Fairchild RC5042, RC5040 specifications Resistor mΩ, = 2000mi

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AN42

APPLICATION NOTE

Table 8. Rsense for various load currents

ILoad,max

RSENSE

RSENSE

PC Trace

Discrete

(A)

Resistor (mΩ)

Resistor (mΩ)

 

 

 

10.0

6.5

8.6

 

 

 

11.2

5.8

7.8

 

 

 

12.4

5.3

7.1

 

 

 

13.9

4.8

6.4

 

 

 

14.0

4.7

6.3

 

 

 

14.5

4.6

6.1

 

 

 

Discrete Sense Resistor

Discrete iron alloy resistors come in a variety of tolerances and power ratings, and are ideal for precision implementa- tions. Either an MnCu alloy wire resistor or an CuNi alloy wire resistor is ideal for a low cost implementation.

Embedded Sense Resistor (PC Trace Resistor)

Embedded PC trace resistors have the advantage of almost zero cost implementation. However, the value of the PC trace resistors have large variations. Embedded resistors have 3 major error sources: the sheet resistivity of the inner layer, the mismatch due to L/W, and the temperature varia- tion of the resistor. When laying out embedded sense resis- tors, consider all error sources described as follows:

Sheet resistivity.

For 1 ounce copper, the thickness variation is typically between 1.15 mil and 1.35 mil. Therefore, the error due to sheet resistivity is (1.35 – 1.15)/1.25 = 16%.

Mismatch due to L/W.

The error in L/W is dictated by the geometry and the power dissipation capability of the sense resistor. The sense resistor must be able to handle the load current and, therefore, requires a minimum width, calculated as follows:

IL

W = ---------

0.05

where W is the minimum width required for proper power dissipation (mils), and IL is the load current in Amps.

For a load current of 15A, the minimum width required is 300mils, which reflects a 1% L/W error.

Thermal Considerations.

The I2R power losses cause the surface temperature of the resistor to increase along with its resistance value. In addition, ambient temperature variations add the change in resistor value:

R = R20[1 + α20(T – 20)]

where R20 is the resistance at 20°C, α20 = 0.00393/ °C,T is the operating temperature, andR is the desired value.

For temperature T = 50°C, the %R change = 12%.

Table 9 is a summary of tolerances for the Embedded PC Trace Resistor.

Table 9. Summary PC Trace Resistor Tolerance

Tolerance due to sheet resistivity variation

16%

 

 

Tolerance due to L/W error

1%

 

 

Tolerance due to temperature variation

12%

 

 

Total Tolerance for PC Trace Resistor

29%

 

 

Design rules for using an embedded resistor

The basic equation for laying an embedded resistor is:

L

 

L

 

 

 

R = ρ ⋅ W------------t

W

 

t

 

 

 

 

where ρ is the Resistivity (W-mil), L is the Length (mils), W is the Width (mils), and t is the Thickness (mils).

For 1oz copper, t = 1.35 mils, ρ = 717.86 ∝Ω-mil, 1 L/1 W = 1 Square ( ).

For example, you can layout a 5.30mΩ embedded sense resistor. From Equations above,

 

IL

 

10

 

 

W = 0.05---------

= 0.05---------

= 200mil

 

L =

R-----------------------W t

=

--------------------------------------------------0.00530200 1.35

= 2000mi

 

ρ

 

 

717.86

 

L/W = 10 .

Therefore, to model 5.30mΩ enbedded resistor, you need W = 200 mils, and L = 2000 mils. See Figure 10.

1 1 1 1 1 1 1 1 1 1

W = 200 mils

L = 2000

Figure 10. 5.30mΩ Sense Resistor (10 )

You can also implement the sense resistor in the following manner. Each corner square is counted as 0.6 square since the current flowing through the corner square does not flow uniformly, concentrated towards the inside edge. This is shown in Figure 11.

1

1

1

1

1

1

.6

 

 

 

 

.6

1

 

 

 

 

1

.8

 

 

 

 

 

Figure 11. 5.30mΩ Sense Resistor (10 )

A Resign Example Combining an Embedded Resistor with a Discrete Resistor

For low cost implementation, the embedded PC trace resistor is the most desirable alternative, but, as discussed earlier, the wide tolerance (±29%) presents a challenge. In addition, changing CPU requirements may force the maximum load

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Contents Pentium Pro DC Power Requirements IntroductionInput Voltages DC Voltage RegulationOutput Ripple and Noise EfficiencyProcessor Voltage Identification ControlsRC5040 and RC5042 Description Simple Step-Down ConverterRC5040 and RC5042 Controllers Power Good Pwrgd Output Enable OutenUpgrade Present UP# Main Control LoopDesign Considerations and Component Selection Over-Voltage ProtectionShort Circuit Protection OscillatorRC5042 Mosfet Selection Two MOSFETs in ParallelThermal Conditions1 Manufacturer & Model # Typ MaxCharge Pump or Bootstrap Mosfet Gate BiasConverter Efficiency Selecting the Inductor Implementing Short Circuit ProtectionShort Circuit Comparator Discrete Metal DescriptionResistor IRC ResistorResistor mΩ = 2000miRC5040 and RC5042 Short Circuit Current Characteristics For each Mosfet⋅ .2 = 0.74W Schottky Diode Selection Schottky Diode Selection Table Output Filter CapacitorsInput filter Bill of MaterialsPCB Layout Guidelines and Considerations PCB Layout GuidelinesMotorola Shottky Diode 320-6110Example of Proper MOSFETs Placements PC Motherboard Layout and Gerber FileApplication Note Troubleshooting Guidelines for Debugging and Performance EvaluationsDebugging Your First Design Implementation Performance Evaluation Vout+ 80.0mV Device Description Iload =13.9ASummary RC5040/RC5042 Evaluation BoardAppendix a Directory of Component Suppliers Life Support Policy

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.