Notifications
Clear all
Search result for: WA 0859 3970 0884 Perkiraan Biaya Renovasi Rumah Minimalis Modern 7x12 Murah Imogiri Bantul
| # | Post Title | Result Info | Date | User | Forum |
| Why is LM317 still used over modern switching regulators? | 8 Relevance | 8 months ago | Suraj | Theoretical questions | |
| I’ve noticed that the LM317 linear voltage regulator is still widely used in various hobbyist and even some professional circuits, despite the availability of efficient and compact switching regulators. Considering that switching regulators offer better efficiency, less heat dissipation, and smaller footprints, what are the reasons engineers or designers still opt for LM317 in certain designs? Is it due to simplicity, cost, noise sensitivity, or something else? | |||||
| Answer to: L293D/L298N heating issue – should I switch to MOSFET-based drivers? | 4 Relevance | 6 months ago | TechPulse | Theoretical questions | |
| Yes, much of the heating behaviour is inherent to older bipolar-driver ICs like the L293D and L298N. Those chips use bipolar transistors (Darlington or bipolar output stages) with large voltage drops, so a significant fraction of motor power is dissipated in the chip as heat. Wiring and supply issues (thin wires, poor decoupling, undervoltage, high stall currents) can worsen the problem, but replacing the driver with a Modern MOSFET-based H-bridge or dedicated MOSFET motor driver typically reduces losses by orders of magnitude and greatly lowers heat. | |||||
| L293D/L298N heating issue – should I switch to MOSFET-based drivers? | 4 Relevance | 6 months ago | Roshan | Theoretical questions | |
| I’ve been using L293D and L298N motor drivers and noticed they heat up quickly, even under light loads.Is this inherent to these older ICs, or could it be a wiring/power supply issue on my side? How much of a difference would Modern MOSFET-based drivers make in terms of efficiency and heat dissipation? | |||||
| Answer to: Best way to protect a motor driver from short circuits? | 4 Relevance | 7 months ago | Janet | Theoretical questions | |
| To protect a motor driver from short circuits, one of the most effective methods is to use a fast-blow fuse or a resettable polyfuse on the power supply line to the driver. This helps cut off the current quickly if a short occurs. Additionally, placing flyback diodes across the motor terminals (if not already built into the driver) protects against voltage spikes caused by motor inductance. For more advanced protection, a current-sense resistor can be added to monitor current flow, and a microcontroller can disable the driver if the current exceeds safe limits. Alternatively, using Modern motor driver ICs like the DRV8871 or BTS7960 is highly recommended, as they come with built-in protections such as overcurrent, thermal shutdown, and undervoltage lockout. Ensuring proper cooling and heat dissipation also helps prevent damage from thermal stress that may result from sustained high current. | |||||
| Answer to: Do I really need anti-static precautions when handling ICs? | 4 Relevance | 8 months ago | Deboojit | Theoretical questions | |
| ... The damage might not be immediate or obvious; it often causes latent failures that show up later during operation. Certain types of chips are more sensitive than others—CMOS devices, including many logic ICs and virtually all microcontrollers, are especially vulnerable due to their delicate internal structures. In contrast, older TTL logic chips (like the 74LS series) are somewhat more robust but still not immune. If the IC is already soldered onto a board, the risk is lower because the surrounding circuitry and ground planes can help dissipate any static ... | |||||
| Answer to: BJT VS MOSFET- Current controlled vs Voltage controlled | 4 Relevance | 8 months ago | nathan | Theoretical questions | |
| There are people claim that BJTs (Bipolar Junction Transistors) are obsolete, but they continue to play a vital role in analog signal amplification due to their high gain and linear characteristics. They are especially preferred in applications like audio amplifiers and analog front-end circuits. However, for switching applications, especially in Modern embedded systems and power electronics, MOSFETs (Metal-Oxide-Semiconductor Field-Effect Transistors) are generally more practical. Their high input impedance, faster switching speeds, and greater efficiency at handling high currents make them ideal for use in digital circuits, motor drivers, and power converters. | |||||
| Answer to: Why do people use MOSFETs instead of relays in switching circuits? | 4 Relevance | 8 months ago | nathan | Theoretical questions | |
| That's actually a great question — and definitely not a silly one. MOSFETs are often preferred over relays in switching circuits for several technical reasons beyond just size and speed. For starters, MOSFETs switch much faster than relays — in microseconds or less — making them ideal for high-speed or PWM applications. They’re silent, have no moving parts, and don’t wear out like mechanical relays, which means they offer greater reliability and longer life. MOSFETs also consume very little current at the gate, making them more power-efficient, especially in battery-powered systems. Their compact size and ease of integration with microcontrollers also make them well-suited for Modern electronic designs. That said, relays are still useful when you need electrical isolation or when switching high-voltage or high-current AC loads that MOSFETs can't handle directly. | |||||
| Answer to: BJT VS MOSFET- Current controlled vs Voltage controlled | 4 Relevance | 9 months ago | Nitin arora | Theoretical questions | |
| MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor) is a voltage-controlled device, while BJT (Bipolar Junction Transistor) is current-controlled. MOSFETs require a voltage across the gate-source to operate, whereas BJTs need a continuous base current. In switching applications, MOSFETs are preferred due to lower power loss and simpler drive requirements. BJTs are still widely used for analog amplification because of their linear characteristics. In terms of construction, MOSFETs come in N-channel and P-channel types, while BJTs are either NPN or PNP. MOSFETs generally handle higher currents and offer better efficiency due to low RDS(on), while BJTs suffer from higher VCE saturation loss. MOSFETs have defined switching characteristics (e.g., gate charge, rise and fall times), whereas BJTs switch faster but with higher conduction losses. Additionally, MOSFETs are thermally more stable and simpler to bias, making them more suitable for Modern high-speed, low-loss applications, such as power supplies and motor drivers. | |||||
| Answer to: Why Fluke multimeters are so expensive? | 4 Relevance | 1 year ago | Neeraj Dev | Equipments | |
| ... designed to provide precise and accurate readings, which are crucial for troubleshooting and validation tasks in both professional and industrial settings. Calibration Standards: These devices meet stringent calibration standards, ensuring consistent and reliable measurements over time. Advanced Features: Fluke includes features such as true-RMS (Root Mean Square) measurement, essential for accurately assessing non-linear loads and Modern electronics. 2. Durability and Safety Robust Construction: Fluke multimeters are engineered to withstand harsh environ ... | |||||
