The present invention relates generally to operation of nonvolatile memory arrays and specifically to operations of nonvolatile memory arrays over a wide range of operating frequencies with low power consumption below a critical frequency.
Non-volatile memory devices, such as electrically erasable and programmable read only memories (EEPROMs), comprise core arrays of memory cells including a variable threshold transistor. Each memory cell can include a number of transistors; at least one of which will be a variable threshold (i.e., programmable) transistor.
With reference to
The plurality of memory cells 101 is each interconnected by a plurality of wordlines lines 103, a plurality of sense lines 105, and a plurality of bitlines 107. In particular, drains of the each of the select transistors 101A are connected to one of the plurality of bitlines 107. A gate of each of the select transistors 101A and the floating gate transistors 101B is each connected to one of the plurality of wordlines 103 and sense lines 107 respectively.
In
The read select transistor 201 is connected to the read select line 201A. When a read operation is active, the read select transistor 201 is turned on, thereby electrically connecting the bitline 107 to the data bus 203A. The data bus 203A, in turn, is connected to the sense amplifier 203. When the non-volatile memory arrangement 200 is subject to a read operation, a conductive state of the memory cell 101 is queried by connecting the bitline 107 to the sense amplifier 203 and applying appropriate bias voltages to the selected bitline 107, sense line 105, and wordline 103. If the select transistor 101A is turned on and the bias voltage applied to the sense line 105 exceeds a threshold of the floating gate transistor 101B, current will flow from the bitline 107 to ground through the memory cell 101 and the sense amplifier 203 will detect a “low” state. Conversely, if the bias voltage applied to the sense line 105 does not exceed the threshold of the floating gate transistor 101B, then no current will flow through the memory cell 101, and the sense amplifier 203 will detect a “high” state. While the sensing approach just described provides an operable memory arrangement, power consumption levels which characterize this approach are disadvantageous.
Power requirements of a contemporary memory sense amplifier are indicated in the dynamic power requirement, Pdyn, as a function of operating frequency, fop, graph 300 of
Pmin=Vdd·ISA
where Vdd is the system voltage and ISA is the sense amplifier current. A linear expression of total memory array power without sense amplifiers, Parray, 303 is governed by
Parray=Ccore·Vdd2·fop
where Ccore is determined from a total gate-source capacitance, Cgs, value of each of the memory transistors within the plurality of memory cells 101 (
Pdyn=(Ccore·Vdd2·fop)+(Vdd·ISA)
which is merely a summation of the constant amplifier consumed power 301 and the linear expression of total memory array power without sense amplifiers 303.
The dynamic power, Pdyn, is a function of one variable—operating frequency, fop. Other functional dependencies, Ccore, Vdd, and ISA, are all fixed for a given memory array configuration. Therefore, it is desirable to minimize the total dynamic power requirement, especially in situations where either the operating frequency is variable during memory array operation or a given memory array is adaptable to a range of operating frequencies within a given circuit.
An automatic address transition detection (ATD) circuit and method is described herein which allows a memory device to operate over a wide range of frequencies; the circuit and method provide for operation under reduced power consumption of the device if the device is operating in accordance with a low system clock frequency (less than, for example, 1 MHz). The reduction in power consumption derives from operating sense amplifiers within the memory device with a steady-state bias current only as compared with a higher-level of current needed for reading a state of memory cells. Therefore, in a system operating at a relatively low clock frequency, the higher-level of current is supplied to the sense amplifiers only at times when they are needed for reading memory cells.
The automatic ATD circuit operates, in one embodiment, with a first delay circuit configured to accept a system clock pulse as an input and produce a delayed version of the system clock pulse as an output. The delay to the system clock is performed to allow a frequency comparison in a later part of the circuit. A rising-edge detection circuit operates when the delayed system clock is received and senses a rising-edge of the delayed system clock pulse. A pulse output from the rising-edge detection circuit feeds into a second delay circuit; the second delay circuit produces an output pulse where a period of the pulse is determined by delay characteristics of the sense amplifier and is thus independent of system clock frequency. The pulse is compared to the system clock frequency. If the system clock frequency is above a determined frequency, the automatic ATD circuit is disabled. If the clock frequency is below the determined frequency, the automatic ATD circuit is enabled and provides a sense amplifier enable signal only when a memory cell read is required.
In an exemplary embodiment of a method of operating the automatic ATD circuit, steps involve delaying an input system clock signal by a first delay period; generating a first pulse (e.g., a rising-edge pulse) based on a the delayed input system clock signal; determining a second delay period based on delay characteristics of the sense amplifier (i.e., sense amplifier characteristics of a time to turn on, a charge delay time, and a time to turn off); producing a critical signal pulse based on the generated pulse and the determined second delay period; and comparing a first period of the system clock signal to the second delay period of the critical signal pulse. If a result of the comparison determines that the first period is shorter than the second period, an address transition detection (ATD) disable pulse is produced. If a result of the comparison determines that the first period is longer than the second period, an address transition detection (ATD) enable pulse is produced.
With reference to
Pres=m·Vdd·ISA,bias
where m is an integer related to a total number of bits within a wordline. Therefore, typically m is set equal to 8, 16, or 32. A linear expression of total memory array power without sense amplifiers, Parray, 405 is governed by
Parray=(Ccore·Vdd2·fop)+(m·Vdd·ISA,bias)
Unlike the prior art, the dynamic power requirement here has two sets of linear traces. A first trace 405 relates to a reduced dynamic power requirement for a memory array without full sense amplifier operation and a second trace 407 relates to a reduced dynamic power requirement for a memory array with full sense amplifier operation. Both the first 405 and the second trace 407 dynamic power requirement occur prior to a critical frequency, fcr, 409. The critical frequency relates to a “slow mode” of memory cell operation and is inversely related to a critical access period, Tcr, such that
fcr=Tcr−1
The critical access period term Tcr will be developed shortly with reference to
Automatic Address Transition Detection (ATD) Circuit
With reference to
Below a “critical frequency,” fcr, the automatic ATD circuit 501 senses whenever an address change occurs and provides a sense amplifier enable, SA_EN, signal to activate sense amplifiers within the memory array. A user can change a system clock frequency over a large range but a system-clock-independent SA_EN signal is determined by the automatic ATD circuit 501 without operator intervention. The automatic ATD circuit 501 senses when an address (ADDR) signal transitions and sends a signal for the sense amplifier to turn on, allowing for time periods sufficient for ramp-up of current to the sense amplifier and charging of the sense amplifier lines (i.e., the sense amplifier is activated during a valid data out period. The critical frequency, fcr, is defined by particular characteristics within a given memory array circuit as explained in detail, infra. Above the critical frequency, the automatic ATD circuit 501 sends a constant SA_EN signal, allowing sense amplifiers to be constantly activated.
With reference to
A skilled artisan will recognize that the delay circuit 511 may be constructed in various ways. For example, an appropriate delay may be achieved by constructing an even number of inverters is series; the higher a number of inverters placed in series, the greater the delay. The initial time delay is chosen to allow a comparison of the SYS_CLK to an output of the critical period delay element 515, thus allowing any positive edge-triggered flip-flop to be used as a time comparator or phase detector. Therefore, if a signal input to the “D” input of the first DQ flip-flop 517 is “0” when the SYS_CLK goes high, then the system period is not short enough to disable SA_EN. Consequently, the automatic ATD detection circuit 501 remains in the “SLOW MODE” of operation (
Operation of the exemplary automatic ATD circuit 501A is independent of a frequency of the system clock, SYS_CLK input. Instead, the exemplary automatic ATD circuit 501A simply relies on the frequency of the SYS_CLK signal to determine when to produce a sense amplifier enable, SA_EN, signal and a duration of the signal.
Timing diagrams of
The automatic address transition detection circuit 501A compares frequencies of the SYS_CLK and an output of the critical period delay element 515. An SA_EN signal is therefore produced only if a negative edge of the SAE_CR pulse (i.e., an output of the critical period delay element 515) occurs before a subsequent rising-edge of the SYS_CLK. Tcr is thus chosen to be longest period that will, overall, allow the sense amplifier 503 (
Operation of the Automatic ATD Circuit (f1<fcr)
For a SYS_CLK frequency f1, a value of f1 is such that T1>Tcr. In this case, a SYS_CLK signal, shown at “A,” is delayed, “B,” by the delay circuit 511. A single pulse, at “C,” is produced as an output of the rising-edge detection circuit 513. The single pulse at “C” is input to the critical period delay element 515. A resultant pulse from the critical period delay element, at “D,” having a period Tcr, produces a SAE_CR pulse which is one of at least two signal inputs to the OR gate 521. (Details of the critical period delay element 515 are provided with reference to
Operation of the Automatic ATD Circuit (f2>fcr)
For a SYS_CLK frequency f2, a value of f2 is such that its related period T2<Tcr. In this case, a high frequency SYS_CLK signal, at “A,” is again delayed, shown at “B,” by the delay circuit 511. As shown at “C,” a single pulse is produced as an output of the rising-edge detection circuit 513. The single pulse at “C” is input to the critical period delay element 515. The resultant pulse (i.e., the same pulse as describe supra with respect to the SYS_CLK frequency at f1) from the critical period delay element, at “D,” having period Tcr, produces a SAE_CR pulse which is input to the OR gate 521. The SYS_CLK still initiates the pulse train at “D” and also provides an enable signal to the first DQ flip-flop 517 (and the optional DQ flip-flop 519) on a rising-edge 525 of the f2 SYS_CLK signal. Here however, since the resultant pulse from the critical period delay element, at “D,” is high, a “1” is latched into the first DQ flip-flop 517. Consequently an SA_EN signal appears high at an output of the OR gate 521.
Operation of the Rising-Edge Detection Circuit
With reference to
∂min=rc·[ln(2)]
where ∂min neglects minimal effects of digital component propagation delays. Consequently, any signal through the lower inverter leg portion of the rising-edge detection circuit 513A will be further delayed in comparison to the signal traveling through the upper leg due to the lower leg analog components. For example, assuming a rising-edge appears at an input to the rising-edge detection circuit 513A, a “fast 1” is produced at point “A.” After the first inverter 531, a resulting “0” makes its way to the bottom leg, causing the PMOS transistor 535 to act as a pull-up device, creating a “1” as an input to the third inverter 539. However, due to the delay going through the resistive and capacitive analog components, the signal is delayed by ∂min prior to passing through the third inverter 539. At point “B,” a “slow 0” (or, otherwise put, a lingering “one”) is present due to the analog delay. Thus, a signal output from the AND gate 541 produces a narrow pulse only at times when both the top leg and bottom leg each are producing a high signal. A width, w, appropriate as an input to the critical period delay element 515 (
Operation of the Critical Period Delay Element
With reference to
TC=ton+tSA
where ton, tSA
where Vdd is the system supply voltage.
Sense Amplifier Design
With reference to
In brief, the sense amplifier 503A is designed such that an output voltage, Vout, is a function of a transimpedance transfer function, Zf, input current, Iin, a reference current, Iref, and the supply voltage, Vdd, according to the formula
and Vout is a digital output voltage based on analog current inputs where Iin=Icell when reading a programmed memory cell such that
Further design considerations include determining a transimpedance transfer function, Zf, such that
and determining a reference current Iref such that
where Icell≅10 μA for a typical programmed memory cell.
Representative Timing Diagrams
With reference to
of the power required to keep a sense amplifier at full power constantly is utilized by adoption of the present invention. Therefore, the critical time period, Tc, noted above with regard to
Note further that as the SYS_CLK frequency increases to a frequency slightly greater than tSA
In the foregoing specification, the present invention has been described with reference to specific embodiments thereof. It will, however, be evident to a skilled artisan that various modifications and changes can be made thereto without departing from the broader spirit and scope of the invention as set forth in the appended claims. For example, skilled artisans will appreciate that the DQ flip-flops of
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Number | Date | Country | |
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20070133340 A1 | Jun 2007 | US |