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In electronic engineering, a DC to DC converter is a circuit which converts a source of direct current (DC) from one voltage level to another. It is a class of power converter.

Contents 1 Usage 2 Conversion methods 2.1 Electronic 2.1.1 Linear 2.1.2 Switched-mode conversion 2.1.2.1 Magnetic 2.1.2.2 Capacitive 2.2 Electrochemical 3 Terminology 3.1 Step down 3.2 Step up 3.3 Continuous Current Mode 3.4 Discontinuous Current Mode 4 See also 5 References 6 External links

DC to DC converters are important in portable electronic devices such as cellular phones and laptop computers, which are supplied with power from batteries. Such electronic devices often contain several sub-circuits with each sub-circuit requiring a unique voltage level different than that supplied by the battery (sometimes higher or lower than the battery voltage, and possibly even negative voltage). Additionally, the battery voltage declines as its stored power is drained. DC to DC converters offer a method of generating multiple controlled voltages from a single variable battery voltage, thereby saving space instead of using multiple batteries to supply different parts of the device.

Linear regulators drop the input voltage to a lower output voltage. They are inefficient, as they convert the dropped voltage into heat dissipation.

Linear regulators are much simpler than switching DC-DC converters. However, unlike switching DC-DC converters, linear regulators cannot generate:

• higher voltages
• higher currents
• voltages of the opposite polarity

An even simpler approach is to use a resistor in series with the voltage supply. That resistor and the load form a voltage divider resulting in a lower voltage. However, this method offers no regulation.

Electronic switch-mode DC to DC converters convert one DC voltage level to another, by storing the input energy temporarily and then releasing that energy to the output at a different voltage. The storage may be in either magnetic components (inductors, transformers) or capacitors. This conversion method is more power efficient (often 80% to 98%) than linear voltage regulation (which dissipates unwanted voltage as heat). This efficiency is beneficial to increasing the running time of battery operated devices. Drawbacks of switching converters include cost, complexity and electronic noise (EMI / RFI).

DC to DC converters are now available as integrated circuits needing minimal additional components. DC to DC converters are also available as a complete hybrid circuit component, ready for use within an electronic assembly.

These DC to DC converters convert one DC voltage to another by storing energy into a magnetic component (an inductor or a transformer) for a period of time (usually in the 30 kHz to 5 MHz range). By adjusting the PWM Duty Cycle (the ratio of on/off time), the amount of power transferred can be controlled. Usually, this is done to control the output voltage, though it could be done to control the input current, the output current, or maintaining a constant power. Transformer based converters may provide isolation between the input and the output. In general, the term "DC to DC converter" refers to one of these switching converters. These circuits are the heart of a switched-mode power supply.

Many topologies exist. This table shows the most common.

	Forward Energy goes from the input, through the the magnetics and to the load, simultaneously	Flyback Energy goes from the input and stored in the magnetics Later, it is released from the magnetics to the load
No transformer Non-isolated	Step-down (Buck) - The output voltage is lower than the input voltage, and of the same polarity	Non-inverting: The output voltage is the same polarity as the input Step-up (Boost) - The output voltage is higher than the input voltage SEPIC - The output voltage can be lower or higher than the input Inverting: the output voltage is of the opposite polarity as the input Inverting (Buck-Boost) Ćuk - Output current is continuous
	True Buck-Boost - The output voltage is the same polarity as the input and can be lower or higher
With transformer May be isolated	Push-pull (Half bridge) - 2 transistors drive Full bridge - 4 transistor drive	Flyback - 1 transistor drive

In addition, each topology may be:

• Hard switched - transistors switch quickly while exposed to both full voltage and full current
• Resonant - an LC circuit shapes the voltage across the transistor and current through it so that the transistor switches when either the voltage or the current is zero

Magnetic DC to DC converters may be operated in two modes, according to the current in its main magnetic component (inductor or transformer):

• Continuous - the current fluctuates but never goes down to zero
• Discontinuous - the current fluctuates during the cycle goes down to zero at the end of each cycle

A converter may be designed to operate in Continuous mode at high power, and in Discontinuous mode at low power.,

Switched capacitor converters rely on alternately connecting capacitors to the input and output in differing topologies. For example, a switched-capacitor reducing converter might charge two capacitors in series and then discharge them in parallel. This would produce an output voltage of half the input voltage, but at twice the current (minus various inefficiencies). Because they operate on discrete quantities of charge, these are also sometimes referred to as charge pump converters. They are typically used in applications requiring relatively small amounts of current, as at higher current loads the increased efficiency and smaller size of switch-mode converters makes them a better choice. They are also used at extremely high voltages, as magnetics would break down at such voltages.

A further means of DC to DC conversion in the kW to many MW range is presented by using redox flow batteries such as the vanadium redox battery, although this technique has not been applied commercially to date.

A converter that outputs a voltage lower than the input.

A converter that outputs a voltage higher than input.

Current and thus the magnetic field in the energy storage never reach zero.

Current and thus the magnetic field in the energy storage may reach or cross zero.

• Switched-mode power supply

• Rudy P. Severns, G. Ed Bloom (1985). Modern DC-DC Switchmode Power Conversion Circuits. Van Nostrand Reinhold. Out of Print.
• George C. Chryssis (1989). High Frequency Switching Power Supplies: Theory and Design. McGraw-Hill. ISBN 0070109516.
• Andre S. Kislovski, Richard Redl, Nathan O. Sokal (1991). Dynamic Analysis of Switching-Mode DC/DC Converters. Van Nostrand Reinhold. ISBN 0442239165.
• Yim-Shu Lee (1993). Computer-Aided Analysis and Design of Switch-Mode Power Supplies. Marcel Dekker. ISBN 0824788036.
• Abraham I. Pressman (1997). Switching Power Supply Design. McGraw-Hill. ISBN 0-07-052236-7.
• Philip T. Krein (1997). Elements of Power Electronics. Oxford University Press. ISBN 0195117018.
• Robert W. Erickson, Dragan Maksimovic (2001). Fundamentals of Power Electronics. Kluwer Academic Publishers. ISBN 9780792372707.
• Ned Mohan, Tore M. Undeland, William P. Robbins (2002). Power Electronics : Converters, Applications, and Design. Wiley. ISBN 0-471-22693-9.
• Chi Kong Tse (2003). Complex Behavior of Switching Power Converter. CRC Press. ISBN 0849318629.

• A general description of DC-DC converters.
• A beginner's guide to switching regulators.
• Power Electronics Books
• Switching regulator application note for LCD Power supply
• Switching Regulator Simulator