ZHCSFV3 November   2016 LM53602 , LM53603

PRODUCTION DATA.  

  1. 特性
  2. 应用
  3. 说明
  4. 修订历史记录
  5. Device Comparison Table
  6. Pin Configuration and Functions
  7. Specifications
    1. 7.1 Absolute Maximum Ratings
    2. 7.2 ESD Ratings
    3. 7.3 Recommended Operating Conditions
    4. 7.4 Thermal Information
    5. 7.5 Electrical Characteristics
    6. 7.6 System Characteristics
    7. 7.7 Timing Requirements
    8. 7.8 Typical Characteristics
  8. Detailed Description
    1. 8.1 Overview
    2. 8.2 Functional Block Diagram
    3. 8.3 Feature Description
      1. 8.3.1 RESET Flag Output
      2. 8.3.2 Enable and Start-Up
      3. 8.3.3 Current Limit
      4. 8.3.4 Synchronizing Input
      5. 8.3.5 Input Supply Current
      6. 8.3.6 UVLO and TSD
    4. 8.4 Device Functional Modes
      1. 8.4.1 AUTO Mode
      2. 8.4.2 FPWM Mode
      3. 8.4.3 Dropout
      4. 8.4.4 Input Voltage Frequency Fold-Back
  9. Application and Implementation
    1. 9.1 Application Information
    2. 9.2 Typical Applications
      1. 9.2.1 Typical and Full-Featured Industrial Application Circuits
        1. 9.2.1.1 Design Parameters
        2. 9.2.1.2 Detailed Design Procedure
          1. 9.2.1.2.1 Setting the Output Voltage
          2. 9.2.1.2.2 Output Capacitors
          3. 9.2.1.2.3 Input Capacitors
          4. 9.2.1.2.4 Inductor
          5. 9.2.1.2.5 VCC
          6. 9.2.1.2.6 BIAS
          7. 9.2.1.2.7 CBOOT
          8. 9.2.1.2.8 Maximum Ambient Temperature
        3. 9.2.1.3 Application Curves
    3. 9.3 Typical Adjustable Industrial Application Circuit
      1. 9.3.1 Design Parameters for Typical Adjustable Output Industrial Power Supply
    4. 9.4 Do's and Don't's
  10. 10Power Supply Recommendations
  11. 11Layout
    1. 11.1 Layout Guidelines
      1. 11.1.1 Ground and Thermal Plane Considerations
    2. 11.2 Layout Example
  12. 12器件和文档支持
    1. 12.1 器件支持
      1. 12.1.1 Third-Party Products Disclaimer
      2. 12.1.2 开发支持
    2. 12.2 文档支持
      1. 12.2.1 相关文档 
    3. 12.3 相关链接
    4. 12.4 接收文档更新通知
    5. 12.5 社区资源
    6. 12.6 商标
    7. 12.7 静电放电警告
    8. 12.8 Glossary
  13. 13机械、封装和可订购信息

封装选项

机械数据 (封装 | 引脚)
散热焊盘机械数据 (封装 | 引脚)
订购信息

Application and Implementation

NOTE

Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI's customers are responsible for determining the suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.

Application Information

The LM53603 and LM53602 are step-down DC-DC converters, typically used to convert a higher DC voltage to a lower DC voltage with a maximum output current of either 3 A or 2 A. The following design procedure can be used to select components for the LM53603 or LM53602. Alternately, the WEBENCH® Design Tool may be used to generate a complete design. This tool uses an iterative design procedure and has access to a comprehensive database of components. This allows the tool to create an optimized design and allows the user to experiment with various design options.

Typical Applications

Typical and Full-Featured Industrial Application Circuits

Figure 15 shows the minimum required application circuit for the fixed output voltage versions, while Figure 16 shows the connections for complete processor control of the LM53603. See these figures while following the design procedures. Table 2 provides an example of typical design requirements.

automotive buck regulator schematic power supply LM53602 LM53603 typ_app_cir5_fixed.gif Figure 15. Typical Industrial Power Supply Schematic
automotive buck regulator schematic power supply programmable micro
				controller LM53602 LM53603 typ_app_cir5_fixed_features.gif Figure 16. Full-Featured Industrial Power Supply Schematic

Design Parameters

There are a few design parameters to take into account. Most of those choices decide which version of the device to use. The desired output current steers the designer toward a LM53602 type or LM53603 type part. If the output voltage is 3.3 V or 5 V, a fixed output version of the device can be used. Any other voltage level within the tolerance of the part can be achieved by using an adjustable version of the device. Most but not all parameters are independent of the of the IC choice. The output filter components (inductor and output capacitors) might vary with the choice of output voltage, especially for output voltages higher than 5 V. See Detailed Design Procedure for help in choosing these components.

Table 2. Design Parameters

DESIGN PARAMETER EXAMPLE VALUE
Input voltage 12 V
Output voltage 5 V
Maximum output current 3 A

Detailed Design Procedure

The following detailed design procedure applies to Figure 15, Figure 16, and Figure 45.

Setting the Output Voltage

For the fixed output voltage versions, the FB input is connected directly to the output voltage node. Preferably, near the top of the output capacitor. If the feed-back point is located further away from the output capacitors (that is, remote sensing), then a small 100-nF capacitor may be needed at the sensing point.

For output voltages other than 5 V or 3.3 V, a feedback divider is required. For the ADJ version of the device, the regulator holds the FB pin at 1 V. The range of adjustable output voltage can be found in the Recommended Operating Conditions. Equation 3 can be used to determine RFBB for a desired output voltage and a given RFBT. Usually RFBT is limited to a maximum value of 100 kΩ.

Equation 3. LM53602 LM53603 FB_div_eq2.gif

In addition, a feed-forward capacitor CFF may be required to optimize the transient response. For output voltages greater than 6 V, the WEBENCH Design Tool can be used to optimize the design. Recommended CFF values for some cases are given in the table below. It is important to note that these values provide a first approximation only and need to be verified for each application by the designer.

Table 3. Recommended CFFcapacitors

VOUT COUT (nominal)(1) L RFBT RFBB CFF
3.2V 44µF 2.2µH 69.8kΩ 31.6kΩ 33pF
3.2V 110µF 2.2µH 69.8kΩ 31.6kΩ 120pF
5.1V 44µF 2.2µH 80.6kΩ 19.6kΩ 33pF
5.1V 110µF 2.2µH 80.6kΩ 19.6kΩ 220pF
8V 66µF 4.7µH 86.6kΩ 12.4kΩ 120pF
8V 100µF 4.7µH 86.6kΩ 12.4kΩ 220pF
10V 66µF 4.7µH 90.9kΩ 10.0kΩ 120pF
16V X7R capacitors used : C3225X7R1C226M250AC (TDK)

Output Capacitors

The LM53603 is designed to work with low-ESR ceramic capacitors. The effective value of these capacitors is defined as the actual capacitance under voltage bias and temperature. All ceramic capacitors have a large voltage coefficient, in addition to normal tolerances and temperature coefficients. Under DC bias, the capacitance value drops considerably. Larger case sizes or higher voltage capacitors are better in this regard. To help mitigate these effects, multiple small capacitors can be used in parallel to bring the minimum effective capacitance up to the desired value. This can also ease the RMS current requirements on a single capacitor. Table 4 shows the nominal and minimum values of total output capacitance recommended for the LM53603. The values shown also provide a starting point for other output voltages, when using the ADJ option. Also shown are the measured values of effective capacitance for the indicated capacitor. More output capacitance can be used to improve transient performance and reduce output voltage ripple.

In practice, the output capacitor has the most influence on the transient response and loop phase margin. Load transient testing and Bode plots are the best way to validate any given design, and should always be completed before the application goes into production. A careful study of temperature and bias voltage variation of any candidate ceramic capacitor should be made to ensure that the minimum value of effective capacitance is provided. The best way to obtain an optimum design is to use the Texas Instruments WEBENCH Design Tool.

In ADJ applications the feed-forward capacitor, CFF, provides another degree of freedom when stabilizing and optimizing the design. Application report Optimizing Transient Response of Internally Compensated dc-dc Converters With Feedforward Capacitor (SLVA289) should prove helpful when adjusting the feed-forward capacitor.

In addition to the capacitance shown in Table 4, a small ceramic capacitor placed on the output can help to reduce high frequency noise. Small case size ceramic capacitors in the range of 1 nF to 100 nF can be very helpful in reducing spikes on the output caused by inductor parasitics.

The maximum value of total output capacitance should be limited to between 300 µF and 400 µF. Large values of output capacitance can prevent the regulator from starting-up correctly and adversely effect the loop stability. If values in the range given above, or greater, are to be used, then a careful study of start-up at full load and loop stability must be performed.

Table 4. Recommended Output Capacitors

OUTPUT VOLTAGE NOMINAL OUTPUT CAPACITANCE MINIMUM OUTPUT CAPACITANCE PART NUMBER (MANUFACTURER)
RATED CAPACITANCE MEASURED CAPACITANCE(1) RATED CAPACITANCE MEASURED CAPACITANCE(1)
3.3 V 3 × 22 µF 63 µF 2 × 22 µF 42 µF C3225X7R1C226M250AC (TDK)
5 V 3 × 22 µF 60 µF 2 × 22 µF 40 µF C3225X7R1C226M250AC (TDK)
6 V 3 × 22 µF 59 µF 2 × 22 µF 39 µF C3225X7R1C226M250AC (TDK)
10 V(2) 3 × 22 µF 48 µF 2 × 22 µF 32 µF C3225X7R1C226M250AC (TDK)
Measured at indicated VOUT at 25°C.
The following components were used: CFF = 47 pF, RFBT = 100 kΩ, RFBB = 11 kΩ, L = 4. 7 µH.

Input Capacitors

The ceramic input capacitors provide a low impedance source to the regulator in addition to supplying ripple current and isolating switching noise from other circuits. Table 5 shows the nominal and minimum values of total input capacitance recommenced for the LM53603. Also shown are the measured values of effective capacitance for the indicated capacitor. In addition, small high frequency bypass capacitors connected directly between the VIN and PGND pins are very helpful in reducing noise spikes and aid in reducing conducted EMI. TI recommends that a small case size 10-nF ceramic capacitor be placed across the input, as close as possible to the device (see Figure 47). Additional high frequency capacitors can be used to help manage conducted EMI or voltage spike issues that may be encountered.

Table 5. Recommended Input Capacitors

NOMINAL INPUT CAPACITANCE MINIMUM INPUT CAPACITANCE PART NUMBER (MANUFACTURER)
RATED CAPACITANCE MEASURED CAPACITANCE (1) RATED CAPACITANCE MEASURED CAPACITANCE(1)
3 x 10 µF 22.5 µF 2 × 10 µF 15 µF CL32B106KBJNNNE (Samsung)
Measured at 14 V and 25°C.

Many times it is desirable to use an electrolytic capacitor on the input, in parallel with the ceramics. This is especially true if longs leads or traces are used to connect the input supply to the regulator. The moderate ESR of this capacitor can help damp any ringing on the input supply caused by long power leads. The use of this additional capacitor also helps with voltage dips caused by input supplies with unusually high impedance.

Most of the input switching current passes through the ceramic input capacitor(s). The approximate RMS value of this current can be calculated from Equation 4 and should be checked against the manufacturers' maximum ratings.

Equation 4. LM53602 LM53603 Irms_eq1.gif

Inductor

The LM53603 and LM53602 are optimized for a nominal inductance of 2.2 µH for the 5-V and 3.3-V versions. This gives a ripple current that is approximately 20% to 30% of the full load current of 3 A. For output voltages greater than 5 V, a proportionally larger inductor can be used. This keeps the ratio of inductor current slope to internal compensating slope constant.

The most important inductor parameters are saturation current and parasitic resistance. Inductors with a saturation current of between 5 A and 6 A are appropriate for most applications, when using the LM53603. For the LM53602, inductors with a saturation current of between 4 A and 5 A are appropriate. Of course the inductor parasitic resistance should be as low as possible to reduce losses at heavy loads. Table 6 gives a list of several possible inductors that can be used with the LM53603.

Table 6. Recommenced Inductors

MANUFACTURER PART NUMBER SATURATION CURRENT DC RESISTANCE
Würth 7440650022 6 A 15 mΩ
Coilcraft DO3316T-222MLB 7.8 A 11 mΩ
Coiltronics MPI4040R3-2R2-R 7.9 A 48 mΩ
Vishay IHLP2525CZER2R2M01 14 A 18 mΩ
Vishay IHLP2525BDER2R2M01 14 A 28 mΩ
Coilcraft XAL6030-222ME 16 A 13 mΩ

VCC

The VCC pin is the output of the internal LDO, used to supply the control circuits of the LM53603. This output requires a 3.3-µF to 4.7-µF, ceramic capacitor connected from VCC to GND for proper operation. An X7R device with a rating of 10 V is highly recommended. In general this output should not be loaded with any external circuitry. However, it can be used to supply a logic level to the FPWM input, or for the pullup resistor used with the RESET output (see Figure 16). The nominal output of the LDO is 3.15 V.

BIAS

The BIAS pin is the input to the internal LDO. As mentioned in Input Supply Current, this input is connected to VOUT to provide the lowest possible supply current at light loads. Because this input is connected directly to the output, it should be protected from negative voltage transients. Such transients may occur when the output is shorted at the end of a long PCB trace or cable. If this is likely, in a given application, then a small resistor should be placed in series between the BIAS input and VOUT, as shown in Figure 15. The resistor should be sized to limit the current out of the BIAS pin to <100 mA. Values in the range of 2 Ω to 5 Ω are usually sufficient. Values greater than 5 Ω are not recommended. As a rough estimate, assume that the full negative transient appears across RBIAS and design for a current of < 100 mA. In severe cases, a Schottky diode can be placed in parallel with the output to limit the transient voltage and current.

CBOOT

The LM53603 requires a boot-strap capacitor between the CBOOT pin and the SW pin. This capacitor stores energy that is used to supply the gate drivers for the power MOSFETs. A ceramic capacitor of 0.47 µF, ≥ 6.3 V is required. A 10-V rated capacitor or higher is highly recommended.

Maximum Ambient Temperature

As with any power conversion device, the LM53603 dissipates internal power while operating. The effect of this power dissipation is to raise the internal temperature of the converter, above ambient. The internal die temperature (TJ) is a function of the ambient temperature, the power loss and the effective thermal resistance, RθJA of the device and PCB combination. The maximum internal die temperature for the LM53603 is 150°C, thus establishing a limit on the maximum device power dissipation and therefore load current at high ambient temperatures. Equation 5 shows the relationships between the important parameters.

Equation 5. LM53602 LM53603 Max_Iout.gif

It is easy to see that larger ambient temperatures (TA) and larger values of RθJA reduce the maximum available output current. As stated in Semiconductor and IC Package Thermal Metrics, the values given in the Thermal Information table are not valid for design purposes and must not be used to estimate the thermal performance of the application. The values reported in that table were measured under a specific set of conditions that are never obtained in an actual application. The effective RθJA is a critical parameter and depends on many factors such as power dissipation, air temperature, PCB area, copper heat sink area, number of thermal vias under the package, air flow, and adjacent component placement. The LM53603 uses an advanced package with a heat spreading pad (EP) on the bottom. This must be soldered directly to the PCB copper ground plane to provide an effective heat sink, as well as a proper electrical connection. The resources in Ground and Thermal Plane Considerations can be used as a guide to optimal thermal PCB design and estimating RθJA for a given application environment. A typical example of RθJA versus copper board area is shown in Figure 17. The copper area in this graph is that for each layer of a four-layer board; the inner layers are 1 oz. (35 µm), while the outer layers are 2 oz. (70 µm). A typical curve of maximum load current versus ambient temperature, for both the LM53603 and LM53602, is shown in Figure 18. This data was taken with the device soldered to a PCB with an RθJA of about 17°C/W and an input voltage of 12 V. It must be remembered that the data shown in these graphs are for illustration only and the actual performance in any given application depends on all of the factors mentioned above.

LM53602 LM53603 D024_thetaJA_SNVSA42.gif
Figure 17. RθJA vs Copper Board Area
power dissipation operation thermal optimized automotive power
						solution LM53602 LM53603 D032_25C_auto_3v3_SNVSA42.gif Figure 19. IC Power Dissipation vs Output Current for 3.3-V output
high temperature operation thermal optimized automotive power
						solution LM53602 LM53603 C006_.png Figure 18. Maximum Output Current vs Ambient Temperature
RθJA = 17°C/W, VIN = 12 V
power dissipation operation thermal optimized automotive power
						solution LM53602 LM53603 D033_25C_auto_5v_SNVSA42.gif Figure 20. IC Power Dissipation vs Output Current for 5-V output

Application Curves

The following characteristics apply only to the circuit of Figure 15. These parameters are not tested and represent typical performance only. Unless otherwise stated, the following conditions apply: VIN = 12 V, TA = 25°C.

LM53602 LM53603 D028_app_eff_5v_revB_SNVSA42.gif
VOUT = 5 V AUTO
Inductor = XAL6030-222ME
Figure 21. Efficiency
LM53602 LM53603 D014_app_input_current_5V_SNVSA42.gif
VOUT = 5 V AUTO IOUT = 0 A
Figure 23. Input Supply Current
LM53602 LM53603 D011_app_drop1_percent_5V_SNVSA42.gif
VOUT = 5 V
Figure 25. Dropout for –1% Regulation
LM53602 LM53603 D008_app_reg_5V_SNVSA42.gif
VOUT = 5 V AUTO
Figure 22. Load and Line Regulation
LM53602 LM53603 D013_app_mode_5V_SNVSA42.gif
VOUT = 5 V
Figure 24. Load Current for Mode Change
LM53602 LM53603 D012_app_drop185_5V_SNVSA42.gif
VOUT = 5 V
Figure 26. Dropout for ≥ 1.85 MHz

The following characteristics apply only to the circuit of Figure 15. These parameters are not tested and represent typical performance only. Unless otherwise stated, the following conditions apply: VIN = 12 V, TA = 25°C.

LM53602 LM53603 D031_app_F_I_5V_revB_SNVSA42.gif
VOUT = 5 V AUTO
Figure 27. Switching Frequency vs Load Current
LM53602 LM53603 start_5V.gif
VOUT = 5 V IOUT = 0 A AUTO
Figure 29. Start-Up
LM53602 LM53603 load_tran_5V_3A_pwm.gif
VOUT = 5 V IOUT = 0 A to 3 A, TR = TF = 1 µs FPWM
Figure 31. Load Transient
LM53602 LM53603 D026_app_F_V_5v_revB_SNVSA42.gif
VOUT = 5 V FPWM
Figure 28. Switching Frequency vs Input Voltage
LM53602 LM53603 load_tran_5V_3A_auto.gif
VOUT = 5 V IOUT = 0 A to 3 A, TR = TF = 1 µs AUTO
Figure 30. Load Transients
LM53602 LM53603 mode_5V.gif
VOUT = 5 V IOUT = 1 mA
Figure 32. Mode Change Transient

The following characteristics apply only to the circuit of Figure 15. These parameters are not tested and represent typical performance only. Unless otherwise stated, the following conditions apply: VIN = 12 V, TA = 25°C.

LM53602 LM53603 D029_app_eff_3p3v_revB_SNVSA42.gif
VOUT = 3.3 V AUTO
Inductor = XAL6030-222ME
Figure 33. Efficiency
LM53602 LM53603 D022_app_input_current_3p3V_SNVSA42.gif
VOUT = 3.3 V AUTO IOUT = 0 A
Figure 35. Input Supply Current
LM53602 LM53603 D019_app_drop1_percent_3p3V_SNVSA42.gif
VOUT = 3.3 V
Figure 37. Dropout for –1% Regulation
LM53602 LM53603 D016_app_reg_3p3V_SNVSA42.gif
VOUT = 3.3 V AUTO
Figure 34. Load and Line Regulation
LM53602 LM53603 D021_app_mode_3p3V_SNVSA42.gif
VOUT = 3.3 V
Figure 36. Load Current for Mode Change
LM53602 LM53603 D020_app_drop185_3p3V_SNVSA42.gif
VOUT = 3.3 V
Figure 38. Dropout for ≥ 1.85 MHz

The following characteristics apply only to the circuit of Figure 15. These parameters are not tested and represent typical performance only. Unless otherwise stated, the following conditions apply: VIN = 12 V, TA = 25°C.

LM53602 LM53603 D030_app_F_I_3p3V_revB_SNVSA42.gif
VOUT = 3.3 V AUTO
Figure 39. Switching Frequency vs Load Current
LM53602 LM53603 start_3p3V.gif
VOUT = 3.3 V AUTO IOUT = 0 A
Figure 41. Start-Up
LM53602 LM53603 load_tran_3p3V_3A_pwm.gif
VOUT = 3.3 V IOUT = 0 A to 3 A, TR = TF = 1 µs FPWM
Figure 43. Load Transient
LM53602 LM53603 D027_app_F_V_3p3v_revB_SNVSA42.gif
VOUT = 3.3 V FPWM
Figure 40. Switching Frequency vs Input Voltage
LM53602 LM53603 load_tran_3p3V_3A_auto.gif
VOUT = 3.3 V IOUT = 0 A to 3 A, TR = TF = 1 µs AUTO
Figure 42. Load Transient
LM53602 LM53603 mode_3p3V.gif
VOUT = 3.3 V IOUT = 1 mA
Figure 44. Mode Change Transient

Typical Adjustable Industrial Application Circuit

Figure 45 shows a typical example of a design with an output voltage of 10 V; while Table 7 gives typical design parameters. See Detailed Design Procedure for the design procedure.

automotive infotainment power supply buck regulator schematic DVD CD
			 blu-ray LM53602 LM53603 typ_app_cir5_10V.gif Figure 45. Typical Adjustable Output Industrial Power Supply Schematic
CD/DVD/Blu-ray Disc™ Motor Drive Applications
VOUT = 10 V

Design Parameters for Typical Adjustable Output Industrial Power Supply

There are a few design parameters to take into account. Most of those choices decide which version of the device to use. The desired output current steers the designer toward a LM53602 type or LM53603 type part. Most but not all parameters are independent of the of the IC choice. The output filter components (inductor and output capacitors) might vary with the choice of output voltage, especially for output voltages higher than 5 V. Refer to Detailed Design Procedure for details on choosing the components for the application.

Table 7. Design Parameters

DESIGN PARAMETER EXAMPLE VALUE
Input Voltage 12 V
Output Voltage 10 V
Maximum Output Current 3 A

Do's and Don't's