UCC2871x Constant-Voltage, Constant-Current Controller With Primary-Side Regulation
1 Features
- < 10-mW No-Load Power
- Primary-Side Regulation (PSR) Eliminates Opto-Coupler
- ±5% Voltage and Current Regulation Across Line and Load
- 700-V Start-Up Switch
- 100-kHz Maximum Switching Frequency Enables High-Power Density Charger Designs
- Resonant Valley-Switching Operation for Highest Overall Efficiency
- Frequency Jitter to Ease EMI Compliance
- Wide VDD Range Allows Small Bias Capacitor
- Clamped Gate-Drive Output for MOSFET
- Overvoltage, Low-Line, and Overcurrent Protection Functions
- Programmable Cable Compensation (UCC28710)
- NTC Resistor Interface (UCC28711, UCC28712 and UCC28713) with Fixed Cable Compensation Options
- SOIC-7 Package
- Create a Custom Design Using the UCC28710 With the WEBENCH® Power Designer
2 Applications
- USB-Compliant Adapters and Chargers for Consumer Electronics
- Smart Phones
- Tablet Computers
- Cameras
- Standby Supply for TV and Desktop
- White Goods
3 Description
The UCC2871x family of flyback power supply controllers provides isolated-output Constant-Voltage (CV) and Constant-Current (CC) output regulation without the use of an optical coupler. The devices process information from the primary power switch and an auxiliary flyback winding for precise control of output voltage and current.
An internal 700-V start-up switch, dynamically-controlled operating states and a tailored modulation profile support ultra-low standby power without sacrificing start-up time or output transient response.
Control algorithms in the UCC28710 family allow operating efficiencies to meet or exceed applicable standards. The output drive interfaces to a MOSFET power switch. Discontinuous conduction mode (DCM) with valley switching reduces switching losses. Modulation of switching frequency and primary current peak amplitude (FM and AM) keeps the conversion efficiency high across the entire load and line ranges.
The controllers have a maximum switching frequency of 100 kHz and always maintain control of the peak-primary current in the transformer. Protection features help keep primary and secondary component stresses in check. The UCC28710 allow the cable compensation to be programmed. The UCC28711, UCC28712 and UCC28713 devices allow remote temperature sensing using a negative temperature coefficient (NTC) resistor while providing fixed cable-compensation levels.
Device Information(1)
| PART NUMBER | PACKAGE | BODY SIZE (NOM) |
|---|---|---|
| UCC28710 | SOIC (7) | 4.91 mm × 3.90 mm |
| UCC28711 | ||
| UCC28712 | ||
| UCC28713 |
- For all available packages, see the orderable addendum at the end of the data sheet.
Simplified Application
4 Revision History
Changes from B Revision (July 2015) to C Revision
- Deleted all references to the UCC28714, UCC28715, and UCC28716 devicesGo
- Deleted quasi from quasi-resonantGo
- Added the Development Support, Receiving Notification of Documentation Updates, and Community Resources sectionsGo
Changes from A Revision (December 2014) to B Revision
- Updated Layout Guidelines sectionGo
Changes from * Revision (November 2012) to A Revision
- Added Pin Configuration and Functions section, ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and Mechanical, Packaging, and Orderable Information section Go
5 Device Comparison Table
| PART NUMBER(1) | MINIMUM SWITCHING FREQUENCY | OPTIONS(2) |
|---|---|---|
| UCC28710 | 680 Hz | Programmable cable compensation |
| UCC28711 | NTC option, 0-mV (at 5-V output) cable compensation | |
| UCC28712 | NTC option, 150-mV (at 5-V output) cable compensation | |
| UCC28713 | NTC option, 300-mV (at 5-V output) cable compensation |
6 Pin Configuration and Functions
Pin Functions
| PIN | I/O | DESCRIPTION | ||
|---|---|---|---|---|
| NAME | UCC28710 | UCC28711 UCC28712 UCC28713 |
||
| CBC | 3 | — | I | Cable compensation is a programming pin for compensation of cable voltage drop. Cable compensation is programmed with a resistor to GND. |
| CS | 5 | 5 | I | Current sense input connects to a ground-referenced current-sense resistor in series with the power switch. The resulting voltage is used to monitor and control the peak primary current. A series resistor can be added to this pin to compensate the peak switch current levels as the AC-mains input varies. |
| DRV | 6 | 6 | O | Drive is an output used to drive the gate of an external high voltage MOSFET switching transistor. |
| GND | 4 | 4 | — | The ground pin is both the reference pin for the controller and the low-side return for the drive output. Special care should be taken to return all AC decoupling capacitors as close as possible to this pin and avoid any common trace length with analog signal return paths. |
| HV | 7 | 7 | I | The high-voltage pin connects directly to the rectified bulk voltage and provides charge to the VDD capacitor for start-up of the power supply. |
| NTC | — | 3 | I | NTC an interface to an external negative temperature coefficient resistor for remote temperature sensing. Pulling this pin low shuts down PWM action. |
| VDD | 1 | 1 | I | VDD is the bias supply input pin to the controller. A carefully-placed bypass capacitor to GND is required on this pin. |
| VS | 2 | 2 | I | Voltage sense is an input used to provide voltage and timing feedback to the controller. This pin is connected to a voltage divider between an auxiliary winding and GND. The value of the upper resistor of this divider is used to program the AC-mains run and stop thresholds and line compensation at the CS pin. |
7 Specifications
7.1 Absolute Maximum Ratings
See (1).| MIN | MAX | UNIT | |||
|---|---|---|---|---|---|
| VHV | Start-up pin voltage, HV | 700 | V | ||
| VVDD | Bias supply voltage, VDD | 38 | V | ||
| IDRV | Continuous gate current sink | 50 | mA | ||
| IDRV | Continuous gate current source | Self-limiting | mA | ||
| IVS | Peak current, VS | −1.2 | mA | ||
| VDRV | Gate drive voltage at DRV | −0.5 | Self-limiting | V | |
| Voltage | VS | −0.75 | 7 | V | |
| CS, CBC, NTC | −0.5 | 5 | V | ||
| TJ | Operating junction temperature | −55 | 150 | °C | |
| Lead temperature 0.6 mm from case for 10 s | 260 | °C | |||
| Tstg | Storage temperature | −65 | 150 | °C | |
7.2 ESD Ratings
| VALUE | UNIT | |||
|---|---|---|---|---|
| V(ESD) | Electrostatic discharge | Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1) | ±2000 | V |
| Charged-device model (CDM), per JEDEC specification JESD22-C101(2) | ±500 | |||
7.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)| MIN | NOM | MAX | UNIT | ||
|---|---|---|---|---|---|
| VDD | Bias supply operating voltage | 9 | 35 | V | |
| CVDD | VDD bypass capacitor | 0.047 | 1 | µF | |
| RCBC | Cable-compensation resistance | 10 | kΩ | ||
| IVS | VS pin current | −1 | mA | ||
| TJ | Operating junction temperature | −40 | 125 | °C | |
7.4 Thermal Information
| THERMAL METRIC(1) | UCC2871x | UNIT | |
|---|---|---|---|
| D (SOIC) | |||
| 7 PINS | |||
| RθJA | Junction-to-ambient thermal resistance | 141.5 | °C/W |
| RθJC(top) | Junction-to-case (top) thermal resistance | 73.8 | °C/W |
| RθJB | Junction-to-board thermal resistance | 89 | °C/W |
| ψJT | Junction-to-top characterization parameter | 23.5 | °C/W |
| ψJB | Junction-to-board characterization parameter | 88.2 | °C/W |
7.5 Electrical Characteristics
over operating free-air temperature range, VVDD = 25 V, HV = open, RCBC(NTC) = open, TA = –40 °C to 125 °C, TA = TJ(unless otherwise noted)
| PARAMETER | TEST CONDITIONS | MIN | TYP | MAX | UNIT | ||
|---|---|---|---|---|---|---|---|
| HIGH-VOLTAGE START UP | |||||||
| IHV | Start-up current out of VDD | VHV = 100 V, VVDD = 0 V, start state | 100 | 250 | 500 | µA | |
| IHVLKG | Leakage current at HV | VHV = 400 V, run state | 0.1 | 1 | µA | ||
| BIAS SUPPLY INPUT | |||||||
| IRUN | Supply current, run | IDRV = 0, run state | 2 | 2.65 | mA | ||
| IWAIT | Supply current, wait | IDRV = 0, wait state | 95 | 120 | µA | ||
| ISTART | Supply current, start | IDRV = 0, VVDD = 18 V, start state, IHV = 0 | 18 | 30 | µA | ||
| IFAULT | Supply current, fault | IDRV = 0, fault state | 95 | 125 | µA | ||
| UNDERVOLTAGE LOCKOUT | |||||||
| VVDD(on) | VDD turnon threshold | VVDD low to high | 19 | 21 | 23 | V | |
| VVDD(off) | VDD turnoff threshold | VVDD high to low | 7.7 | 8.1 | 8.5 | V | |
| VS INPUT | |||||||
| VVSR | Regulating level | Measured at no-load condition, TJ = 25 °C(1) | 4.01 | 4.05 | 4.09 | V | |
| VVSNC | Negative clamp level | IVS = –300 µA, volts below ground | 190 | 250 | 325 | mV | |
| IVSB | Input bias current | VVS = 4 V | –0.25 | 0 | 0.25 | µA | |
| CS INPUT | |||||||
| VCST(max) | Maximum CS threshold voltage | VVS = 3.7 V | 738 | 780 | 810 | mV | |
| VCST(min) | Minimum CS threshold voltage | VVS = 4.35 V | 175 | 195 | 215 | mV | |
| KAM | AM control ratio | VCST(max) / VCST(min) | 3.6 | 4 | 4.4 | V/V | |
| VCCR | Constant current regulating level | CC regulation constant | 318 | 330 | 343 | mV | |
| KLC | Line compensation current ratio | IVSLS = –300 µA, IVSLS / current out of CS pin | 24 | 25 | 28.6 | A/A | |
| TCSLEB | Leading-edge blanking time | DRV output duration, VCS = 1 V | 180 | 235 | 280 | ns | |
| DRIVERS | |||||||
| IDRS | DRV source current | VDRV = 8 V, VVDD = 9 V | 20 | 25 | mA | ||
| RDRVLS | DRV low-side drive resistance | IDRV = 10 mA | 6 | 12 | Ω | ||
| VDRCL | DRV clamp voltage | VVDD = 35 V | 14 | 16 | V | ||
| RDRVSS | DRV pulldown in start state | 150 | 190 | 230 | kΩ | ||
| TIMING | |||||||
| fSW(max) | Maximum switching frequency | VVS = 3.7 V | 92 | 100 | 106 | kHz | |
| fSW(min) | Minimum switching frequency | VVS = 4.35 V | UCC28710 UCC28711 UCC28712 UCC28713 |
600 | 680 | 755 | Hz |
| tZTO | Zero-crossing timeout delay | 1.8 | 2.1 | 2.55 | µs | ||
| PROTECTION | |||||||
| VOVP | Overvoltage threshold | At VS input, TJ = 25 °C(1) | 4.55 | 4.6 | 4.71 | V | |
| VOCP | Overcurrent threshold | At CS input | 1.4 | 1.5 | 1.6 | V | |
| IVSL(run) | VS line-sense run current | Current out of VS pin increasing | 190 | 225 | 275 | µA | |
| IVSL(stop) | VS line-sense stop current | Current out of VS pin decreasing | 70 | 80 | 100 | µA | |
| KVSL | VS line sense ratio | IVSL(run) / IVSL(stop) | 2.45 | 2.8 | 3.05 | A/A | |
| TJ(stop) | Thermal shut-down temperature | Internal junction temperature | 165 | °C | |||
| CABLE COMPENSATION | |||||||
| VCBC(max) | Cable compensation maximum voltage | Voltage at CBC at full load | UCC28710 | 2.9 | 3.2 | 3.5 | V |
| VCVS(min) | Compensation at VS | VCBC = open, change in VS regulating level at full load | UCC28710 | –55 | –15 | 25 | mV |
| VCVS(max) | Maximum compensation at VS | VCBC = 0 V, change in VS regulating level at full load | UCC28710 | 275 | 320 | 375 | mV |
| VCVS | Compensation at VS | Change in VS regulating level at full load | UCC28711 | –55 | –15 | 25 | mV |
| UCC28712 | 103 | ||||||
| UCC28713 | 206 | ||||||
| NTC INPUT | |||||||
| VNTCTH | NTC shut-down threshold | Fault UVLO cycle when below this threshold | UCC28711 UCC28712 UCC28713 |
0.9 | 0.95 | 1 | V |
| INTC | NTC pullup current | Current out of pin | UCC28711 UCC28712 UCC28713 |
90 | 105 | 125 | µA |
7.6 Typical Characteristics
VDD = 25 V, unless otherwise noted.
Figure 1. Bias Supply Current vs. Bias Supply Voltage
Figure 3. VS Regulation Voltage vs. Temperature
Figure 5. Minimum CS Threshold vs. Temperature
Figure 9. NTC Shutdown Threshold Voltage vs. Temperature
Figure 11. VS Overvoltage Threshold vs. Temperature
Figure 2. Bias Supply Current vs. Temperature
Figure 4. VS Line Sense Current vs. Temperature
Figure 6. Constant Current Regulating Level vs. Temperature
| VDRV = 8 V | VVDD = 9 V |
Figure 10. NTC Pull-Up Current vs. Temperature
Figure 12. HV Start-Up Current vs. Temperature
8 Detailed Description
8.1 Overview
The UCC2871x family is a flyback power supply controller which provides accurate voltage and constant current regulation with primary-side feedback, eliminating the need for opto-coupler feedback circuits. The controller operates in discontinuous conduction mode with valley-switching to minimize switching losses. The modulation scheme is a combination of frequency and primary peak current modulation to provide high conversion efficiency across the load range. The control law provides a wide-dynamic operating range of output power which allows the power designer to achieve the <10-mW stand-by power requirement.
During low-power operating ranges the device has power management features to reduce the device operating current at operating frequencies below 33 kHz. The UCC2871x family includes features in the modulator to reduce the EMI peak energy of the fundamental switching frequency and harmonics. Accurate voltage and constant current regulation, fast dynamic response, and fault protection are achieved with primary-side control. A complete charger solution can be realized with a straightforward design process, low cost and low component count.
8.2 Functional Block Diagram
8.3 Feature Description
8.3.1 Detailed Pin Description
8.3.1.1 VDD (Device Bias Voltage Supply)
The VDD pin is connected to a bypass capacitor to ground and a start-up resistance to the input bulk capacitor (+) terminal. The VDD turnon UVLO threshold is 21 V and turnoff UVLO threshold is 8.1 V, with an available operating range up to 35 V. The USB charging specification requires the output current to operate in constant-current mode from 5 V to a minimum of 2 V; this is easily achieved with a nominal VDD of approximately 25 V. The additional VDD headroom up to 35 V allows for VDD to rise due to the leakage energy delivered to the VDD capacitor in high-load conditions. Also, the wide VDD range provides the advantage of selecting a relatively small VDD capacitor and high-value start-up resistance to minimize no-load stand-by power loss in the start-up resistor.
8.3.1.2 GND (Ground)
This is a single ground reference external to the device for the gate drive current and analog signal reference. Place the VDD bypass capacitor close to GND and VDD with short traces to minimize noise on the VS and CS signal pins.
8.3.1.3 VS (Voltage-Sense)
The VS pin is connected to a resistor divider from the auxiliary winding to ground. The output-voltage feedback information is sampled at the end of the transformer secondary current demagnetization time to provide an accurate representation of the output voltage. Timing information to achieve valley-switching and to control the duty cycle of the secondary transformer current is determined by the waveform on the VS pin. Avoid placing a filter capacitor on this input which would interfere with accurate sensing of this waveform.
The VS pin also senses the bulk capacitor voltage to provide for AC-input run and stop thresholds, and to compensate the current-sense threshold across the AC-input range. This information is sensed during the MOSFET on-time. For the AC-input run/stop function, the run threshold on VS is 220 µA and the stop threshold is 80 µA. The values for the auxilliary voltage divider upper-resistor RS1 and lower-resistor RS2 can be determined by the equations below.
where
- NPA is the transformer primary-to-auxiliary turns ratio,
- VIN(run) is the AC RMS voltage to enable turnon of the controller (run),
- IVSL(run) is the run-threshold for the current pulled out of the VS pin during the MOSFET on-time. (see the Electrical Characteristics table)
where
- VOCV is the converter regulated output voltage,
- VF is the output rectifier forward drop at near-zero current,
- NAS is the transformer auxiliary to secondary turns ratio,
- RS1 is the VS divider high-side resistance,
- VVSR is the CV regulating level at the VS input (see the Electrical Characteristics table).
8.3.1.4 DRV (Gate Drive)
The DRV pin is connected to the MOSFET gate pin, usually through a series resistor. The gate driver provides a gate-drive signal limited to 14 V. The turnon characteristic of the driver is a 25-mA current source which limits the turnon dv/dt of the MOSFET drain and reduces the leading-edge current spike, but still provides gate-drive current to overcome the Miller plateau. The gate-drive turnoff current is determined by the low-side driver RDS(on) and any external gate-drive resistance. The user can reduce the turnoff MOSFET drain dv/dt by adding external gate resistance.
8.3.1.5 CS (Current Sense)
The current-sense pin is connected through a series resistor (RLC) to the current-sense resistor (RCS). The current-sense threshold is 0.75 V for IPP(max) and 0.25 V for IPP(min). The series resistor RLC provides the function of feed-forward line compensation to eliminate change in IPP due to change in di/dt and the propagation delay of the internal comparator and MOSFET turnoff time. There is an internal leading-edge blanking time of 235 ns to eliminate sensitivity to the MOSFET turnon current spike. It should not be necessary to place a bypass capacitor on the CS pin. The value of RCS is determined by the target output current in constant-current (CC) regulation. The values of RCS and RLC can be determined by the equations below. The term ηXFMR is intended to account for the energy stored in the transformer but not delivered to the secondary. This includes transformer resistance and core loss, bias power, and primary-to-secondary leakage ratio.
Example: With a transformer core and winding loss of 5%, primary-to-secondary leakage inductance of 3.5%, and bias power to output power ratio of 1.5%. The ηXFMR value is approximately: 1 - 0.05 - 0.035 - 0.015 = 0.9.
where
- VCCR is a current regulation constant (see the Electrical Characteristics table),
- NPS is the transformer primary-to-secondary turns ratio (a ratio of 13 to 15 is recommended for 5-V output),
- IOCC is the target output current in constant-current regulation,
- ηXFMR is the transformer efficiency.
where
- RS1 is the VS pin high-side resistor value,
- RCS is the current-sense resistor value,
- TD is the current-sense delay including MOSFET turnoff delay, add ~50 ns to MOSFET delay,
- NPA is the transformer primary-to-auxiliary turns ratio,
- LP is the transformer primary inductance,
- KLC is a current-scaling constant (see the Electrical Characteristics table).
8.3.1.6 CBC (Cable Compensation), Pin 1 UCC28700
The cable compensation pin is connected to a resistor to ground to program the amount of output voltage compensation to offset cable resistance. The cable compensation block provides a 0-V to 3-V voltage level on the CBC pin corresponding to 0 to IOCC output current. The resistance selected on the CBC pin programs a current mirror that is summed into the VS feedback divider therefore increasing the output voltage as IOUT increases. There is an internal series resistance of 28 kΩ to the CBC pin which sets a maximum cable compensation of a 5-V output to 400 mV when CBC is shorted to ground. The CBC resistance value can be determined by the equation below.
where
- VO is the output voltage,
- VF is the diode forward voltage,
- VOCBC is the target cable compensation voltage at the output terminals,
- VCBC(max) is the maximum voltage at the cable compensation pin at the maximum converter output current (see the Electrical Characteristics table),
- VVSR is the CV regulating level at the VS input (see the Electrical Characteristics table).
8.3.1.7 NTC (NTC Thermistor Shut-down), Pin 1 UCC28701/2/3
These versions of the UCC28700 family utilize pin 1 for an external NTC thermistor to allow user-programmable external thermal shut-down. The shut-down threshold is 0.95 V with an internal 105-µA current source which results in a 9.05-kΩ thermistor shut-down threshold. These controllers have either zero or fixed internal cable compensation.
8.3.2 Fault Protection
There is comprehensive fault protection. Protection functions include:
- Output overvoltage fault
- Input undervoltage fault
- Internal overtemperature fault
- Primary overcurrent fault
- CS pin fault
- VS pin fault
A UVLO reset and restart sequence applies for all fault protection events.
The output overvoltage function is determined by the voltage feedback on the VS pin. If the voltage sample on VS exceeds 115% of the nominal VOUT, the device stops switching and the internal current consumption is IFAULT which discharges the VDD capacitor to the UVLO turnoff threshold. After that, the device returns to the start state and a start-up sequence ensues.
The UCC2871x family always operates with cycle-by-cycle primary peak current control. The normal operating range of the CS pin is 0.78 V to 0.195 V. There is additional protection if the CS pin reaches 1.5 V. This results in a UVLO reset and restart sequence.
The line input run and stop thresholds are determined by current information at the VS pin during the MOSFET on-time. While the VS pin is clamped close to GND during the MOSFET on-time, the current through RS1 is monitored to determine a sample of the bulk capacitor voltage. A wide separation of run and stop thresholds allows clean start-up and shut-down of the power supply with the line voltage. The run current threshold is 225 µA and the stop current threshold is 80 µA.
The internal over-temperature protection threshold is 165°C. If the junction temperature reaches this threshold the device initiates a UVLO reset cycle. If the temperature is still high at the end of the UVLO cycle, the protection cycle repeats.
Protection is included in the event of component failures on the VS pin. If complete loss of feedback information on the VS pin occurs, the controller stops switching and restarts.
8.4 Device Functional Modes
8.4.1 Primary-Side Voltage Regulation
Figure 13 illustrates a simplified flyback convertor with the main voltage regulation blocks of the device shown. The power train operation is the same as any DCM flyback circuit but accurate output voltage and current sensing is the key to primary-side control.
Figure 13. Simplified Flyback Convertor (With the Main Voltage Regulation Blocks)
In primary-side control, the output voltage is sensed on the auxiliary winding during the transfer of transformer energy to the secondary. As shown in Figure 14 it is clear there is a down slope representing a decreasing total rectifier VF and resistance voltage drop (ISRS) as the secondary current decreases to zero. To achieve an accurate representation of the secondary output voltage on the auxiliary winding, the discriminator reliably blocks the leakage inductance reset and ringing, continuously samples the auxiliary voltage during the down slope after the ringing is diminished, and captures the error signal at the time the secondary winding reaches zero current. The internal reference on VS is 4.05 V. Temperature compensation on the VS reference voltage of -0.8-mV/°C offsets the change in the output rectifier forward voltage with temperature. The resistor divider is selected as outlined in the VS pin description.
Figure 14. Auxiliary Winding Voltage
The UCC2871x family includes a VS signal sampler that signals discrimination methods to ensure an accurate sample of the output voltage from the auxiliary winding. There are however some details of the auxiliary winding signal to ensure reliable operation, specifically the reset time of the leakage inductance and the duration of any subsequent leakage inductance ring. Refer to Figure 15 below for a detailed illustration of waveform criteria to ensure a reliable sample on the VS pin. The first detail to examine is the duration of the leakage inductance reset pedestal, tLK_RESET in Figure 15. Because this can mimic the waveform of the secondary current decay, followed by a sharp downslope, it is important to keep the leakage reset time less than 600 ns for IPRI minimum, and less than 2.2 µs for IPRI maximum. The second detail is the amplitude of ringing on the VAUX waveform following tLK_RESET. The peak-to-peak voltage at the VS pin should be less than approximately 100 mVp-p at least 200 ns before the end of the demagnetization time, tDM. If there is a concern with excessive ringing, it usually occurs during light or no-load conditions, when tDM is at the minimum. The tolerable ripple on VS is scaled up to the auxiliary winding voltage by RS1 and RS2, and is equal to 100 mV x (RS1 + RS2) / RS2.
Figure 15. Auxiliary Waveform Details
During voltage regulation, the controller operates in frequency modulation mode and amplitude modulation mode as illustrated in Figure 16 below. The internal operating frequency limits of the device are 100 kHz maximum and fSW(min). The transformer primary inductance and primary peak current chosen sets the maximum operating frequency of the converter. The output preload resistor and efficiency at low power determines the converter minimum operating frequency. There is no stability compensation required for the UCC2871x family.
Figure 16. Frequency and Amplitude Modulation Modes (During Voltage Regulation)
8.4.2 Primary-Side Current Regulation
Timing information at the VS pin and current information at the CS pin allow accurate regulation of the secondary average current. The control law dictates that as power is increased in CV regulation and approaching CC regulation the primary-peak current is at IPP(max). Referring to Figure 17 below, the primary-peak current, turns ratio, secondary demagnetization time (tDM), and switching period (tSW) determine the secondary average output current. Ignoring leakage inductance effects, the average output current is given by Equation 6. When the average output current reaches the regulation reference in the current control block, the controller operates in frequency modulation mode to control the output current at any output voltage at or below the voltage regulation target as long as the auxiliary winding can keep VDD above the UVLO turnoff threshold.
Figure 17. Transformer Currents
Figure 18. Typical Target Output V-I Characteristic
8.4.3 Valley Switching
The UCC2871x family utilizes valley switching to reduce switching losses in the MOSFET, to reduce induced-EMI, and to minimize the turnon current spike at the sense resistor. The controller operates in valley-switching in all load conditions unless the VDS ringing has diminished.
Referring to Figure 19 below, the UCC2871x family operates in a valley-skipping mode in most load conditions to maintain an accurate voltage or current regulation point and still switch on the lowest available VDS voltage.
Figure 19. Valley-Skipping Mode
8.4.4 Start-Up Operation
The internal high-voltage start-up switch connected to the bulk capacitor voltage (VBLK) through the HV pin charges the VDD capacitor. During start up there is typically 300 µA available to charge the VDD capacitor. When VDD reaches the 21-V UVLO turnon threshold, the controller is enabled, the converter starts switching and the start-up switch is turned off. The initial three cycles are limited to IPP(min). After the initial three cycles at minimum IPP(min), the controller responds to the condition dictated by the control law. The converter will remain in discontinuous mode during charging of the output capacitor(s), maintaining a constant output current until the output voltage is in regulation.
