# L293 > series of push-pull driver circuits **Wikidata**: [Q115896697](https://www.wikidata.org/wiki/Q115896697) **Source**: https://4ort.xyz/entity/l293 ## Summary The L293 is a model series of integrated circuits designed as push-pull driver circuits for electric drive applications. It serves as a compact electronic solution for controlling devices like motors and actuators. ## Key Facts - **Classification**: Model series of integrated circuits specializing in push-pull driver circuits. - **Primary Use**: Electric drive applications (e.g., motor control). - **Technical Type**: Subclass of integrated circuits, driver circuits, and electronic switches. - **Documentation**: Features an image and schematic on Wikimedia Commons. - **Presence**: Has one Wikimedia Commons sitelink and is categorized under "L293" in the commons. - **Language Availability**: Documented on Wikimedia Commons, accessible across language editions. ## FAQs ### Q: What is the L293 used for? A: The L293 is used for electric drive applications, particularly for controlling devices such as motors and actuators. Its push-pull driver design enables bidirectional current flow. ### Q: How is the L293 classified technically? A: It is classified as a model series of integrated circuits, specifically functioning as a driver circuit and electronic switch. It falls under broader categories of integrated circuits and electronic switches. ### Q: Where can I find resources for the L293? A: The L293 has dedicated documentation on Wikimedia Commons, including an image and schematic, under the "L293" commons category. ### Q: What distinguishes the L293 from other driver circuits? A: It is explicitly designed as a series of push-pull driver circuits, providing a specialized solution for electric drive control, with structured documentation and broad accessibility. ## Why It Matters The L293 series addresses the need for efficient, integrated solutions in electric drive systems, simplifying motor and actuator control. Its push-pull architecture allows bidirectional current handling, which is critical for applications requiring reversible motion, such as robotics and automation. By consolidating driver functions into a single integrated circuit, it reduces component complexity, lowers power consumption, and accelerates prototyping for engineers and hobbyists. This model series exemplifies how standardized integrated circuits democratize access to precise control mechanisms in industrial and consumer electronics. ## Notable For - **Specialized Design**: Exclusively engineered as a series of push-pull driver circuits, distinguishing it from generic driver ICs. - **Multi-Categorization**: Explicitly classified under integrated circuits, driver circuits, and electronic switches, demonstrating versatility. - **Open Documentation**: Features comprehensive public resources (image, schematic) on Wikimedia Commons, enhancing accessibility and referenceability. - **Niche Application Focus**: Tailored specifically for electric drive needs, making it a cornerstone in motion control systems. ## Body ### Overview The L293 is a model series of integrated circuits categorized by its push-pull driver circuit design. It serves as an electronic switch optimized for electric drive applications, enabling control of motors and similar actuators. ### Technical Classification - **Instance Of**: Model series - **Subclasses**: Integrated circuit, driver circuit, electronic switch, integrated circuit model - **Primary Function**: Electric drive ### Documentation Resources - **Image**: Available at [https://commons.wikimedia.org/wiki/Special:FilePath/L293D.jpg](https://commons.wikimedia.org/wiki/Special:FilePath/L293D.jpg) - **Schematic**: Accessible via [https://commons.wikimedia.org/wiki/Special:FilePath/Schematics_of_the_circuit.png](https://commons.wikimedia.org/wiki/Special:FilePath/Schematics_of_the_circuit.png) - **Sitelink Count**: 1 (Wikimedia Commons) - **Commons Category**: L293 - **Wikipedia Languages**: Commons ### Key Applications - **Core Use**: Electric drive (e.g., motor control systems) - **Operation**: Utilizes push-pull circuitry to facilitate bidirectional current flow, essential for reversible actuation.