This article discusses the importance and application advantages of switching regulators in electronic system design, introduces different types of switching converters, and compares the differences between linear regulators and switch-mode power supplies (SMPS). Additionally, the article provides detailed information on multiple switching regulator products from SLKOR Semiconductor, which feature high efficiency, compact size, and low standby current. The article also emphasizes the significance of high-efficiency and miniaturized power conversion in modern electronic device design.

When selecting a switching regulator, efficiency is the most critical criterion. Modern compact devices must achieve reliable power delivery within a small footprint. The ability to generate stable voltages while supplying substantial current is a fundamental requirement in electronic component design. Switching regulators are essential devices for generating stable supply voltages and stepping voltages up or down. Switching regulators are known by various names: converters or switches, switch-mode power supplies (SMPS), and DC/DC regulators or converters. Their popularity continues to rise due to advantages such as meeting high-power conversion efficiency requirements, flexibility in deriving stable outputs from a single input voltage source, and adaptability to multi-output configurations with varying polarities. The most common types of switching converters include:

Boost Type:Increases the input voltage and delivers a regulated output.

Buck Type:Reduces the input voltage and delivers a regulated output.

Buck-Boost:Steps the input voltage up or down, with optional negative polarity.

Flyback Type:A buck-boost variant that provides electrical isolation.

Constant-Voltage and Adjustable Linear Voltage Regulators

For years, power supply designs have relied on linear regulators. Linear regulators excel at providing continuous, fixed output voltages. Additionally, other linear regulators (e.g., LM317) offer adjustability. Common constant and linear output voltage regulator types include the 78xx series (positive output) and 79xx series (negative output). These regulators provide stable outputs ranging from 5 V to 24 V. Linear regulators are not switch-mode power supplies. Their advantages include simplicity, low cost, low noise, and low ripple. However, their output power is typically below 10 W, and their efficiency is often low, leading to heat generation. Linear regulators can only perform step-down regulation, whereas SMPS can utilize buck, boost, or buck-boost topologies to step voltages up, down, or invert polarities.

Switch-Mode Power Supply Systems

Most modern televisions, personal computers, DC motor drivers, and power amplifiers require advanced, high-efficiency SMPS devices. These devices utilize semiconductor switching technology instead of conventional linear methods to deliver output voltages. A basic switching converter consists of a power-switching stage and a control circuit. SMPS offers lower power dissipation and higher efficiency by operating internal transistors (or power MOSFETs) in saturated "ON" and cutoff "OFF" states.

Buck Switching Regulators

The LM2596x series from SLKOR Semiconductor provides high-efficiency DC/DC buck converters, making them a compact solution for applications requiring efficient power conversion, such as automotive and industrial designs. The LM2596x integrates a fixed-frequency oscillator and frequency compensation module.

Its design simplicity requires minimal external components. The chip also features built-in enable with hysteresis, over-temperature protection, overcurrent protection, and secondary overcurrent protection. During secondary overcurrent events, the chip reduces the operating frequency from 150 kHz to 50 kHz. An example is the LM2596S-ADJ buck switching regulator (Figure 1).

Figure 1: LM2596S-ADJ buck switching regulator delivers stable output voltage. (Image credit: SLKOR Semiconductor)

The LM2596SX-12 buck switching regulator (Figure 2) is a 150 kHz fixed-frequency PWM DC/DC converter. It offers a 3A output current drive capability with high efficiency, low ripple, and excellent line/load regulation. Utilizing PWM modulation, the chip supports a linear duty cycle range of 0–100%.

This device not only provides excellent transient response but also occupies minimal PCB area. Its compact package and high power density make it ideal for LCD displays, TVs, digital photo frames, set-top boxes, modems, telecommunication devices, and network equipment.

Figure 2: LM2596SX-12 buck switching regulator meets low-voltage requirements. (Image credit: SLKOR Semiconductor)

Boost Switching Regulators

The SL2733 is a DC/DC boost converter designed to deliver precise constant current for driving multiple LEDs. With a fixed 1 MHz switching frequency, the SL2733 can be paired with small external ceramic capacitors and inductors. The output current is adjustable via an external resistor (R1), enabling the device to drive multiple LEDs in series. The SL2733 is suitable for driving identical LEDs, supporting up to nine white LEDs in series or a maximum drive voltage of 32 V. LED brightness can be adjusted using a DC voltage, logic signal, or pulse-width modulation (PWM) signal. The shutdown (SHDW) pin allows the device to operate in a low-quiescent-current power-down mode. In addition to thermal protection and overload current limiting, the chip enters an ultra-low-power mode during LED open-circuit faults. It is housed in a compact SOT23-5 package.

Smaller Is Better

Using the SL2188 reduces the number of external components. This device supports compact external components while its soft-start feature minimizes inrush current. It handles a wide range of current loads and integrates a power MOSFET capable of supporting peak switching currents exceeding 1 A, with an output voltage of up to 3.6 V. This versatile, high-power, and compact design is ideal for single-cell lithium battery products, including two- and three-cell alkaline, NiMH, or NiCd battery systems. Boost converters like the SL2188 are ideal for wireless peripherals, gaming accessories, personal medical devices, and portable media players. Rapid technological advancements continue to drive smaller form factors. Compared to SOP-J8, the SOT23-packaged SL2188 significantly reduces required PCB area.

Figure 3: As component designs shrink, miniaturized packages (e.g., SOT23) become essential. (Image credit: SLKOR Semiconductor)

Maximizing Efficiency While Reducing Power Consumption

The demand for miniaturization remains a driving force, alongside the need to maintain reliability and power efficiency. The SY8120B buck switching regulator (Figure 4) offers a compact design with adjustable output and reliable power delivery.

Figure 4: SY8120B is a buck switching regulator that reliably delivers power in a smaller, more compact design. (Image credit: SLKOR Semiconductor)

Some may assume miniaturization sacrifices load capability or reliable power delivery, but this is not the case. The SY8120B achieves high conversion efficiency while reducing power consumption (Figure 5). By providing low standby current, battery-powered devices minimize idle-state power draw. Additionally, constant on-time control enables efficient light-load operation.

Figure 5: Designers seek high-efficiency DC/DC buck converters that deliver power reliably. (Image credit: SLKOR Semiconductor)

Flyback Converters for AC/DC and DC/DC Applications

A flyback converter is a buck-boost topology incorporating a flyback transformer. It is suitable for both AC/DC and DC/DC conversion, providing electrical isolation between input and output. It also offers voltage ratio multiplication and isolation benefits. Isolated power converters employ two control schemes: voltage-mode control and current-mode control. For stable operation, current-mode control is typically preferred.

Buck-Boost DC/DC Converters

A buck-boost converter is a classic DC/DC converter whose output voltage magnitude can be higher or lower than the input voltage. It can also generate negative voltages. Similar to a flyback converter, it uses a single inductor instead of a transformer. Specifically, the buck-boost converter comprises two distinct topologies capable of generating output voltages ranging from above the input voltage down to zero. DC/DC power supplies, sometimes called "choppers," include a buck-boost circuit that functions as either a boost or buck converter depending on the duty cycle.

Conclusion

High-efficiency power conversion in modern automotive and industrial designs relies on switching regulators. As designs grow increasingly compact, the demand for versatile, high-efficiency devices capable of maintaining stable power levels has never been greater. Though switching regulators may be referred to by various names — SMPS, DC/DC switching regulators, converters, or regulators—SLKOR offers a wide range of compact solutions for applications requiring efficient power conversion.

Switching regulators hold significant value in electronic system design, providing stable, efficient power conversion with miniaturization and multi-functionality. They are widely adopted across numerous fields. Through this article, we have gained a deeper understanding of the fundamental concepts and types of switching regulators, the differences between linear regulators and SMPS, and SLKOR’s high-efficiency switching regulator products and their applications.

What are your experiences or questions regarding switching regulator design and applications? Share your thoughts in the comments!

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