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How to use LM5117 Chip to Design Buck Circuit

  • Contents

I Description

In this blog, you will see how we use the LM5117 chip developed by TI to design a buck circuit. LM5117 chip has broad market prospects. That's because, this chip has the advantages of high frequency, high efficiency, low ripple, and simplified circuit design. Also, the power supply designed with LM5117 not only has good stability, but also high reliability. And these are the reasons why it is very suitable for occasions with high power requirements.

lm5117

Catalog

I Description

II Introduction to LM5117 Chip

III Buck Circuit Design

3.1 Design Requirements

3.2 Design Principle

IV Experimental Results

V Summary

VI FAQ

Ordering & Quantity

II Introduction to LM5117 Chip

LM5117 is suitable for high-voltage or various input power buck regulator applications. And, these applications often need current mode control that simulates current ramps. The internal structure of the LM5117 chip is shown in Figure 1. Its main features are:

  1.  5.5V~65V wide voltage range output.
  2.  The operating frequency can be set in the range of 55kHz~750kHz.
  3.  Optional diode emulation mode to improve power efficiency under light load.
  4.  0.8V programmable output, voltage reference with 1.5% accuracy.
  5.  With analog current monitor, real-time monitoring of current value.
  6.  With discontinuous mode current protection.
  7.  The current mode control of the simulated current ramp reduces the noise sensitivity of the pulse width modulation circuit.

The following table briefly introduces the functions of all 20 pins of LM5117:

Pin Number

Pin Function

Pin 1

UVLO is the under-voltage lockout pin. The voltage regulator is shut down below 0.4V, and the voltage regulator is in standby mode when it is greater than 0.4V and less than 1.25V. The voltage regulator above 1.25V works normally and stably.

Pin 2

DEMB is a diode emulation mode pin, which can be floated if not needed.

Pin 3

RES restarts the timer pin and can configure hiccup current-limiting mode.

Pin 4

SS can set the internal reference slope of the internal error amplifier.

Pin 5

RT sets the clock frequency and the maximum frequency can be configured to 750kHz, just connect a resistor between ground, and connect a capacitor to synchronize to the external frequency.

Pin 6

Ground

Pin 7

VCCDIS is an optional input pin for disabling the regulator.

Pin 8

FB feedback pin is used to stabilize the set output, and the reference base is 0.8V.

Pin 9

COMP is the output of the internal error amplifier

Pin 10

CM is the output of the current monitor, which can detect the average current value for programming.

Pin 11

feet RAMP is the PWM ramp signal.

Pin 12

CS is the current detection input pin.

Pin 13

Ground

Pin 14

Ground

Pin 15

Pin 15 is the bottom MOS output drive pin.

Pin 16

Pin 16 is the VCC power bias pin

Pin 17

SW is the switch node of the buck regulator and provides a bootstrap loop.

Pin 18

HO is high bridge MOS drive output

Pin 19

HB is Gaoqiao bootstrap power input

Pin 20

VIN is the power supply voltage input source of VCC regulator

And the following part is the internal structure of LM5117:

lm5117 internal structure

Figure 1. LM5117 Internal Structure

III Buck Circuit Design

3.1 Design Requirements

Design a step-down DC switching power supply with TI's step-down controller LM5117 chip as the core device. The circuit design reference diagram is shown in Figure 2. The rated input DC voltage UIN=16V, the rated output DC voltage Uo=5V, and the maximum output current is IOmax=3A. The specific parameter requirements are:

1. Under the rated input voltage, the output voltage deviation |ΔU|=|5V-Uo|≤100mV;

2. Peak-to-peak output noise ripple: UOPP≤50mV (UIN=16V, IO=IOmax);

3. When the output Io is from 3A at full load to 0.6A at light load, load regulation rate:

Si=|(UO light load/ UO full load)-1|×100%≤5%(UIN=16V);

4. UIN changes to 17.6V and 13.6V, voltage adjustment rate:

Sv={max(|Uo(17.6V)-Uo(16V)|, |Uo(16V)-Uo(13.6V)|)/ Uo(16V)}× 100%≤0.5%

  RL=Uo(16V)/ IOmax

5. The power efficiency is greater than 85% (under rated conditions);

6. The protection current value is set to 3.2A;

7. With load port identification function, that is, Uo=R/1kΩ(V).

circuit design

  Figure 2. Circuit Design Diagram

3.2 Design Principle

According to the design requirements in Section 3.1, this article designs a DC step-down circuit with a rated output of 5V/3A  as shown in Figure 3. The circuit uses a half-bridge structure to improve circuit efficiency. The following is a detailed analysis of the circuit:

  • When Q1 turns on, the inductor L charges.
  • When Q1 is off, Q2 conducts freewheeling to achieve the voltage reduction function.
  • R1, R2 voltage division power supply undervoltage lockout pin UVLO, the voltage value of this pin is greater than 1.25V during normal operation.
  • R3 and C6 provide chip startup power.
  • D1 and C13 form a bootstrap circuit to provide the upper bridge Q1 drive.
  • R7 and R8 are drive current limiting resistors.
  • R4 is connected between RT and GND to provide the operating frequency. In this design, the switching frequency is set to 230kHz. According to the calculation formula provided in the manual, RT=5.2×109/ fsw-948Ω, and R4 can be calculated to be approximately 21.7kΩ.
  • C7 is the current-limiting capacitor for restart hiccups, and C8 is the capacitor for setting the reference slope of the error amplifier.
  • C12 is a PWM slope compensation capacitor to improve chip adjustment efficiency.
  • R9 is a current sampling resistor, connected to pins 12 and 13. According to the internal structure diagram in Figure 1, this pin is the positive and negative input of the internal current sampling amplifier, which is amplified by 10 times.
  • C14 is the input filter capacitor.
  • R6 and C11 are the internal current monitor output filter circuit, this output can output the sampled current value for programming or display.
  • R11 and R12 form an output voltage divider feedback circuit, which feeds back the voltage to pin 8 of the chip to stabilize the output voltage of 5V. Since the internal reference voltage value of the chip is 0.8V, the resistance value can be determined according to the formula (1+R11/R12)×0.8V=Uout. Because the design requires a stable output of 5V, the resistance values are set to 5.25kΩ and 1kΩ.
  • C10, R5, and C9 are connected to the output of the feedback circuit and the internal error amplifier to form a loop compensation network.
  • D2, D3, and R10 provide output power to the VCC pin, and use output feedback to supply power to reduce input high-voltage power supply efficiency loss.

lm5117 buck circuit

  Figure 3. LM5117 Buck Circuit

3.2.1 Short Circuit Protection

The circuit design needs to have a circuit protection function. According to the chip manual, there are two ways to realize this function:

(1) Utilize UVLO foot to realize electric current protection. The current monitor CM determines the output current protection value. Determine the high and low levels of the UVLO pin according to the protection value. If the protection value is reached, set the undervoltage latch pin to a high level of 5V, and set it to 0 to make it work normally if it is below the protection value. Figure 4 is a schematic diagram of the protection realization principle.

utilize UVLO pin to realize current protection structure

  Figure 4. Utilize UVLO Pin to Realize Current Protection Sructure 

(2) Use current feedback closed-loop control to lock the PWM output to achieve protection. How to close the output and realize the purpose of current protection?

According to Figure 1, the current is amplified by 10 times through the sampling circuit, and compared with 10UCS(th), the output of the R/S latch is determined with the PWM comparator.

This method only needs to determine the current sampling resistance to achieve current protection. The sampling resistance is calculated according to the internal structure:

  R9=10Uch(th)/(10×3.2A)=10×0.12V/(10×3.2A)=37.5mΩ.

Compared with the above solutions, it is found that the implementation of the second method is simpler. This design chooses the second scheme to realize the 3.2A protection function. The chip provides powerful peripheral functions, greatly improving the efficiency of circuit design.

3.2.2 Resistance follow output

The circuit design requires the realization of voltage follow resistance output, that is, it has the function of port recognition, and can realize Uo=R1kΩ(V) follow output: 1kΩ resistance value corresponds to 1V output, 2kΩ corresponds to 2V output, and 10kΩ corresponds to 10V output.

 According to the analysis of the circuit principle, the tracking function can be realized by adjusting the feedback voltage value.The design circuit structure is shown as in Fig. 5.

The output voltage in the figure is finally output to the feedback FB pin after two stages of reverse amplification. According to the calculation relationship in the figure:

  • Uout×{-(8kΩ/R)}×{-(1kΩ/1kΩ)}=0.8V is calculated;
  • Uout=R is obtained to realize the tracking function.

resistance follower output interface circuit

Figure 5. Resistance Follower Output Interface Circuit

IV Experimental Results

According to the design requirements, a step-down power supply circuit with DC 5V/3A output is produced. Besides, parameter tests can also be performed together. The results are shown in Table 1. According to Table 1 and the design requirements, the calculation method is provided, and the design output voltage deviation of 5V is less than 100mV. The load regulation rate of 0.69% is far less than the design requirement of 5%. The voltage regulation rate of 0.02% is sufficiently less than 0.5%. The circuit power can reach 88.6% when running at rated power. At the same time, the circuit has a 3.2A current protection action and a load port identification function. And this fuction can accurately track resistance changes from 1kΩ to 10kΩ.

Ripple design is an important part of the circuit design. At the same time, reducing noise ripple is also one of the main features of this chip. The chip provides a COMP error compensation pin. According to the manual, it can be known that a reasonable setting of the compensation capacitor resistance value of this pin can greatly reduce the noise ripple. At the same time, you need to pay attention to the following points:

  1. The chip PCB design requirements are relatively high;

  2. The circuit is reasonably wired;

  3. The circuit is coated with copper;

  4. The chip heat dissipation, etc.

So as to optimize the circuit performance.

The circuit ripple test waveform is shown in Figure 6. It can be seen from the figure that the circuit ripple is controlled within 10mV, and the occasional noise ripple does not exceed 40mV. Therefore, the circuit designed in this way can fully meet the circuit design requirements.

Table 1: LM5117 step-down power supply circuit test parameters

waveform of ripple test

Figure 6. Waveform of Ripple Test

V Summary

As a switching power supply step-down chip, LM5117 improves the stability of the switching power supply. It can directly drive dual-bridge MOS transistors. It also provides a wealth of expansion units, including current monitoring, with excellent performance. This design makes full use of the control function of the LM5117 chip. And it also realize a high-performance, high-efficiency and high-stability switching power supply.

VI FAQ

What is lm5117?

Synchronous buck controller

 

What type of applications are LM5117 suitable for?

High-voltage or various input power buck regulator applications.

 

How many pins does LM5117 have?

20 pins

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