USRE46333EActiveUtility

High-side sensing of zero inductor current for step-down DC-DC converter

62
Assignee: Intersil Americas LLCPriority: Mar 3, 2008Filed: Nov 27, 2013Granted: Mar 7, 2017
Est. expiryMar 3, 2028(~1.7 yrs left)· nominal 20-yr term from priority
B01J 13/04
62
PatentIndex Score
0
Cited by
16
References
17
Claims

Abstract

A DC to DC converter circuit includes circuitry for generating a PWM waveform signal at a phase node of a DC to DC converter responsive to an input voltage and a monitor monitored output voltage. The circuitry further includes a high side switching transistor connected between the input voltage and a phase node and a low side switching transistor connected between the phase node and ground. An output filter is connected to the circuitry for generating the PWM waveform signal. The output filter includes an inductor having a first side connected to the phase node and a second side connected to an output voltage node. Detection circuitry detects zero current crossings in the inductor responsive to a voltage across the high side switching transistor and a voltage across the low side switching transistor.

Claims

exact text as granted — not AI-modified
What is claimed is: 
     
       1. A DC to DC DC-to-DC converter circuit, comprising:
 circuitry for generating configured to generate a PWM waveform signal of the DC to DC DC-to-DC converter responsive to an input voltage and a monitored output voltage, the circuitry further comprising a high side high-side switching transistor connected between the input voltage and the a phase node and a low side low-side switching transistor connected between the phase node and ground; 
 an output filter connected to the circuitry for generating and configured to generate the PWM waveform signal, the output filter including an inductor having a first side connected to the phase node and a second side connected to an output voltage node; 
 detection circuitry for detecting zero current configured to detect zero-current crossings in the inductor responsive to a voltage across the high side high-side switching transistor and a voltage across the low side low-side switching transistor; and 
 wherein the detection circuitry detects is configured to detect zero current crossing zero-current crossings in the inductor using the turn on time of a high side during a turn-on time of the high-side switching transistor at while circuitry is operating in a frequency range causing that causes a turn on turn-on time of a low side the low-side switching transistor to be too short to detect the zero current crossing zero-current crossings in the inductor using the low side low-side switching transistor. 
 
     
     
       2. The DC to DC DC-to-DC converter circuit of  claim 1 , wherein the detection of the zero current crossings in the inductor enables the DC to DC DC-to-DC converter to pass from a PWM mode to a PFM mode. 
     
     
       3. The DC to DC DC-to-DC converter circuit of  claim 1 , wherein the detection circuitry further comprises:
 a first comparator for comparing configured to compare a first voltage at the phase node with a second voltage at the ground and generating to generate a first output responsive thereto; 
 a second comparator for comparing configured to compare the first voltage at the phase node with a third voltage at an input voltage node and generating to generate a second output responsive thereto; and 
 a logical OR gate connected to receive the first output and the second output and to generate a third output responsive thereto, wherein the third output indicates the zero current zero-current crossings in the inductor. 
 
     
     
       4. The DC to DC DC-to-DC converter circuit of  claim 3 , wherein the first comparator providing is configured to generate the first output at a first logical level is responsive to a difference between the first voltage and the second voltage going from a negative value to a positive value and further wherein the second comparator providing is configured to generate the second output at the first logical level is responsive to a difference between the first voltage and the third voltage going from a negative value to a positive value. 
     
     
       5. The DC to DC DC-to-DC converter circuit of  claim 3 , wherein the detection circuitry can is configured to detect the zero current zero-current crossings in the inductor when while the operating frequency of the DC to DC DC-to-DC converter operates at is in a frequency range causing a turn on turn-on time of the low side low-side switching transistor to be too short for the first comparator to detect the zero current zero-current crossings in the inductor. 
     
     
       6. The DC to DC DC-to-DC converter circuit of  claim 2 , wherein the detection circuitry detects the zero current is configured to detect the zero-current crossings in the inductor using the turn on time of high side during the turn-on time of the high-side switching transistor at while the circuitry is operating in a frequency range causing a turn on time of the low side which causes the turn-on time of the low-side switching transistor to be too short for the first comparator to detect the zero current zero-current crossings in the inductor. 
     
     
       7. Detection circuitry for detecting zero current zero-current crossings through an inductor of a DC to DC DC-to-DC converter circuit, comprising:
 a first comparator for detecting a turn on time of a low side configured, during a turn-on time of a low-side switching transistor by comparing, to compare a first voltage at the a phase node with a second voltage at a ground node and generating to generate a first output responsive thereto; 
 a second comparator for detecting a turn on time of a high side configured, during a turn-on time of a high-side switching transistor by comparing, to compare the first voltage at the phase node with a third voltage at an input voltage and generating to generate a second output responsive thereto; 
 a logical OR gate connected to receive the first output and the second output and to generate a third output responsive thereto, wherein the third output indicates the zero current zero-current crossings in the inductor; and 
 wherein the detection circuitry can is configured to detect the zero current zero-current crossings in the inductor when while the operating frequency of the DC to DC DC-to-DC converter operates at is in a frequency range causing a turn on time of the low side turn-on time of the low-side switching transistor to be too short for the first comparator to detect the zero current zero-current crossings in the inductor. 
 
     
     
       8. The detection circuit of  claim 7 , wherein the detection of the zero current zero-current crossings in the inductor enables the DC to DC DC-to-DC converter to pass from a PWM mode to a PFM mode. 
     
     
       9. The detection circuit of  claim 7 , wherein the first comparator providing is configured to generate the first output at a first logical level is responsive to a difference between the first voltage and the second voltage going from a negative value to a positive value and further wherein the second comparator providing is configured to generate the second output at the first logical level is responsive to a difference between the first voltage and the third voltage going from a negative value to a positive value. 
     
     
       10. The detection circuit of  claim 7 , wherein the detection circuitry detects is configured to detect the zero current zero-current crossings in the inductor using the turn on time of high side during the turn-on time of the high-side switching transistor at while the detection circuitry is operating in a frequency range causing a turn on time of the low side which causes the turn-on time of the low-side switching transistor to be too short for the first comparator to detect the zero current zero-current crossings in the inductor. 
     
     
       11. A method for detecting zero current zero-current crossings within a DC to DC DC-to-DC converter circuit, comprising the steps of:
 generating a PWM waveform signal of the DC to DC DC-to-DC converter responsive to an input voltage and a monitored output voltage; 
 filtering the PWM waveform signal through an output filter including and an inductor to generate an output voltage; and  
 detecting zero current the zero-current crossings in the inductor responsive to a voltage voltages across both a high side high-side switching transistor and a low side low-side switching transistor when while the operating frequency of the DC to DC DC-to-DC converter operates at in a frequency range causing a turn on turn-on time of the low side low-side switching transistor to be too short to detect the zero current crossing zero-current crossings in the inductor using only the low side low-side switching transistor. 
 
     
     
       12. The method of  claim 11 , wherein the step of detecting further comprises the steps of:
 detecting an “on” state of the low side low-side switching transistor; 
 detecting an “on” state of the high side high-side switching transistor; and 
 generating an indication of the zero current crossing zero-current crossings responsive to the detection of the “on” state of at least one of the low side low-side switching transistor and the “on” state of at least one of the high side high-side switching transistor. 
 
     
     
       13. The method of  claim 11  further including the step of switching the DC to DC DC-to-DC converter from a PWM mode to a PFM mode responsive to the detection of the zero current zero-current crossings in the inductor. 
     
     
       14. The method of  claim 11 , wherein the step of detecting further comprises the steps of:
 comparing a first voltage at a phase node on a first side of the low side low-side switching transistor with a second voltage at a ground node on a second side of the low side low-side switching transistor; 
 generating a first output responsive to the comparison of the first voltage and the second voltage; 
 comparing the first voltage at the phase node on a first side of the high side high-side switching transistor with a third voltage at an input voltage node on a second side of the high side high-side switching transistor; and 
 generating a second output responsive to the comparison of the first voltage and the third voltage; and 
 logically ORing the first output and the second output to generate a third output, wherein the third output indicates the zero current zero-current crossings in the inductor. 
 
     
     
       15. The method of  claim 14 , wherein the step of generating the first output further comprises the step of generating the first output at a first logical level responsive to a difference between the first voltage and the second voltage going from a negative value to a positive value. 
     
     
       16. The method of  claim 15 , wherein the step of generating the second output further comprises the step of generating the second output at the first logical level responsive to a difference between the first voltage and the third voltage going from a negative value to a positive value. 
     
     
       17. Detection circuitry for detecting zero current zero-current crossings through an inductor of a DC to DC DC-to-DC converter circuit, comprising:
 a first comparator for detecting a turn on time of a low side configured, during a turn-on time of a low-side switching transistor by comparing, to compare a first voltage at the a phase node with a second voltage at a ground node and generating to generate a first output responsive thereto; 
 a second comparator for detecting a turn on time of a high side configured, during a turn-on time of a high-side switching transistor by comparing, to compare the first voltage at the phase node with a third voltage at an input voltage node and generating to generate a second output responsive thereto; 
 a logical OR gate connected to receive the first output and the second output and to generate a third output responsive thereto, wherein the third output indicates the zero current zero-current crossings in through the inductor; and 
 wherein the detection circuitry detects the zero current crossings in the inductor using the turn on time of high side is configured to detect the zero-current crossings through the inductor using the high-side switching transistor during the turn-on time of the high-side switching transistor at while the low-side switching transistor is operating in a frequency range  causing a turn on time of the low side which causes the turn-on time of the low-side switching transistor to be too short for the first comparator to detect the zero current crossings in the inductor zero-current crossings through the inductor using the low-side switching transistor.

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