MHz M4 reduces drive latency to 7.5ms (vs. 14ms with 80MHz MCUs)-motor precision improved by 15%. We reduced product rejects by 21%.??
• LQFP64 Debug-Friendly Package: Cuts maintenance time. A factory sensor brand shared: ??LQFP64??s exposed pins let us debug on-site-QFN packages need $5k X-ray tools. We cut service time by 35%, saving $38,000 yearly in downtime costs.??
• 0.42??A Ultra-Low Standby Current: Extends battery life. An IoT edge firm confirmed: ??Our remote grid sensors lasted 1.9 years with 0.85??A MCUs-this 0.42??A model lasts 3.8 years. Maintenance costs dropped by 49%, saving $78,000 yearly.??
• 256KB Flash Memory: Fits industrial code. A small inverter brand said: ??Our inverter control code (230KB) fits without external memory-we removed a $3.20 flash chip, saving $96,000 yearly and simplifying supply chains.??
• EtherCAT-Lite Connectivity: Enables fast industrial communication. A factory automation firm explained: ??EtherCAT-Lite reduces data latency to 1.8ms (vs. 9ms with UART)-factory throughput improved by 27%. We retained a $1.7M automotive client.??

Advantages of XMC4200F64K256BAXQSA1 vs. Typical Alternatives

Compared to low-speed industrial MCUs (high latency), QFN packages (hard to debug), and narrow-voltage MCUs (need regulators), this Infineon XMC4000 MCU solves critical B2B pain points-backed by real customer feedback:

1. Lower Latency Than Low-Speed Industrial MCUs: Low-speed industrial MCUs (80MHz) cause 14ms latency in motor drives, reducing precision and increasing rejects. The 120MHz Cortex-M4 cuts latency to 7.5ms. An industrial motor brand said: ??Our old 80MHz drives had 14ms latency-this 120MHz model has 7.5ms. Motor precision improved by 15%, rejects dropped by 21%, and we won a $1.3M contract with a automotive parts maker.??

2. Easier Debugging Than QFN Packages: QFN packages require expensive X-ray tools ($5,000+/unit) to debug pin connections, leading to 4-hour average service time for factory sensors. The LQFP64??s exposed pins enable 2.6-hour on-site debugging. A factory sensor firm shared: ??Our old QFN sensors needed X-ray debugging-this LQFP64 model uses standard multimeters. We cut service time by 35%, saving $38,000 yearly in downtime costs and keeping factory lines running 98% of the time.??

3. Wider Voltage Range Than Narrow-Voltage MCUs: Narrow-voltage industrial MCUs (3.3V only) need $0.95 voltage regulators to work with 5V industrial power rails, adding cost and PCB space. The 2.7V?C5.5V range eliminates regulators. An energy firm confirmed: ??Our old 3.3V-only inverters needed regulators-this wide-voltage model doesn??t. We saved $28,500 yearly on 30,000 units and reduced PCB size by 14%, fitting smaller enclosures in tight factory spaces.??

Typical Applications of Infineon XMC4200F64K256BAXQSA1

This rugged, real-time XMC4000 MCU excels in harsh-environment, low-latency B2B designs-proven in these key use cases:

• Industrial Automation (Precision Motor Drives): 120MHz M4 cuts latency, -40??C to +105??C handles factory heat. A motor firm confirmed: ??Drive latency down to 7.5ms, precision up by 15%, we secured a 3-year contract for 38,000 units with a global manufacturing firm.??
• Internet of Things (IoT) (Remote Grid Peripherals): 0.42??A standby extends life, EtherCAT-Lite secures data. A utility supplier reported: ??Peripheral uptime hit 99.97%, maintenance costs down by 49%, we sold 75,000 units to a national grid operator and reduced service calls by 87%.??
• Energy and Power (Small Inverter Controls): 256KB flash fits code, wide voltage range works with industrial rails. An energy brand noted: ??Inverter efficiency improved by 8%, failure rates cut by 32%, we sold 24,000 controls to a renewable energy firm and expanded to 2 new markets.??
• Industrial Automation (Factory Sensor Nodes): LQFP64 eases debugging, 16-channel ADC tracks 8 parameters. A factory firm shared: ??Sensor nodes debugged on-site (no X-ray tools)-data accuracy hit 99.9%, real-time alerts reduced downtime by 38%, we retained a $1.6M contract with a electronics manufacturer.??
• Internet of Things (IoT) (Outdoor Environmental Sensors): Low standby reduces maintenance, CAN 2.0 enables communication. An IoT firm confirmed: ??Sensor life up by 100% (1.9??3.8 years), dropout rates down to 1.8%, we secured a $580,000 contract with a municipal environmental agency.??

Frequently Asked Questions (FAQ) About Infineon XMC4200F64K256BAXQSA1

Why is 120MHz Cortex-M4 with FPU important for industrial motor drives?

Industrial motor drives need low latency (??10ms) and math processing for precision control-low-speed 80MHz MCUs cause 14ms latency and struggle with complex calculations, leading to 6% more rejects. The 120MHz M4 with FPU cuts latency to 7.5ms and handles math tasks faster. An industrial engineer said: ??Our old 80MHz drives had 14ms latency-this 120MHz model has 7.5ms. Motor precision improved by 15%, rejects dropped by 21%, and we won a $1.3M contract with a automotive parts maker.??

How does the LQFP64 package benefit factory sensor node maintenance?

Factory sensor nodes often need in-field repairs-QFN packages require X-ray tools ($5,000+/unit) to check pin connections, leading to 4-hour service time and costly downtime. The LQFP64??s exposed pins let engineers use standard multimeters, cutting service time to 2.6 hours. A factory engineer said: ??Our old QFN sensors needed X-ray debugging-this LQFP64 model uses standard tools. We cut service time by 35%, saving $38,000 yearly in downtime costs and keeping factory lines operational 98% of the time.??

What value does 0.42??A standby current add for remote grid peripherals?

Remote grid peripherals are deployed in hard-to-reach areas (power poles, rural substations), so frequent battery changes cost $156 per unit yearly. 0.42??A standby extends battery life to 3.8 years (vs. 1.9 years with 0.85??A MCUs). A utility engineer said: ??Our old 0.85??A peripherals cost $156,000 yearly to maintain-this 0.42??A model cuts costs by 49%, saving $78,000. We also avoided service disruptions that risked $45,000 in contract penalties.??

Why is 256KB flash memory critical for small inverter controls?

Small inverter controls need 220KB+ code for maximum power point tracking (MPPT), grid synchronization, and fault protection-128KB flash MCUs can??t fit this, requiring $3.20 external flash chips. The 256KB flash eliminates this cost. An energy engineer said: ??Our old 128KB MCU inverters needed external flash-this 256KB model doesn??t. We saved $96,000 yearly and reduced PCB layers by 1, cutting production time by 23% and meeting delivery deadlines 99% of the time.??

How does the 2.7V?C5.5V wide supply range improve industrial system design?

Industrial systems use mixed power rails (3.3V for logic circuits, 5V for actuators)-narrow-voltage MCUs (3.3V only) need $0.95 voltage regulators to work with 5V, adding cost and PCB space. The wide range works with both rails, eliminating regulators. An industrial engineer said: ??Our old 3.3V-only systems needed regulators-this wide-voltage model doesn??t. We saved $28,500 yearly on 30,000 units and reduced PCB size by 14%, fitting smaller enclosures that work in tight factory spaces where larger designs can??t.??