Abstract:
Method and apparatus for providing a regulated, direct current (DC) output voltage for use in computers. An unregulated voltage source is regulated by a power converter of the present invention that produces the regulated voltage reliably, inexpensively, and without requiring heat sinks or auxiliary fans. In a preferred embodiment, the power converter includes a buck regulator and a control circuit. The control circuit includes a resistor-divider feedback loop connected to the output of the buck regulator in order to provide a feedback voltage. The feedback voltage is supplied to an error amplifier which compares the feedback voltage to an internal reference voltage and produces an output that is the amplified difference between the two voltages. The amplified output is then provided to a frequency modulation (FM) port of a multipurpose timer. As a result, the timer can control and modulate the frequency and pulse width of the buck regulator.

Description:
TECHNICAL FIELD 
     The invention relates generally to computers and more specifically, to a relatively low cost frequency modulating and pulse width modulating power converter for use with computers and the like. 
     BACKGROUND OF THE INVENTION 
     A power converter is simply a device that converts energy from an input source to produce a regulated output source of energy. Although there are many types and applications for power converters, one such type is a switching, direct current (DC) to DC, step-down power converter, or &#34;buck&#34; regulator, for use in computers and the like. 
     FIG. 1 illustrates a conventional non-synchronous buck regulator, designated generally by the reference numeral 10. The buck regulator 10 receives an input voltage V IN  and drives an output voltage V OUT  and an output current I OUT  for use by a load Z, such that V OUT  &lt;V IN . The buck regulator 10 comprises a switch S1, which is typically a field effect transistor (&#34;FET&#34;), a diode D1, an inductor L1 and a capacitor C1. A control circuit 12 turns the switch &#34;off&#34; and &#34;on&#34;, i.e., non-conducting and conducting, respectively, as discussed in greater detail below. 
     The buck regulator 10 operates on the principle of pulse width modulation to provide &#34;point-of-load&#34; voltage regulation. Point-of-load voltage is the voltage level directly at the load Z. A voltage V D1 , across the diode D1 is manipulated in such a way that the output voltage V OUT  maintains the point-of-load voltage at a regulated voltage level. 
     The control circuit 12 modulates the switch S1 between &#34;off&#34; and &#34;on&#34; for specific periods, or pulses, of time, referred to as pulse width modulation (&#34;PWM&#34;). In this way, the control circuit 12 controls the duty cycle of the switch S1, and thereby controls the output voltage V OUT . Switching regulators such as the buck regulator 10 have conventionally used dedicated PWM chips for the control circuit 12. 
     Conventional dedicated PWM chips have only moderate performance responses to sharp changes in the point-of-load voltage at the load Z. When the load Z has a sharp transient response, it increases the output current I OUT  and thereby causes the output voltage V OUT  to sharply fall. As a result, the PWM chip must increase the duty cycle so that it may rapidly pull the output voltage V OUT  back to the desired point-of-load voltage level. 
     The PWM chip increases the duty cycle by increasing the &#34;on&#34; time and decreasing the &#34;off&#34; time of the switch S1, thereby maintaining a fixed frequency. The changes in the duty cycle occur incrementally, i.e., the PWM chip can not make large and instantaneous changes in the duty cycle. The changes in the duty cycle are also restricted by the fixed frequency because the &#34;on&#34; time can not exceed the frequency period. Because of the small change in pulse width, the point-of-load voltage and output voltage V OUT  will continue to drop until the regulator has sufficiently increased the duty cycle. As a result, hard and/or soft errors may occur in the load Z, depending on the sensitivity of the load to large swings in the point-of-load voltage. 
     In addition, dedicated PWM chips are relatively expensive. As a result, one solution has been to use linear regulators. Linear regulators are often fairly inexpensive and very simple, by contrast, to the buck regulator 10. However, linear regulators require substantial heat sinking. Typically, for higher power levels, an extruded heat sink is required, even when used with an auxiliary fan. Thus while the regulators are low in cost and easy to manufacture, they have poor thermal performance. As a result, the cost savings from using a linear regulator are expended on thermal management using a heat sink and/or auxiliary fan. 
     Therefore, what is needed is a power converter such as a buck regulator with a control circuit that is relatively inexpensive. 
     Furthermore what is needed is a power converter which does not have the thermal penalties of a conventional linear regulator. 
     Furthermore what is needed is a power converter such as a buck regulator, with relatively sharp responses to transients in the point-of-load voltage. 
     SUMMARY OF THE INVENTION 
     The foregoing problems are solved and a technical advance is achieved by a low cost method and apparatus for providing a regulated, direct current (DC) output voltage for use in computers and the like. An unregulated voltage source is regulated by a power converter of the present invention that produces the regulated voltage reliably, inexpensively, and without requiring heat sinks or auxiliary fans. 
     In a preferred embodiment, the power converter includes a buck regulator comprising an n-type field effect transistor (FET) switch with the drain connected to the unregulated power source and the source connected to a diode&#39;s cathode. The anode of the diode is connected to a ground supply. An inductor is connected between the source of the switch and an output node of the power converter and a capacitor is connected between output node and ground. 
     The power converter also includes a resistor-divider feedback loop connected to the output node to provide a feedback voltage. The feedback voltage is supplied to a shunt regulator, acting as an error amplifier, which compares the feedback voltage to an internal voltage and produces an output that is the amplified difference between the two voltages. The amplifier output is then provided to a frequency modulation (FM) port of a multipurpose timer. The output of the timer is connected to the gate of the switch, thereby allowing the timer to control and modulate the frequency and pulse width of the switch. 
     A technical advantage achieved with the invention is that it provides a relatively inexpensive power converter. 
     Another technical advantage achieved with the invention is that it provides a power converter with sharp responses to transients in the output voltage. 
     Another technical advantage achieved with the invention is that it provides a power converter that does not have the thermal penalties of a conventional linear regulator. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic of a prior art, non-synchronous buck voltage regulator. 
     FIG. 2 is a block diagram of a computer system utilizing a power converter and power distribution circuit of the present invention. 
     FIG. 3 is a schematic diagram of the power converter of FIG. 2. 
     FIG. 4 is a schematic diagram of the power distribution circuit of FIG. 2. 
     FIG. 5 shows voltage waveforms illustrating the operation of the power converter of FIG. 2, as compared to the operation of the non-synchronous buck voltage regulator of FIG. 1. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     As mentioned above, FIG. 1 schematically represents a conventional, non-synchronous, direct current (&#34;DC&#34;) to DC step down converter commonly referred to as a buck regulator. 
     Referring to FIG. 2, the reference numeral 20 refers to a personal computer, though it may also refer to a laptop computer, a file server, a mainframe computer, or other electrical device. The computer 20 includes an alternating current (&#34;AC&#34;) to DC power converter 22, a DC to DC power converter 24, a power distribution circuit 26, a processing device 28, a memory device 30 and a peripheral device 32. The processing device 28, memory device 30 and peripheral device 32 are representative of a plurality of electronic devices of the computer 20, and are collectively represented as a load Z1. 
     The AC to DC power converter 22 receives AC power through a power plug 34. Although not shown, the power plug 34 connects to a conventional electrical outlet. However, the power plug 34, as well as the AC to DC power converter 22 may not exist in some applications, such as a laptop computer or other battery driven devices. The AC to DC power converter 22 sources at least three separate DC voltages: a 12V supply, a 5V supply, and a 3.3V supply, as well as a 0V or ground supply GND. 
     The DC to DC converter 24 and the power distribution circuit 26 receive the DC voltages from the AC to DC power converter 22. The DC to DC converter 24 drives a first voltage V1, which in the present description also represents the point-of-load voltage for the load Z1. The power distribution circuit 26 drives a second voltage V2. The DC to DC converter 24 and the power distribution circuit 26 also receive a dual-power signal V DET . The dual-power signal V DET  is a conventional signal that allows the DC to DC converter 24 and the power distribution circuit 26 to support different voltage requirements of the computer 20. In the preferred embodiment, if the load Z1 requires two separate voltages V1, V2, such that V1≠V2, then the level of the dual-power signal V DET  is set &#34;low.&#34; If, however, the load Z1 requires a single voltage V1, V2, such that V1=V2, then the dual-power signal V DET  is set &#34;high.&#34; 
     Referring to FIG. 3, the DC to DC power converter 24 uses a multipurpose timer 40 to control a switch 42. In the preferred embodiment, the switch 42 is a field effect transistor (&#34;FET&#34;) and the multipurpose timer 40 is a conventional &#34;555&#34; timer, such as the LM555 timer manufactured by National Semiconductor Company of Santa Clara, Calif. The pin numbers 1-8 shown on the timer chip 40 also correspond to the LM555. Trigger, reset and threshold levels for the timer chip 40 are configured, as shown, by resistors 42, 44 and capacitors 46 connected between the 12V power supply and ground GND. Such a configuration of the timer 40 is well known by those of ordinary skill in the art and, for the sake of brevity, will not be further discussed. 
     An output 50 of the timer chip 40 connects to the gate of the FET 42 through an optional resistor 52. The drain of the FET 42 is tied to the 5V power supply, which is decoupled with a capacitor 54. The source of the FET 42 and a cathode of a diode 58 are commonly connected to a node A, wherein a voltage V A  represents the voltage difference between the node A and ground GND. The anode of the diode 58 is connected to ground GND. An inductor 60 is connected between the node A and a node B, wherein the first voltage V1 represents the voltage difference between the node B and ground GND. An output capacitor 62 is also connected between the node B and ground GND. 
     The first voltage V1 also supports a feedback loop comprising voltage divider resistors 64, 66 connected between the node B and ground GND, thereby producing a feedback voltage V FBK  at a node C. The feedback voltage V FBK  is also selectively responsive to the dual-power signal V DET  and circuit 67. If the dual-power signal V DET  is low, the circuit 67 has no effect on the feedback voltage V FBK . If the dual-power signal V DET  is high, the circuit 67 places a resistor 68 in parallel with the resistor 66, thereby reducing the feedback voltage V FBK . 
     The feedback voltage V FBK  is supplied to a voltage input 69 of a shunt regulator 70, which in the preferred embodiment is a TL431 shunt regulator manufactured by National Semiconductor Company of Santa Clara, Calif. The shunt regulator 70 serves as an error amplifier, in that it compares a voltage on the voltage input 69 with an internal voltage, and amplifies the difference accordingly. The shunt regulator 70 used in the present invention has an anode connected to ground GND, a cathode connected to a node D and an internal reference voltage of about 2.5V. The node D connects the shunt regulator cathode to the frequency modulation (&#34;FM&#34;) port 72 of the timer 40 through a resistor 74. The node D is also pulled high by a resistor 76 and supports a control loop compensation network comprising a resistor 78 and a capacitor 80 going to the voltage input 69 of the shunt regulator. 
     Referring to FIG. 4, the power distribution circuit 26 receives the first voltage V1 and the dual-power signal V DET  to produce the second voltage V2. If the dual-power signal V DET  is low, a FET 80, which is connected between the 3.3V power supply and the second voltage V2, drives the second voltage V2 to about 3.3V. If the dual-power signal V DET  is high, two FETs 82, 84 tie the second voltage V2 to the first voltage V1. 
     Referring to FIGS. 2-4, in operation, the DC to DC power converter 24 provides a relatively stable point-of-load voltage for the load Z1. The timer 40 drives the output 50 at an initial frequency and duty cycle, as determined by the resistors 42, 44 and the capacitor 46. However, if a change occurs in the point-of-load voltage, such as one caused by a sudden increase in current consumption by the load Z1, the level of the first voltage V1 will drop. 
     The shunt regulator 70 works to compensate for the drop in the first voltage V1 by comparing the feedback voltage V FBK  with an internal feedback voltage and amplifying the difference therebetween. Whenever the first voltage V1 drops, the feedback voltage V FBK  also drops. Therefore, as the feedback voltage V FBK  changes, the shunt regulator 70 output at node D changes at an amplified rate. 
     The shunt regulator 70 controls the FM port 72 of the timer 40. Because the shunt regulator 70 provides a fast and broad range of change in the voltage level of node D, both the frequency and the pulse width of the timer output 50 are modulated. In response, the &#34;on&#34; time, or pulse width, of the FET 42 can be increased past the original frequency period of the FET. By modulating both the pulse width and frequency, the combination of both the shunt regulator 70 and timer 40 cause the output voltage V OUT  to quickly regain the original point-of-load voltage level. 
     Referring also to FIGS. 1 and 5, the performance of the present invention is dramatically improved over that of the prior art buck regulator 10 of FIG. 1, as shown by three graphs 90, 92, and 94. For example, if at a time t1 the load Z1 begins to consume a great deal of current, the first voltage V1 of the present invention only drops to a voltage level 100. However, in the prior art buck regulator 10, the output voltage V OUT  drops to a lower voltage level 102. In addition, at a time t2 when the point-of-load voltage reaches its desired voltage level, the output voltage V OUT  overshoots the desired voltage level, as compared to the first voltage V1 of the present invention. The improved performance of the present invention is due to the responsiveness of the timer 40, with respect to the shunt regulator 70, over that of the conventional control circuit 12. 
     The graph 92 illustrates the switching performance of the switch S1 of the prior art buck regulator 10. The control circuit 12 is limited to the fixed frequency ƒ as well as small incremental changes in pulse width &#34;on&#34; time of the voltage V D1 . As a result, at the time t1, the pulse width &#34;on time&#34; of the switch S1 is only slightly increased, and can never exceed the length of the frequency period. As a result, the output voltage V OUT  drops to the voltage level 102. In addition, at the time t2, the pulse width &#34;off time&#34; of the switch S1 is only slightly decreased, so that the output voltage V OUT  rises above the voltage level 102. 
     The graph 94 illustrates the performance of the DC to DC power converter 24 of the present invention. The timer 40 is not limited to a fixed frequency, but supports frequency modulation such as f1, f2, f3, f4, f5, f6 wherein f1≠f2, f2≠f3, f3≠f4, f4≠f5, and f5≠f6. Not being bound to a fixed frequency, the &#34;on time&#34; of the voltage V A  is capable of relatively large incremental changes. For example, an on-time t3 of the voltage V A  immediately after the time t1 is greater than both the on-time t4 and off-time t5 immediately preceding the time t1. Likewise, an off-time t6 immediately after the time t2 is greater than both the off-time t7 and the on-time t8 immediately preceding the time t2. As a result, the present invention provides a voltage regulator that is more responsive to changes in the point-of-load voltage, thereby allowing the first voltage V1 to only drop to the voltage level 100 and to only rise slightly above the desired voltage level. 
     In summary, the DC to DC power converter 24 of the present invention provides a more reliable point-of-load voltage for the load Z1 than that of the prior art. Furthermore, because the timer 40 and the shunt regulator 70 have a combined cost of about one-fifth that of the dedicated control chip of the prior art, the present invention is relatively inexpensive. Finally, the present invention does not have the thermal considerations of a linear regulator, and therefore does not require a heat sink and/or auxiliary fan. 
     Although an illustrative embodiment of the invention has been shown and described, other modifications, changes, and substitutions are intended in the foregoing disclosure. In addition, portions of the preferred embodiment, such as circuits and components associated with the dual-power signal V DET  and the second voltage V2, can be removed or modified, while still utilizing the present invention. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the invention.