RC5040 and RC5042 Description

APPLICATION NOTE	AN42

RC5040 and RC5042 Description

Simple Step-Down Converter

S1	L1
			+
VIN	D1	C1	RL Vout
			–
			65-AP42-01

Figure 1. Simple Buck DC-DC Converter

Figure 1 illustrates a step-down DC-DC converter with no feedback control. The basic step-down converter serves as the basis for deriving the design equations for the RC5040 and RC5042. From Figure 1, the basic operation begins by closing the switch S1, so that the input voltage VIN is impressed across inductor L1. The current ﬂowing through this inductor is given by the following equation:

IL =	(VIN – VOUT )TON
	----------------------------------------------L1

where TON is the duty cycle (the time when S1 is closed).

When S1 opens, the diode D1 conducts the inductor

current and the output current is delivered to the load accord- ing to the following equation:

IL =	VOUT(TS – TON )
	------------------------------------------L1-

where TS is the overall switching period and (TS – TON) is the time during which S1 is open.

By solving these equations you can obtain the basic relation- ship for the output voltage of a step-down converter:

 TON

V = V  ----------

OUT IN TS

In order to obtain a more accurate approximation for VOUT, we must also include the forward voltage VD across diode D1 and the switching loss, VSW. After taking into account these factors, the new relationship becomes:

VOUT	= (VIN	+ VD	TON
			– VSW )----------– VD
			TS

Where VSW = IL • RDS,ON.

The RC5040 and RC5042 Controllers

The RC5040 is a programmable synchronous-mode DC-DC converter controller. The RC5042 is a non-synchronous ver- sion of the RC5040. When designed with the appropriate external components, either device can be conﬁgured to deliver more than 14.5A of output current. During heavy loading conditions, these controllers function as current- mode PWM step-down regulators. Under light loads, they function in PFM (pulse frequency modulation) or pulse skip- ping mode. The controllers sense the load level and switch between the two operating modes automatically, thus opti- mizing efﬁciency under all loads. The key differences between the RC5040 and RC5042 are listed in Table 4.

Table 4. RC5040 and RC5042 Differences

	RC5040	RC5042

Operation	Synchronous	Non-Synchronous

Package	20-pin SOIC	16-pin SOIC

Output Enable/	Yes	No
Disable

Refer to the RC5040 Block Diagram illustrated in Figure 2. The control loop of the regulator contains two main sections: the analog control block and the digital control block. The analog block consists of signal conditioning ampliﬁers feed- ing into a set of comparators which provide the inputs to the digital block. The signal conditioning section accepts inputs from the IFB (current feedback) and VFB (voltage feedback) pins and sets two controlling signal paths. The voltage con- trol path ampliﬁes the VFB signal and presents the output to one of the summing ampliﬁer inputs. The current control path takes the difference between the IFB and VFB and pre- sents the result to another input of the summing ampliﬁer. These two signals are then summed together with the slope compensation input from the oscillator. This output is then presented to a comparator, which provides the main PWM control signal to the digital control block.

The additional comparators in the analog control section sets the threshold for when the RC5040 enters PFM mode during light loads and the point when the current limit comparator disables the output drive signals to the MOSFETs.

The digital control block is designed to take the comparator inputs along with the main clock signal from the oscillator and provide the appropriate pulses to the HIDRV and LODRV pins that control the external power MOSFETs. The digital section was designed utilizing high speed Schottky transistor logic, thus allowing the RC5040 to operate at clock speeds as high as 1MHz.

RC5040, RC5042 specifications

The Fairchild RC5042 and RC5040 are versatile integrated circuits that stand out in the realm of high-performance analog applications. Designed to meet the demands of modern electronic systems, these devices integrate various features and technologies that contribute to their effectiveness in a multitude of applications.

The RC5040 is a precision voltage reference that offers a stable, low-noise output, making it ideal for applications such as instrumentation, data acquisition systems, and RF circuits. It boasts an operating temperature range of -40°C to +85°C, ensuring reliability in diverse environments. One of its most significant characteristics is its low-temperature drift, which minimizes variations in output voltage over temperature fluctuations, thereby enhancing the accuracy of devices that utilize it.

On the other hand, the RC5042 is designed as a high-speed comparator with an integrated voltage reference. This dual functionality allows for a more compact design in applications where space is a premium. The RC5042 features an ultra-fast response time and high input impedance, which contribute to its capability to handle rapidly changing signals without distortion. This makes it particularly useful in applications like analog signal processing and threshold detection.

Both devices utilize Fairchild's advanced BiCMOS technology, which combines the benefits of bipolar and CMOS processes. This technology allows the devices to operate with low power consumption while maintaining high speed and operational efficiency. The RC5042 and RC5040 also incorporate noise-reduction techniques, which help in minimizing unwanted disturbances that could impact circuit performance.

Another noteworthy characteristic of both the RC5040 and RC5042 is their ease of integration. They come in compact package sizes, making them easier to incorporate into various designs without compromising on performance. Furthermore, the availability of multiple output options allows engineers the flexibility to choose configurations that best suit their specific applications.

In conclusion, the Fairchild RC5042 and RC5040 are robust devices that offer essential functionality for various high-performance analog applications. With their precision, fast response time, and exceptional reliability, these integrated circuits are a valuable asset in the design of modern electronic systems, catering to the growing demands of the technology landscape.