SLVSD81A January   2016  – February 2017 TPS7H1101-SP

PRODUCTION DATA.  

  1. Features
  2. Applications
  3. Description
  4. Revision History
  5. Description (continued)
  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 Typical Characteristics
  8. Detailed Description
    1. 8.1 Overview
    2. 8.2 Functional Block Diagram
    3. 8.3 Feature Description
      1. 8.3.1 Soft Start
      2. 8.3.2 Power Good (PG)
    4. 8.4 Device Functional Modes
      1. 8.4.1 Enable/Disable
  9. Application and Implementation
    1. 9.1 Application Information
      1. 9.1.1 Stability
    2. 9.2 Typical Application
      1. 9.2.1 Design Requirements
      2. 9.2.2 Detailed Design Procedure
        1. 9.2.2.1 Adjustable Output Voltage (Feedback Circuit)
        2. 9.2.2.2 PCL
        3. 9.2.2.3 High-Side Current Sense
        4. 9.2.2.4 Current Foldback
        5. 9.2.2.5 Transient Response
        6. 9.2.2.6 Current Sharing
        7. 9.2.2.7 Compensation
        8. 9.2.2.8 Output Noise
        9. 9.2.2.9 Capacitors
      3. 9.2.3 Application Curves
  10. 10Power Supply Recommendations
  11. 11Layout
    1. 11.1 Layout Guidelines
    2. 11.2 Layout Example
  12. 12Device and Documentation Support
    1. 12.1 Device Support
      1. 12.1.1 Third-Party Products Disclaimer
    2. 12.2 Documentation Support
      1. 12.2.1 Related Documentation
    3. 12.3 Receiving Notification of Documentation Updates
    4. 12.4 Community Resources
    5. 12.5 Trademarks
    6. 12.6 Electrostatic Discharge Caution
    7. 12.7 Glossary
  13. 13Mechanical, Packaging, and Orderable Information
    1. 13.1 Device Nomenclature

Package Options

Mechanical Data (Package|Pins)
Thermal pad, mechanical data (Package|Pins)
Orderable Information

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 suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality.

Application Information

The TPS7H1101-SP LDO linear regulator is targeted to harsh environment applications. This regulator has various features such as low dropout, soft start, output current foldback, high-side current sensing (where sensing voltage at CS pin provides voltage proportional to output current), and current sharing.

Stability

Conventional Bode plots are a standard approach in assessing stability as shown in Figure 11. This approach requires that we have a single feedback path where an AC signal is injected across a resistor (typically 50 Ω) and measurements are taken on either side of the resistor. From this, loop gain and phase plots can be generated. Crossover frequency, ƒC, is defined as the frequency where the magnitude of the loop gain is unity and phase margin is evaluated at the crossover frequency ƒC.

TPS7H1101-SP bode_plot_meas_slvsas4.gif Figure 11. Conventional Bode Plot

However, there are conditions where the feedback loop is not accessible or there may be multiple feedback paths, as with the TPS7H1101-SP. When there are multiple feedback loops the conventional bode plot approach will not be representative of the device's true response. The TPS7H1101-SP uses a conventional feedback loop in addition to an inner fast loop that injects current into the error amplifier, which in turn greatly improves the transient response of the device. The Bode plot method can still be used to understand the behavior of the main loop, but this will show a lower crossover frequency and thus imply a slower transient response than the actual performance of the device. Fortunately, accurate and quantitative stability metrics can still be assessed from output impedance measurements and simulations.

There are multiple ways output impedance can be measured. One approach is to inject a small current at the output of the regulator and compare it to the resulting voltage response. The variation in the phase of the output impedance across frequency can be related to the phase margin through the group delay.

Group delay, Tg, is the rate of change of phase with respect to frequency as shown in Equation 2. Most SPICE simulation packages can plot this parameter and certain frequency analyzers boast software that supports a direct measurement. Using this software, phase margin can be extracted from the group delay plot. The phase margin and crossover frequency reported from these measurements will include the effects of both feedback loops.

Equation 2. TPS7H1101-SP eq_02_Tg_slvsas4.gif

The stability of the device can be qualitatively validated by applying a step load to the output and observing the response. The SPICE models for the device can be found in Tools & Software on the product page. To simulate impedance measurements, the transient model should be used. For a more detailed explanation of this approach and how to use the model to simulate the output impedance and group delay, please see reference (1).

Typical Application

TPS7H1101-SP typ_app_cir_1_lvsd81.gif Figure 12. Typical Application Circuit

Design Requirements

Table 1 shows the design parameters.

Table 1. Design Parameters

PARAMETER VALUE
Input voltage 1.5 V to 7 V
Output voltage User programmable
Output current 3-A max

Detailed Design Procedure

Adjustable Output Voltage (Feedback Circuit)

The output voltage of the TPS7H1101-SP can be set to a user-programmable level between 0.8 V and 6.65 V. Achieve this by using a resistor divider connected between VOUT, FB, and GND terminals. RTOP connected between VOUT and VFB, and RBOTTOM connected between VFB and GND.

Use Equation 3 to determine VOUT.

Equation 3. TPS7H1101-SP eq1_lvsas4.gif

where

  • VFB = 0.605 V

Table 2. Resistor Values for Typical Voltages

VOUT Standard 1% Resistors Standard 0.1% Resistors
RTOP RBOTTOM RTOP RBOTTOM
0.8 V 10.7 kΩ 33.2 kΩ 10.7 kΩ 33.2 kΩ
1 V 13.7 kΩ 21 kΩ 12.6 kΩ 19.3 kΩ
1.2 V 11.3 kΩ 11.5 kΩ 11.8 kΩ 12 kΩ
1.5 V 15.8 kΩ 10.7 kΩ 18.2 kΩ 12.3 kΩ
1.8 V 23.2 kΩ 11.8 kΩ 32 kΩ 16.2 kΩ
2.5 V 10.7 kΩ 3.4 kΩ 37.9 kΩ 12.1 kΩ
3.3 V 51.1 kΩ 11.5 kΩ 10.2 kΩ 2.29 kΩ
4 V 13.3 kΩ 2.37 kΩ 31.2 kΩ 5.56 kΩ
5 V 11.5 kΩ 1.58 kΩ 16.2 kΩ 2.23 kΩ
5.5 V 17.4 kΩ 2.15 kΩ 89.8 kΩ 11.1 kΩ
6 V 90.9 kΩ 10.2 kΩ 10.7 kΩ 1.2 kΩ
6.5 V 26.7 kΩ 2.74 kΩ 15.2 kΩ 1.56 kΩ
6.6 V 11.3 kΩ 1.15 kΩ 22.1 kΩ 2.23 kΩ
6.7 V 39.2 kΩ 3.92 kΩ 13.8 kΩ 1.37 kΩ

PCL

PCL resistor, Rpcl, sets the overcurrent limit activation point and can be calculated per Equation 4.

Equation 4. Rpcl = (CSR × Vref) / (ICL – 0.0403)

where

  • Vref = 0.605 V
  • ICL = Programmable current limit (A)
  • Current sense ratio (CSR) is the ratio of output load current to ICS. The typical value of the CSR is 47394.

Figure 13 shows the output load current (IOUT) versus PCL terminal current (ICL)

A suitable resistor Rpcl must be chosen to ensure the CS terminal is within its operating range of 0.3 V to VIN.

The maximum PCL is 3.5 A. The range of resistor that can be used on the PCL terminal to GND is 8.2 kΩ to 160 kΩ.

TPS7H1101-SP C001_SLVU944.gif
VIN = 2.3 V VOUT = 1.8 V y = 47394x + 0.0403
Figure 13. IOUT (A) vs IPCL (µA)

High-Side Current Sense

Figure 14 shows the cascode NMOS current mirror. Vcs must be in the range as specified in the Electrical Characteristics table. The following example shows the typical calculation of Rcs.

Equation 5. TPS7H1101-SP eq_Ics_slvsas4.gif
Equation 6. TPS7H1101-SP eq3_Rcsmax_slvsas4.gif

where

  • ILOAD is the output load current.
  • CSR is the current sense ratio.

When VIN = 2.3 V, select VCS = 2.05 V, ILOAD = 3 A, CSR = 47394, and Ioffset = 0.1899 A, then ICS = 67.306 µA and RCS = 3.714 kΩ.

TPS7H1101-SP Cascode_NMOS_slvsas4.gif Figure 14. Cascode NMOS Current Mirror

For TPS7H1101-SP, Figure 15 shows the typical curve VCS vs IOUT for VIN = 2.28 V and RCS = 3.65 kΩ. A resistor connected from the CS terminal to VIN indicates voltage proportional to the output current.

Monitoring current in the CS terminal (ICS vs IOUT) indicates the current sense ratio between the main PMOSFET and the current sense MOSFET as shown in Figure 16.

Figure 17 shows IOUT vs ICS when the voltage on CS terminal is varied from 0.3 V to 7 V.

TPS7H1101-SP C003_SLVU944.gif
VIN = 2.3 V VOUT = 1.8 V y = –0.078x + 2.2853
Figure 15. VCS (V) vs IOUT (A)
TPS7H1101-SP C003_SLVU943.gif
y = 49917x – 0.2466
Figure 17. IOUT (A) vs ICS (A)
TPS7H1101-SP C002a_slvsas4.gif
VIN = 2.3 V VOUT = 1.8 V
Figure 16. IOUT (A) vs ICS (A)

Current Foldback

  1. The TPS7H1101-SP has a current foldback feature which can be enabled when the CS terminal is held high. Shorting CS low disables the foldback current limit. If the foldback current limit is disabled, then the LDO will begin regulating again as soon as the current falls below the clamp threshold.
  2. With foldback current limit enabled, when current limit trip point is activated,
    1. Output voltage drops low.
    2. Output current folds back to approximately 50% of the current limit trip point.
    This results in minimizing the power loss under fault conditions. Monitoring the voltage at the CS terminal indicates voltage proportional to the output current.

Transient Response

Figure 18, Figure 19, and Figure 20 indicate the transient response behavior of the LDO for 50% step load change.

Channel 1: Input Voltage

Channel 2: Output voltage overshoot/undershoot

Channel 3: Step load in current

TPS7H1101-SP trans_repeat_slvu944.gif Figure 18. Load Transient Response: Step Load 0.1 A to 1.6 A, VIN = 2.3 V, VOUT = 1.8 V
TPS7H1101-SP trans_undershoot_slvu944.gif Figure 20. Expanded View Undershoot
TPS7H1101-SP trans_overshoot_slvu944.gif Figure 19. Expanded View Overshoot

Current Sharing

For demanding load requirements, multiple LDOs can be paralleled as indicated in Figure 22. In parallel mode, the CS terminal of LDO1 must be connected to the PCL terminal of LDO2 via a series resistor RCL, and CS terminal of LDO2 must be connected to PCL terminal of LDO1 via series resistor RCL. The typical value of RCL in parallel operation is 3.75 kΩ for current limit > 6 A. In parallel configuration, RCL (resistor from PCL to GND) and RCS (resistor from CS terminal to VIN) must be left open (unpopulated). The RCL value must be selected so that the operating condition of the CS terminal is maintained, as specified in the Electrical Characteristics table. The current from PCL through RCL of LDO1 is determined by the output load current of LDO2 divided by the CSR. Hence, the voltage at CS terminal of the LDO1 is 0.605 V – ((output load current of LDO2 + 0.2458) / CSR × RCL).

Alternately, it can also provide twice the output current to meet system needs. When using two LDOs in parallel operation for higher output load current, use POL TPS50601-SP as an input source.

TPS7H1101-SP LDO_7h11_SLVSAS4.gif
Figure 21. LDO Current Share
TPS7H1101-SP fbd2_parallel_lvsas4.gif Figure 22. Block Diagram (Parallel Operation)

Compensation

Figure 23 shows a generic block diagram for TPS7H1101-SP LDO with external compensation components. LDO incorporates nested loops, thus providing the high gain necessary to meet design performance.

TPS7H1101-SP compensation_slvsas4.gif Figure 23. TPS7H1101-SP Compensation

Resistor divider composed of Rtop and Rbottom determine the output voltage set points as indicated by Equation 3.

Output capacitor COUT introduces a pole and a zero as shown in the following.

Equation 7. TPS7H1101-SP eq5_Fpco_slvsas4.gif
Equation 8. TPS7H1101-SP eq6_Fzco_slvsas4.gif

The TPS7H1101-SP was designed so that the ESR of the output capacitor will not have a strong influence on the response of the LDO. However, an optional capacitor, Cx, can be added in parallel with the bottom feedback resistor to introduce a pole to cancel Fz_co. Equation 9 shows how to calculate the location of the pole introduced by Cx. To cancel the zero directly, Fp should be equal to Fz_co.

Equation 9. TPS7H1101-SP eq8_Fp_slvsas4.gif

Cx is calculated to be 1000 pF for Co = 220 µF, Cesr = 45 mΩ, and Rbottom = 10 kΩ.

Internal compensation in the LDO cancels the output capacitor pole introduced by COUT and RL.

Ccomp introduces a dominant pole at low frequency. TI recommends that a Ccomp value of 10 nF.

Output Noise

Output noise is measured using an HP3495A. Figure 24, Figure 25, , and show noise of the TPS7H1101-SP in µV/√Hz vs frequency.

TPS7H1101-SP noise2_lvsas4.gif
VIN = 2 V VOUT = 1.8 V at 3 A
CIN = 220 µF CLOAD = 220 µF
Figure 24. RMS Noise (10 Hz to 100 kHz)
= 20.33 µVrms
TPS7H1101-SP noise2a_lvsas4.gif
VIN = 7 V VOUT = 6.7 V at ILOAD = 3 A
CIN = 220 µF CLOAD = 220 µF
Figure 25. RMS Noise (10 Hz to 100 kHz)
= 31.68 µVrms

Capacitors

TPS7H1101-SP requires the use of a combination of tantalum and ceramic capacitors to achieve good volume to capacitance ratio. Table 3 highlights some of the capacitors used in the device. TI recommends to follow proper derating guidelines as recommended by the capacitor manufacturer based upon output voltage and operating temperature.

Note that polymer-based tantalum capacitors must be derated to at least 60% of rated voltage, whereas manganese oxide (MnO2) based tantalum capacitors should be derated to 33% of rated voltage depending upon the operating temperature.

TI recommends to use a tantalum capacitor along with a 0.1-µF ceramic capacitor. The device is stable for input and output tantalum capacitor values of 10 to 220 µF with the ESR range of 10 mΩ to 2 Ω. However, the dynamic performance of the device varies based on load conditions and the capacitor values used.

TI recommends a minimum output capacitor of 22 µF with ESR of 1 Ω or less to prevent oscillations. X7R dielectrics are preferred. See Table 3 for various capacitor recommendations.

Table 3. TPS7H1101-SP Capacitors

CAPACITOR PART NUMBER CAPACITOR DETAILS
(CAPACITOR, VOLTAGE, ESR)
TYPE VENDOR
T493X107K016CH612A(1) 100 µF, 16 V, 100 mΩ Tantalum - MnO2 Kemet
T493X226M025AH6x20(1) 22 µF, 25 V, 35 mΩ Tantalum - MnO2 Kemet
T525D476M016ATE035(1) 47 µF, 10 V, 35 mΩ Tantalum - Polymer Kemet
T540D476M016AH6520(1) 47 µF, 16 V, 20 mΩ Tantalum - Polymer Kemet
T525D107M010ATE025(1) 100 µF, 10 V, 25 mΩ Tantalum - Polymer Kemet
T541X337M010AH6720(1) 330 µF, 10 V, 6 mΩ Tantalum - Polymer Kemet
T525D227M010ATE025(1) 220 µF, 10 V, 25 mΩ Tantalum - Polymer Kemet
T495X107K016ATE100(1) 100 µF, 16 V, 100 mΩ Tantalum - MnO2 Kemet
CWR29FK227JTHC(1) 220 µF, 10 V, 180 mΩ Tantalum - MnO2 AVX
THJE107K016AJH 100 µF, 16 V, 58 mΩ Tantalum AVX
THJE227K010AJH 220 µF, 10 V, 40 mΩ Tantalum AVX
SMX33C336KAN360 33 µF, 25 V Stacked ceramic AVX
SR2225X7R335K1P5#M123 3.3 µF, 25 V, 10 mΩ Ceramic Presidio Components Inc
Operating temperature is –55°C to 125°C.

Application Curves

TPS7H1101-SP vdo_vs_iout_7h11b_lvsas4.gif Figure 26. VDO vs IOUT