This disclosure relates generally to integrated circuits that are used in, for example, computing devices, and more particularly but not exclusively, to circuits and methods that solve the problem of glitches occurring in a reset signal that is applied to an integrated circuit on a circuit board. The present invention also relates more particularly to circuits and methods that enhance the operation of integrated circuits.
When an integrated circuit (i.e., a chip or part) is on a circuit board, the reset signal applied to the integrated circuit usually has glitches, and these glitches can lock up the integrated circuit, as well as prevent the integrated circuit from functioning. Thus, it is desirable to eliminate such glitches from the reset signals and enhance the operation of the integrated circuit. Conventionally, a glitch free reset signal is obtained from the circuit board. In conventional approaches, emphasis was typically based on eliminating such glitches on the reset signals that are applied to the integrated circuit.
However, as the number of cards on the circuit board increases, the likelihood of completely eliminating a glitch in a reset signal from the circuit board decreases. Accordingly, improvements are needed with regard to solving the problem of glitches that occur in reset signals that are applied to integrated circuits.
Non-limiting and non-exhaustive embodiments of the present invention are described with reference to the following figures, wherein like reference numerals refer to like parts throughout the various views unless otherwise specified.
Embodiments of systems and methods for compensating for a glitch occurrence in a reset signal are disclosed herein. As an overview, an embodiment of the invention provides a reset circuit that compares an original reset signal with a delayed version of the reset signal. When the reset circuit detects both the original non-delayed reset signal and the delayed version of the reset signal to be in the same state, then that state (which is output from an S-R flop) is applied to the appropriate components of an integrated circuit.
In another embodiment, a reset circuit receives an incoming reset signal “reset” and delays an incoming reset signal to generate a delayed reset signal “delayed_reset”. The reset circuit compares the non-delayed reset signal with the delayed_reset signal. When both the non-delayed reset signal and the delayed reset signal are in the same state (asserted state or non-asserted state), then the non-delayed reset signal is sampled as the output value “OUTB”. On the other hand, if the non-delayed reset signal and the delayed_reset signal are not in the same state, then the non-delayed reset signal is not sampled, and the previously sampled state of the non-delayed reset signal is held as the output value “OUTB”. The output value “OUTB” determines the value of the reset signal that is applied to the appropriate components of an integrated circuit.
The present invention advantageously solves the problem of glitch occurrences in reset signals that are applied to integrated circuits. The present invention also advantageously provides circuits and methods that are very versatile and that may be selectively used anywhere on the circuit board to eliminate glitches in signals. The present invention may also advantageously provide circuits and methods that effectively eliminate small glitches in reset signals by minimizing the signal delay and that effectively eliminate larger glitches in reset signals by increasing the signal delay. Thus, the present invention may advantageously enhance the operation of integrated circuits on a circuit board.
In the description herein, numerous specific details are provided, such as the description of system components in
Reference throughout this specification to “one embodiment”, “an embodiment”, or “a specific embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of the phrases “in one embodiment”, “in an embodiment”, or “in a specific embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
Additionally, the signal arrows in the drawings/figures are considered as exemplary and are not limiting, unless otherwise specifically noted. Furthermore, the term “or” as used in this disclosure is generally intended to mean “and/or” unless otherwise indicated. Combinations of components or steps will also be considered as being noted, where terminology is foreseen as rendering the ability to separate or combine is unclear.
It will also be appreciated that one or more of the elements depicted in the drawings/figures can also be implemented in a more separated or integrated manner, or even removed or rendered as inoperable in certain cases, as is useful in accordance with a particular application.
Referring in detail now to the drawings wherein similar parts of the present invention are identified by like reference numerals, and initially referencing
The conventional system 100 is of the type that may be implemented in, for example, a personal computer (PC). The chipset 105, graphics chip 125, and audio chip 130 are coupled together by a bus 135 such as, for example, a peripheral component interconnect (PCI) bus.
As known to those skilled in the art, a chipset is a number of integrated circuits designed to perform one or more related functions. For example, one chipset may provide the basic functions of a modem while another chipset provides the central processing unit (CPU) functions for a computer. Newer chipsets generally include functions provided by two or more older-type chipsets. In some cases, older-type chipsets that require two or more physical chips can be replaced with a chipset on one chip. The chipset 105 communicates with the CPU 110, memory 115, and southbridge 120. The CPU 110 can only communicate directly with the chipset 105. Thus, if the CPU 110 will retrieve data from the memory 115, the CPU 110 will instruct the chipset 105 to retrieve the data from memory 115, and data is then transferred by the chipset 105 from the memory 115 to the CPU 110. Similarly, if the graphics chip 125 or audio chip 130 will retrieve data from the memory 115, the graphics chip 125 or audio chip 130 will instruct the chipset 105 to retrieve the data from memory 115, and data is then transferred by the chipset 105 from the memory 115 to the graphics chip 125 or audio chip 130.
The chipset 105 may be of the type available from, for example, Via Technology, Incorporated, Fremont, Calif. or Intel Corporation, Santa Clara, Calif. The CPU 110 may be of the type available from, for example, Intel Corporation or Motorola Incorporated. The memory 115 may be, for example, a dynamic random access memory (DRAM) for serving as a main memory device.
As known to those skilled in the art, a southbridge is the integrated circuit in a core logic chip set that controls the integrated drive electronics (IDE) bus, universal serial bus.
(USB), plug-n-play support, the Peripheral Component Interconnect Industry Standard Architecture (PCI-ISA) bridge, keyboard/mouse controller, power management, and various other features. One particular southbridge brand provides sound card functions.
The graphics chip 125 may be of the type available from, for example, S3 Graphics, Incorporated, Fremont, Calif., while the audio chip 130 may be of the type available from various manufacturers.
As also known to those skilled in the art, a PCI bus is a local bus standard developed by Intel Corporation. Most modern personal computers include a PCI bus in addition to a more general ISA expansion bus. PCI is also used on newer versions of the Macintosh computer from Apple Computers Corporation, Cupertino, Calif.
The chipset 105 sends a reset signal 140 via bus 135 to the graphics chip 125, audio chip 130, and other chips coupled to the bus 135 before the chipset 105 begins communication with these chips. However, in practice, since multiple chips (e.g., graphics chip 125 and audio chip 130) share the bus 135, the reset signal 140 will not be smooth in form and will include a glitch that adversely impacts the operation of the system 100. In this conventional system 100, components are typically used to try to eliminate glitch occurrence in the reset signal. However, as number of integrated circuits on the circuit board increases, the likelihood of completely eliminating a glitch in a reset signal 140 decreases.
In one embodiment, the present invention provides a reset circuit 325 which compensates for glitch occurrence in a reset signal 330. For purposes of explaining the functionality of the present invention, the reset circuit 325 is shown as being included in the graphics chip 305. However, other reset circuits in accordance with an embodiment of the present invention may also be included in the audio chip 310, in the other chip 315 and/or in other integrated circuits that may be coupled to the bus 320. For example, the audio chip 310 may include a reset circuit 350 in accordance with an embodiment of the present invention. The other chip 315 may include a reset circuit 355 in accordance with an embodiment of the present invention.
It is also noted that in the embodiment shown in
In
In the embodiment illustrated in
The reset circuit 325a uses the S-R flop 410 to recognize the exact state of a reset signal. The reset signal is delayed and then compared with the original, non-delayed reset signal. When both the delayed reset signal and the original, non-delayed reset signal are in the same state (asserted state or un-asserted state), a set or a reset occurs in the S-R flop 410. The output of the S-R flop 410 is fed to all appropriate circuits and components in an integrated circuit that implements the reset circuit 325a.
Various features in
Reference is now made to the reset circuit 325a in
The GFRST_IN0 reset signal is the incoming reset signal that is generated from the chipset 105 and transmitted across the bus 320 to graphics chip 305 and to other integrated circuits that may be coupled to the bus 320 (such as audio chip 310 and/or other chips 315). The GFRST_IN0 reset signal is received by the first input of NAND gate 400 and by the first input of NAND gate 405.
The GFRST_IN100 delayed reset signal is a delayed version of the GFRST_IN0 reset signal. In one embodiment, a delay stage 450 is used to delay the GFRST_IN0 reset signal to generate the GFRST_IN100 delayed reset signal. The delay stage 450 may be formed by, for example, one-hundred delay elements in an array. The delay stage 450 may be located in, for example, in the reset circuit 325 or in the I/O buffer 335 (
During initial time t1, the GFRST_IN0 reset signal and the GFRST_IN100 delayed reset signal are at a low level. The GFRST_IN0 and GFRST_IN100 are received by both the NAND gate 400 (
At time t2, a glitch 500 occurs in the GFRST_IN0 incoming reset signal, and the glitch 500 is delayed by the array 450, as shown at time t3 in the GFRST_IN100 delayed reset signal. At time t4, the edge 505 in the GFRST_IN0 signal occurs as the GFRST_IN0 signal switches from a low level to a high level. This edge 505 is delayed by the array 450 as shown in the GFRST_IN100 delayed reset signal.
When the GFRST_IN0 and GRFST_IN100 signals both switch high, the GFRST_SET signal will switch to a low level, as shown by edge 510 at time t5. When the GFRST_SET signal switches to a low level, the GFRST_QFB signal will switch to a high level as shown by edge 515. This edge 515 is delayed by buffer 415, as shown in the GFRST_Q signal during time t6. The high level GFRST_Q signal is applied to all appropriate components in the integrated circuit (e.g., graphics chip 305) as a reset signal. As shown in
Table 3 shows some input and output values for the S-R flop 410 at successive times (Tn, Tn+1, Tn+2, and Tn+3, and so forth). These values show when the GFRST_QFB output value of the S-R flop 410 switches from a low level to a high level.
X = don't care value
It is noted further that the delay applied to the GFRST_IN0 incoming reset signal can be minimized to compensate for small glitches in the GFRST_IN0 incoming reset signal. The delay applied to the GFRST_IN0 incoming reset signal can be increased to compensate for larger glitches in the GFRST_IN0 incoming reset signal.
It is noted that when the GFRST_RESET signal will switch to a low level as shown by edge 610. The low GFRST_RESET signal will cause the output of NAND 430 to switch to a high level. When the GFRST_SET signal and the output of NAND 430 are both at a high level, then the GFRST_QFB output of NAND 425 will switch to a low level, as shown by edge 615 at time t12. The edge 615 is delayed by buffer 415 as shown by the edge 615 in the GFRST_Q signal at time t12. Thus, after time t12, the GFRST_Q signal (which is applied as the reset signal to the components of an integrated circuit) will be at a low level.
At time t13, a glitch 605 may occur in the GFRST_IN0 incoming reset signal. The delay applied to the GFRST_IN0 glitch and the various components of reset circuit 325 (including S-R flop 410) permit the GFRST_Q signal to remain at a low level even if the glitch 605 occurs in the GFRST_IN0 incoming reset signal.
Table 4 shows some input and output values for the S-R flop 410 at successive times (Tn+10, Tn+11, Tn+12, and Tn+13, and so forth). These values show when the GFRST_QFB output value of the S-R flop 410 switches from a high level to a low level.
X = don't care value
As further shown in
A third logic operation is then performed (820) on the input set flop signal and the input reset flop signal to generate a reset signal without a glitch. For example, the third logic operation is performed (820) on the GFRST_SET input set flop signal and the GFRST_RESET input reset flop signal by the S-R flop 410 (
In one embodiment, the reset circuit (sample-hold circuit) 325b includes an XNOR gate 900, a delay stage (e.g., array) 905, an inverter 910, an optional XOR gate 915, a pass-through circuit 920, and inverters 925 and 930. The pass-through circuit 920 includes N-channel transistor 935 and P-channel transistor 940.
Reference is now made to the reset circuit 325b in
The delay element 905 delays the incoming “reset” signal as the delayed signal “delayed_reset”. Thus, a glitch 1000 in the reset signal will be shown as the delayed glitch 1000 in the delayed_reset signal. Similarly, the positive pulse 1005 in the incoming reset signal will also be delayed as shown in the delayed_reset signal. Similarly, a glitch 1010 that may occur in the incoming reset signal will also be delayed as shown in the delayed_reset signal. The XNOR gate 900 output signal, XNOR_OUT, is determined by the logic operation shown in Table 6. Thus, when both of the reset signal and the delayed_reset signal are in the same state (e.g., when the reset signal and the delayed_reset signal are both low, or when the reset signal and the delayed_reset signal are both high), then the XNOR_OUT value will be high. The interval when the XNOR_OUT value is high is indicated by “s” in
When XNOR_OUT is high, then the N-channel transistor 935 is on because the gate of transistor 935 is receiving the high XNOR_OUT signal. The high XNOR_OUT signal is also inverted by the inverter 910 into a low inverted_XNOR_OUT signal that turns on the P-channel transistor 940. Since both of the transistors 935 and 940 are on, the pass-through circuit 920 will pass through the reset signal. Thus, the value of the reset signal is sampled (as indicated by “s”) and will be the value of OUTB signal.
When XNOR_OUT is low, then the N-channel transistor 935 is off because the gate of transistor 935 is receiving the low XNOR_OUT signal. The low XNOR_OUT signal is also inverted by the inverter 910 into a high inverted_XNOR_OUT signal that turns off the P-channel transistor 940. Since both of the transistors 935 and 940 are off, the pass-through circuit 920 will not pass through the reset signal. Thus, the current value of the reset signal will be held (as indicated by “h”) and will be the value of OUTB signal.
As shown in
In one embodiment, the XOR gate 915 serves to add additional delay to the reset signal to set the timing of arrival to the pass-through circuit 920 of the XNOR_OUT signal, 8 the inverted_XNOR_OUT signal, and the reset signal.
The reset circuits described above are very versatile and can be used in any portion of a circuit board to compensate for glitches in the reset signals. For example, a reset circuit in accordance with an embodiment of the invention can be implemented internally to an integrated circuit or may be implemented externally to an integrated circuit. Other variations and modifications of the above-described embodiments and methods are possible in light of the foregoing teaching.
Further, at least some of the components of this invention may be implemented by using a programmed general-purpose digital computer, by using application specific integrated circuits or field programmable gate arrays, or by using a network of interconnected components and circuits, and/or by use of discrete elements.
It is also within the scope of the present invention to implement a program or code that can be stored in an electronically-readable medium to permit a computer to perform any of the methods described above.
The above description of illustrated embodiments of the invention, including what is described in the Abstract, is not intended to be exhaustive or to limit the invention to the precise forms disclosed. While specific embodiments of, and examples for, the invention are described herein for illustrative purposes, various equivalent modifications are possible within the scope of the invention, as those skilled in the relevant art will recognize.
These modifications can be made to the invention in light of the above detailed description. The terms used in the following claims should not be construed to limit the invention to the specific embodiments disclosed in the specification and the claims. Rather, the scope of the invention is to be determined entirely by the following claims, which are to be construed in accordance with established doctrines of claim interpretation.
This application is a divisional application of U.S. patent application Ser. No. 09/944,963, filed Aug. 31, 2001 and entitled “Glitch Free Reset Circuit” which parent Application is herein incorporated by reference.
Number | Date | Country | |
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Parent | 09944963 | Aug 2001 | US |
Child | 11365068 | Feb 2006 | US |