Datasheet XDPS21071 (Infineon) - 7
| Hersteller | Infineon |
| Beschreibung | Forced Frequency Resonant Flyback controller |
| Seiten / Seite | 54 / 7 — Forced Frequency Resonant Flyback controller. Functional Description 4. … |
| Revision | 01_00 |
| Dateiformat / Größe | PDF / 2.2 Mb |
| Dokumentensprache | Englisch |
Forced Frequency Resonant Flyback controller. Functional Description 4. Functional Description. 4.1. Power supply management
Modelllinie für dieses Datenblatt
Textversion des Dokuments
link to page 36 link to page 7 link to page 12 link to page 30 link to page 7 link to page 8 link to page 9 link to page 9 link to page 11 link to page 11 link to page 9 link to page 8 link to page 9 link to page 31 link to page 8 link to page 31
Forced Frequency Resonant Flyback controller Functional Description 4 Functional Description
The functional description gives an overview about the integrated functions and features and their relationship. The mentioned parameters and equations are based on typical values at TA = 25 °C. The correlated minimal and maximal values are shown in the electrical characteristics in Chapter 6. The functional description is grouped in following sections: Power supply management (Chapter 4.1) Control features (Chapter 4.2) Protection features (Chapter 4.3)
4.1 Power supply management
The power supply management ensures a reliable and robust IC operation. Depending on the operation mode of the control IC, the power supply management unit runs in different ways for VCC supply and for brown-in monitoring, which are described in the sequel: • VCC capacitor charge-up and startup sequence (see Chapter 4.1.1) • Brown-in monitoring (Chapter 4.1.2) • Brown-out protection response (Chapter 4.1.3) • During burst mode (QBM) operation (Chapter 4.1.4) • Bang-bang mode during latch mode (LM) operation (Chapter 4.1.5.1 ) • Bang-bang mode during auto-restart mode (ARM) operation (Chapter 4.1.5.2)
4.1.1 VCC capacitor charge-up and startup sequence
There are two main functions supported at HV pin by a resistor RHV connected to the bulk capacitor (see Figure 5). They are the VCC capacitor charge-up, and the bulk voltage monitoring (see Chapter 4.1.2). At beginning of a cold startup, the depletion startup cell is on. Once the AC line voltage is applied and charging the bulk capacitor, a current flows through the external resistor RHV into HV pin. Via the integrated diode D1, that current may charge up the external VCC capacitor (see Figure 5). Once VCC voltage exceeds the threshold VVCCon = 20.5 V, the startup cell is turned off, the control IC is enabled and the firmware boot sequence follows which takes about 1.2 ms. Both bulk voltage brown-in and VCC brown-in condition (see Chapter 4.3.4) are checked continuously. Once they both are above the brown-in level, respectively, the first GD0 pulse according to the soft-start control will be generated earliest after the 1.2 ms boot sequence time. The voltage VVCC drops until the supply via the auxiliary winding (VVCCSS) takes over the VCC supply (see Figure 4). For a proper system startup and operation, the supply voltage VVCC must be always above the VCC off-threshold VVCCoff=7.2 V (see Chapter 4.3.3). Data Sheet 7 Revision 2.0 2019-10-30
Forced Frequency Resonant Flyback controller Functional Description 4 Functional Description
The functional description gives an overview about the integrated functions and features and their relationship. The mentioned parameters and equations are based on typical values at TA = 25 °C. The correlated minimal and maximal values are shown in the electrical characteristics in Chapter 6. The functional description is grouped in following sections: Power supply management (Chapter 4.1) Control features (Chapter 4.2) Protection features (Chapter 4.3)
4.1 Power supply management
The power supply management ensures a reliable and robust IC operation. Depending on the operation mode of the control IC, the power supply management unit runs in different ways for VCC supply and for brown-in monitoring, which are described in the sequel: • VCC capacitor charge-up and startup sequence (see Chapter 4.1.1) • Brown-in monitoring (Chapter 4.1.2) • Brown-out protection response (Chapter 4.1.3) • During burst mode (QBM) operation (Chapter 4.1.4) • Bang-bang mode during latch mode (LM) operation (Chapter 4.1.5.1 ) • Bang-bang mode during auto-restart mode (ARM) operation (Chapter 4.1.5.2)
4.1.1 VCC capacitor charge-up and startup sequence
There are two main functions supported at HV pin by a resistor RHV connected to the bulk capacitor (see Figure 5). They are the VCC capacitor charge-up, and the bulk voltage monitoring (see Chapter 4.1.2). At beginning of a cold startup, the depletion startup cell is on. Once the AC line voltage is applied and charging the bulk capacitor, a current flows through the external resistor RHV into HV pin. Via the integrated diode D1, that current may charge up the external VCC capacitor (see Figure 5). Once VCC voltage exceeds the threshold VVCCon = 20.5 V, the startup cell is turned off, the control IC is enabled and the firmware boot sequence follows which takes about 1.2 ms. Both bulk voltage brown-in and VCC brown-in condition (see Chapter 4.3.4) are checked continuously. Once they both are above the brown-in level, respectively, the first GD0 pulse according to the soft-start control will be generated earliest after the 1.2 ms boot sequence time. The voltage VVCC drops until the supply via the auxiliary winding (VVCCSS) takes over the VCC supply (see Figure 4). For a proper system startup and operation, the supply voltage VVCC must be always above the VCC off-threshold VVCCoff=7.2 V (see Chapter 4.3.3). Data Sheet 7 Revision 2.0 2019-10-30