The present invention relates to a programmable power supply, and more specifically relates to a control circuit for the programmable power supply.
A programmable power supply provides a wide range of the output voltage and the output current, such as 5V˜20V and 0.5 A˜5 A. In general, it would be difficult to develop a cost effective solution and achieve good protections, such as over-voltage protection, over-current protection, etc. The objective of the present invention is to solve this problem and achieve good performance for the programmable power supply.
The objective of the present invention is to provide a control circuit for controlling a programmable power supply, and it achieves good performance for the programmable power supply.
A control circuit for a programmable power supply according to the present invention comprises a reference generation circuit, a feedback circuit, a switching controller, and a micro-controller. The reference generation circuit is coupled to generate a voltage-reference signal and a current-reference signal for regulating an output voltage and an output current of the power supply. The feedback circuit is coupled to detect the output voltage and the output current for generating a feedback signal in accordance with the voltage-reference signal and the current-reference signal. The switching controller generates a switching signal coupled to switch a transformer for generating the output voltage and the output current in accordance with the feedback signal. The micro-controller is coupled to control the reference generation circuit. The micro-controller, the reference generation circuit, and the feedback circuit are equipped in the secondary side of the transformer. The switching controller is equipped in the primary side of the transformer.
The accompanying drawings are included to provide further understanding of the invention, and are incorporated into and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A capacitor 70 coupled to the controller 100 is used for a voltage-loop compensation. A capacitor 75 coupled to the controller 100 is applied to compensate a current-loop for the regulation of the output current IO. The controller 100 further generates a control signal SX coupled to control the switching controller 300 through a second signal-transfer device, such as an opto-coupler 60. The control signal SX is used for programming of the switching controller 300 and the protections. A resistor 51 is coupled to the opto-coupler 50 and receives the output voltage VO from an output terminal of the programmable power supply. The resistor 51 is utilized to bias the operating current of the opto-coupler 50. A resistor 61 is coupled to the opto-coupler 60 and receives the output voltage VO from the output terminal of the programmable power supply. The resistor 61 is applied to limit the current of the opto-coupler 60. The controller 100 includes a communication interface COMM, (e.g. USB-PD, IEEE UPAMD 1823, one-wire communication, etc.) for the communication with the external devices.
The opto-coupler 50 will generate a feedback signal VB coupled to the switching controller 300 in accordance with the feedback signal FB. The opto-coupler 60 will generate a control signal SY coupled to the switching controller 300 in response to the control signal SX. The switching controller 300 generates a switching signal SW for switching a primary-side winding NP of a transformer 10 and generating the output voltage VO and the output current IO at the secondary side of the transformer 10 through a secondary-side winding NS, a rectifier 30, and an output capacitor 40. A capacitor 45 and the resistor 35 are coupled to the output terminal of the programmable power supply. A first terminal of the primary-side winding NP receives an input voltage VIN. A transistor 20 is coupled to a second terminal of the primary-side winding NP to switch the transformer 10 in response to the switching signal SW.
An auxiliary winding NA of the transformer 10 produces a reflected signal VS coupled to the switching controller 300 via a voltage divider developed by resistors 15 and 16. The reflected signal VS is correlated to the output voltage VO. A resistor 25 is coupled between the transistor 20 and a ground to sense a switching current IP of the transformer 10 for generating a current signal CS coupled to the switching controller 300. The switching controller 300 generates the switching signal SW in accordance with the feedback signal VB, the control signal SY, the reflected signal VS, and the current signal CS. The controller 100 is equipped in the secondary side of the transformer 10. The switching controller 300 is equipped in the primary side of the transformer 10.
The current-sense signal VCS is coupled to generate a current signal VI through a feedback circuit 200. The current signal VI is connected to the multiplexer 96. The current signal VI is correlated to the output current IO shown in
The micro-controller 80 controls the outputs of the digital-to-analog converters 91, 92, and 93. The first digital-to-analog converter 91 generates a voltage-reference signal VRV in response to the reference value of the register 81 for controlling the output voltage VO. The second digital-to-analog converter 92 generates a current-reference signal VRI in response to the reference value of the register 82 for controlling the output current IO. The third digital-to-analog converter 93 generates an over-voltage reference threshold VOV in response to the reference value of the register 83 for the over-voltage protection. Therefore, the digital-to-analog converters 91, 92, and 93 are operated as a reference generation circuit to generate the voltage-reference signal VRV, the current-reference signal VRI, and the over-voltage reference threshold VOV.
The micro-controller 80 will control the over-voltage reference threshold VOV in accordance with the level of the output voltage VO. The registers 81, 82, and 83 will be reset to provide an initial value in response to the power-on of the power supply. For example, the initial value of the first register 81 will be utilized to produce a minimum value of the voltage-reference signal VRV that is used to generate a 5V output voltage VO. The initial value of the second register 82 will be utilized to produce a minimum value of the current-reference signal VRI that is used to generate a 0.5 A output current IO. In other words, the voltage-reference signal VRV, the current-reference signal VRI, and the over-voltage reference threshold VOV will be reset to the initial value in response to the power-on of the power supply.
The feedback circuit 200 generates a voltage-feedback signal COMV, a current-feedback signal COMI, the feedback signal FB, and the control signal SX in response to the voltage-reference signal VRV, the current-reference signal VRI, the over-voltage reference threshold VOV, the output voltage VO, the feedback signal VFB, the current-sense signal VCS, the watch-dog signal WG, the control signal CNT, and the control-bus signal NB. The feedback circuit 200 is coupled to detect the output voltage VO and the output current IO for generating the feedback signal FB in accordance with the feedback signal VFB, the current-sense signal VCS, the voltage-reference signal VRV, and the current-reference signal VRI. The feedback signal FB is transferred from the feedback circuit 200 to the switching controller 300 by the opto-coupler 50 (as shown in
An error amplifier 230 generates the current-feedback signal COMI in accordance with the current signal VI and the current-reference signal VRI. The current signal VI is coupled to a negative input terminal of the error amplifier 230. The current-reference signal VRI is supplied with a positive input terminal of the error amplifier 230. An output terminal of the error amplifier 230 outputs the current-feedback signal COMI. Therefore, the error amplifier 230 generates the current-feedback signal COMI in accordance with the output current IO (as shown in
An error amplifier 240 generates the voltage-feedback signal COMV in accordance with the feedback signal VFB and the voltage-reference signal VRV. The feedback signal VFB is coupled to a negative input terminal of the error amplifier 240. The voltage-reference signal VRV is supplied with a positive input terminal of the error amplifier 240. An output terminal of the error amplifier 240 outputs the voltage-feedback signal COMV. Therefore, the error amplifier 240 generates the voltage-feedback signal COMV in accordance with the output voltage VO (as shown in
The voltage-feedback signal COMV is further connected to a positive input terminal of a buffer (OD) 245 to generate the feedback signal FB. A negative input terminal of the buffer 245 is coupled to an output terminal of the buffer 245. The current-feedback signal COMI is further connected to a positive input terminal of a buffer 235. A negative input terminal of the buffer 235 is coupled to an output terminal of the buffer 235. The output terminal of the buffer 245 is parallel connected to the output terminal of the buffer 235. The buffer 235 and the buffer 245 have the open-drain output, thus they can be wire-OR connected.
The over-voltage reference threshold VOV and a threshold VT are coupled to a multiplexer (MUX) 260. The multiplexer 260 outputs the over-voltage reference threshold VOV or the threshold VT as an over-voltage threshold for the over-voltage protection. Therefore, the multiplexer 260 is associated with the third register 83 and the third digital-to-analog converter 93 (as shown in
The threshold VT is a minimum threshold for the over-voltage protection. The over-voltage threshold of the over-voltage protection is programmable by the micro-controller 80 through programming the level of the over-voltage reference threshold VOV. This over-voltage threshold will be reset as a minimum value (the threshold VT) if the watch-dog signal WG is not generated in time periodically. For example, the over-voltage threshold will be programmed to 14V for a 12V output voltage VO, and the over-voltage threshold will be programmed to 6V for a 5V output voltage VO. If the watch-dog signal WG is not generated by the micro-controller 80 timely, then the over-voltage threshold will be reset to 6V even the output voltage VO is set as 12V, which will protect the power supply from abnormal operation when the micro-controller 80 is operated incorrectly. Further, the over-voltage threshold also will be reset as the minimum value in response to the power-on of the power supply.
An output signal of the comparator 265 is coupled to a gate of a transistor 271. Once the output voltage VO is higher than the over-voltage threshold (the over-voltage reference threshold VOV or the threshold VT), the output signal of the comparator 265 drives the transistor 271 for generating the control signal SX (logic-low level). A source of the transistor 271 is coupled to the ground. A drain of the transistor 271 outputs the control signal SX. Accordingly, the comparator 265 is utilized to compare the output voltage VO with the over-voltage threshold for the over-voltage protection. The comparator 265 is associated with the transistor 271 as an over-voltage protection circuit to generate the control signal SX. The control signal SX serves as an over-voltage signal. As shown in
The control signal CNT from the micro-controller 80 also drives a transistor 272 to generate the control signal SX. The control signal CNT is coupled to a gate of the transistor 272. A source of the transistor 272 is coupled to the ground. A drain of the transistor 272 outputs the control signal SX. The outputs of the transistors 271 and 272 are parallel connected. Thus, the control signal SX is used for the protection of the power supply and the control of the micro-controller 80.
The constant current source 283 is utilized to charge the capacitor 285. The input signal CLR of the watch-dog timer 280 is coupled to discharge the capacitor 285 via the inverter 281 and the transistor 282. If the capacitor 285 is not discharged by the input signal CLR timely, then the comparator 290 will generate the expired signal TOUT when the voltage of the capacitor 285 is charged and higher than the threshold VTH1. At this time, the level of the expired signal TOUT is the logic-low level.
The voltage-loop signal VEA is coupled to a positive input terminal of a comparator 315. A reference signal REF_V is supplied with a negative input terminal of the comparator 315. The voltage-loop signal VEA is coupled to the comparator 315 for generating an over-voltage signal OV when the voltage-loop signal VEA is higher than the reference signal REF_V. The current-loop signal IEA is coupled to a negative input terminal of an amplifier 325. A reference signal REF_I is supplied with a positive input terminal of the amplifier 325. The current-loop signal IEA associated with the reference signal REF_I generates a current feedback signal IIB for generating the switching signal SW. Therefore, the switching controller 300 generates the switching signal SW in accordance with the reference signal REF_I.
A programmable circuit 400 is coupled to generate the reference signals REF_V, REF_I, and a protection signal PRT in response to the control signal SY and the power-on reset signal PWRST. The reference signal REF_V is operated as an over-voltage threshold signal for the over-voltage protection. This over-voltage protection is developed by the detection of the reflected signal VS. The reference signal REF_I is operated as a current limit threshold signal for limiting the output current IO (as shown in
The protection signal PRT and the over-voltage signal OV are coupled to generate an off signal OFF via an OR gate 331. A resistor 335 is utilized to pull high the feedback signal VB. The feedback signal VB is coupled to generate a secondary feedback signal VA through a level-shift circuit. The level-shift circuit comprises a transistor 336, and resistors 335, 337, 338. A drain of the transistor 336 is coupled to a supply voltage VDD. A first terminal of the resistor 335 is coupled to the supply voltage VDD and the drain of the transistor 336. A second terminal of the resistor 335 is coupled to a gate of the transistor 336 and the feedback signal VB. The gate of the transistor 336 is further coupled to receive the feedback signal VB. A source of the transistor 336 is coupled to a first terminal of the resistor 337. The resistor 338 is coupled between a second terminal of the resistor 337 and the ground. The secondary feedback signal VA is generated at the joint of the resistors 337 and 338. The secondary feedback signal VA is correlated to the feedback signal VB.
A PWM circuit (PWM) 350 generates the switching signal SW in response to the secondary feedback signal VA, the current feedback signal IFB, the off signal OFF, and the power-on reset signal PWRST.
The ramp signal RMP is coupled to negative input terminals of comparators 365 and 367. The current feedback signal IFB is coupled to a positive input terminal of the comparator 365 to compare with the ramp signal RMP. The secondary feedback signal VA is coupled to a positive input terminal of the comparator 367 to compare with the ramp signal RMP. Output terminals of the comparators 365 and 367 are coupled to input terminals of an AND gate 370. The off signal OFF is further coupled to the input terminal of the AND gate 370 though the inverter 351. The power-on reset signal PWRST is also coupled to the input terminal of the AND gate 370. An output terminal of the AND gate 370 is coupled to a reset input terminal R of the flip-flop 375.
The clock signal PLS periodically enables the switching signal SW via the flip-flop 375. The switching signal SW will be disabled once the ramp signal RMP is higher than the current feedback signal IFB in the comparator 365 or the secondary feedback signal VA in the comparator 367. The off signal OFF is also coupled to disable the switching signal SW through the inverter 351 and the AND gate 370. The power-on reset signal PWRST is also coupled to disable the switching signal SW through the AND gate 370.
A pulse-position modulation circuit (PPM) 500 generates a demodulated signal SM and a synchronous signal SYNC in response to the pulse signal SCNT. The pulse signal SCNT indicates the control signal SX of the controller 100 (as shown in
Therefore, the reference signal REF_V and the reference signal REF_I are programmable by the micro-controller 80 of the controller 100. The reflected signal VS of the transformer 10 (as shown in
The pulse signal SCNT is further coupled to a timer (TIMER_L) 420 for detecting the pulse width of the pulse signal SCNT. That is, the timer 420 is used to detect the logic-low period of the control signal SX shown in
This protection signal PRT is coupled to the OR gate 331 (as shown in
Another timer (TIMER_H) 425 is coupled to receive the pulse signal SCNT through an inverter 427. An output terminal of the timer 425 is coupled to an AND gate 426. The timer 425 will generate a reset signal PRST via the AND gate 426 once the pulse signal SCNT is not generated over a specific period TOT. The circuit of the timer 425 can be the same as the circuit of the watch-dog timer 280 shown in
Therefore, the reference signal REF_V will be set to a minimum value (reference signal VRF), that is the initial value, for the over-voltage protection once the control signal SX is not generated in time by the controller 100 or the power supply is powered on. Besides, the reference signal REF_I will be set to a minimum value (reference signal IRF), that is the initial value, for limiting the output current IO once the control signal SX is not generated in time by the controller 100 or the power supply is powered on. Therefore, if the micro-controller 80 is not operated properly, then the threshold (reference signal REF_V) for the over-voltage protection and the threshold (reference signal REF_I) for the output current limit will be reset to the minimum value for the protection.
Consequently, the control signal SX generated by the controller 100 is used for,
(1) the over-voltage protection when the over-voltage is detected in the controller 100;
(2) the communication for setting the over-voltage threshold (REF_V) and the current limit threshold (REF_I) in the switching controller 300;
(3) resetting the timer 425 in the switching controller 300 to ensure the controller 100 is operated properly, otherwise the over-voltage threshold (REF_V) and the current limit threshold (REF_I) of the switching controller 300 will be reset to the minimum value for protecting the power supply.
A positive input terminal of a comparator 530 is coupled to the first terminal of the capacitor 520. A threshold VT2 is supplied with a negative input terminal of the comparator 530. The comparator 530 will generate a data signal SD as a logic-high level once the slope signal SLP is higher than the threshold VT2. The data signal SD is coupled to an input terminal D of a flip-flop 570. The pulse signal SCNT is further coupled to a clock input terminal CK of the flip-flop 570. The data signal SD will be latched into the flip-flop 570 in response to the pulse signal SCNT for generating the demodulated signal SM at an output terminal Q of the flip-flop 570. The power-on reset signal PWRST is coupled to a reset input terminal R of the flip-flop 570 to reset the flip-flop 570. The pulse signal SCNT is further coupled to generate the synchronous signal SYNC through a pulse generation circuit 580. The demodulated signal SM is generated in accordance with the pulse position of the control signal SX.
Although the present invention and the advantages thereof have been described in detail, it should be understood that various changes, substitutions, and alternations can be made therein without departing from the spirit and scope of the invention as defined by the appended claims. That is, the discussion included in this invention is intended to serve as a basic description. It should be understood that the specific discussion may not explicitly describe all embodiments possible; many alternatives are implicit. The generic nature of the invention may not fully explained and may not explicitly show that how each feature or element can actually be representative of a broader function or of a great variety of alternative or equivalent elements. Again, these are implicitly included in this disclosure. Neither the description nor the terminology is intended to limit the scope of the claims.
This Application is based on Provisional Application Ser. No. 61/749,972, filed 8 Jan. 2013, and priority thereto is hereby claimed. The present application is also a continuation application of patent application Ser. No. 15/891,035 filed on Feb. 7, 2018 which was a continuation of prior U.S. application Ser. No. 14/148,955, filed on Jan. 7, 2014, which are all hereby incorporated herein by reference, and priority thereto for common subject matter is hereby claimed.
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Child | 16521043 | US | |
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Child | 15891035 | US |