`Abe
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`US0055900.82A
`[11] Patent Number:
`5,590,082
`[45]. Date of Patent:
`Dec. 31, 1996
`
`[54] CIRCUIT AND METHOD FOR RETAINING
`DRAM CONTENT
`
`[75] Inventor: Seiichi Abe, Odawara, Japan
`[73] Assignee: Hitachi, Ltd., Tokyo, Japan
`
`Patent Abstracts of Japan, Publication No. JP7085660, Mar.
`1995, vol. 950, No. 3.
`Patent Abstracts of Japan, Publication No. JP4111295, Apr.
`13, 1992, vol. 16, No. 361.
`
`Primary Examiner—David C. Nelms
`Assistant Examiner—Vu A. Le
`Attorney, Agent, or Firm—Fay, Sharpe, Beall, Fagan, Min
`nich & McKee
`
`Appl. No.: 467,277
`[21]
`Filed:
`Jun. 6, 1995
`[22]
`Foreign Application Priority Data
`[30]
`Jun. 7, 1994
`[JP]
`Japan .................................... 6-125377
`[51] Int. Cl* … G11C 7/00
`ABSTRACT
`[57]
`[52] U.S. Cl. ............
`... 36.5/222; 36.5/226; 36.5/229
`For a DRAM provided with a self-refreshing function,
`[58] Field of Search ..................................... 36.5/229, 228,
`self-refresh starting operations and execution of the self
`365/226, 222
`refresh mode are performed when the power supply voltage
`is cut off thereby achieving battery backup of the DRAM.
`This is achieved by detecting when the power supply voltage
`is at the lowest voltage at which normal data transfer can be
`performed. The operations carried out by the DRAM control
`circuit relate to stopping transfer of the following data after
`completing any transfer that was in the course of execution,
`executing refreshing, and establishing the self-refresh mode.
`All except for the last function are preceding processes for
`self-refreshing. Then, when the voltage of the power supply
`is determined to be in the proximity of the lowest voltage at
`which the DRAM drive circuit can perform normally, the
`drive circuit is disabled and the RAS and CAS signals of the
`drive circuit go low by means of pull-down resistors so that
`the self-refresh mode is established.
`
`[56]
`
`References Cited
`U.S. PATENT DOCUMENTS
`4,631,701 12/1986 Kappeler et al. ....................... 365/.222
`4,962,485 10/1990 Kato et al. .......
`... 36.5/229
`5,204,840 4/1993 Mazur ......
`... 36.5/229
`5,245,582 9/1993 Kimura ................................... 365/.229
`FOREIGN PATENT DOCUMENTS
`53-105935 9/1978 Japan.
`60-72012 4/1985 Japan .
`62-23349 2/1987 Japan .
`4-178553 6/1992 Japan .
`4-289582 10/1992 Japan .
`OTHER PUBLICATIONS
`Patent Abstracts of Japan, Publication No. JP6251581, Sep.
`9, 1994, vol. 18, No. 654.
`Patent Abstracts of Japna, Publication No. JP7045066, Feb.
`14, 1995, vol. 950, No. 2.
`
`19 Claims, 3 Drawing Sheets
`
`* -------------------------,
`
`
`
`
`
`
`
`POWER
`SUPPLY
`
`POWER I DHAM
`
`SUPPLY
`MONITOR
`
`CONTROL
`CHRCljiT
`
`*------------------
`
`POWER
`SUPPLY
`MONITOR
`
`
`
`
`
`At JXiLIARY
`POWER
`SUPPLY
`
`MiAiN
`CIRCUIT
`
`Samsung Ex. 1005
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`U.S. Patent
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`Dec. 31, 1996
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`Sheet 1 of 3
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`5,590,082
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`17
`
`FIG. 1
`
`Dº 16
`_º
`DS
`
`
`
`12
`
`F-------------------
`
`MAIN
`POWER
`SUPPLY
`
`
`
`AUXILIARY
`POWER
`SUPPLY
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`
`
`
`
`
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`
`
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`
`
`
`
`
`SUPPLY
`MONITOR
`
`DRAM
`CONTROL
`CIFCUIT
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`POWER
`SUPPLY
`MONITOR
`
`
`
`MAN
`CIRCUIT
`
`64
`
`MEMORY MODULE
`
`– 6
`
`
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`MAIN POWER SUPPLY 13
`
`vil
`Vt2
`
`SIGNAL 9
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`SIGNAL 1 O
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`Sheet 2 of 3
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`5,590,082
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`F------------------- -n
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`:
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`
`FIG. 3
`
`12
`
`POWER
`SUPPLY
`MONITOR
`
`DRAM
`CONTROL
`CIRCUIT
`
`POWER
`SUPPLY
`MONITOR
`
`
`
`17
`
`DS 16
`
`bi-
`DS
`D-
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`
`
`MAIN
`POWER
`SUPPLY
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`
`
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`
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`AUXILIARY
`POWER
`SUPPLY
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`7
`
`MAIN
`CIRCUIT
`
`FIG. 4
`
`
`
`
`
`STOP DATA TRANSFER
`
`EXECUTE REFRESHING
`
`ESTABLISH SELF-FEFRESH
`MODE
`
`40i
`
`402
`
`403
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`US. Patent
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`Dec. 31, 1996
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`Sheet 3 of 3
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`5,590,082
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`Samsung EX. 1005
`Page 4 0f 9
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`Samsung Ex. 1005
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`
`
`1
`CIRCUIT AND METHOD FOR RETAINING
`DRAM CONTENT
`
`5,590,082
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`FIELD OF THE INVENTION
`The present invention relates to a memory control circuit
`having a DRAM and, more particularly, to a control circuit
`retaining the content stored in a DRAM having a self
`refreshing function with the use of an auxiliary power
`supply when the main power supply is cut off.
`
`BACKGROUND OF THE INVENTION
`As a control circuit for retaining the content stored in a
`CMOS memory or the like with the use of an auxiliary
`power supply, there is known a memory control circuit
`utilizing an output signal of a power supply monitor to
`protect the memory by means of a circuit causing the chip
`select signal of an SRAM to go high to thereby disable the
`memory when the power supply is cut off. As a known
`example of the described type, there is for example one
`disclosed in the gazette of Japanese Utility Model Laid-open
`No. Sho 62–23349.
`
`10
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`20
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`
`SUMMARY OF THE INVENTION
`In the above described prior art, the content stored in an
`SRAM is retained while consuming a small amount of
`power and, with such an SRAM, the disabling control can be
`achieved in a short period of time of tens of ns when the
`power supply voltage is lowered. However, the prior art
`method is directed to an SRAM and no disclosure is pro
`vided about how to retain the content stored in a DRAM
`with an auxiliary power supply when the power supply
`voltage is lowered by having the DRAM provided with a
`self-refreshing function or a method to carry out self-refresh
`starting operations taking several Hs in a stabilized manner
`to retain the content of storage. Further, in the case where the
`content stored in a DRAM provided with a self-refreshing
`function is retained with the use of an auxiliary power
`supply, the RAS signal and the CAS signal as the outputs of
`40
`the DRAM drive circuit must be held low while the stored
`content is retained with the auxiliary power supply. How
`ever, since an SRAM is disabled by a high-level signal
`according to the prior art, there is not known any method for
`bringing the RAS signal and the CAS signal of a DRAM
`45
`drive circuit to low level with a small amount or number of
`circuit components.
`An object of the present invention is to solve the above
`mentioned problems, i.e., to provide a memory control
`circuit capable of reliably carrying out self-refresh starting
`50
`operations to establish a self-refresh mode for a DRAM
`when the power supply voltage is lowered and, further, to
`easily realize a self-refresh mode consuming small power at
`the time when the power supply voltage is lowered with the
`use of a simple circuit configuration formed of a small
`number of circuit components.
`In order to achieve the above mentioned object, the
`present invention provides a memory control circuit having
`a DRAM, a drive circuit for driving the DRAM, a DRAM
`control circuit for controlling operation of the DRAM
`60
`through the drive circuit, a power supply, a first detection
`circuit (first power supply monitor) for generating a first
`detection signal when the power supply voltage is lowered
`to a voltage higher than the lowest power supply voltage at
`which data transfer for the DRAM can be performed nor
`mally, and a second detection circuit (second power supply
`monitor) for generating a second detection signal when the
`
`55
`
`65
`
`2
`power supply voltage is lowered to a voltage equal to or
`slightly higher than the lowest power supply voltage at
`which the DRAM control circuit can operate normally.
`When the first detection signal is detected, the DRAM
`control circuit starts self-refreshing and completes the rela
`tive preceding processes and then, when the second detec
`tion signal is detected, the drive circuit establishes a self
`refresh mode for the DRAM.
`According to the invention, when the power supply volt
`age is lowered to a voltage slightly higher than the lowest
`power supply voltage at which data transfer for the DRAM
`can be performed, the DRAM control circuit (adapted to be
`operative at a voltage lower than the power supply voltage
`at which data transfer can be performed normally) is caused
`to start the self-refreshing function by a first detection signal.
`As a result, necessary preceding processes (to completely
`finish the data transfer being executed and stop the following
`transfer as well as cause the refreshing function to be
`executed and the self-refresh mode to be established) can be
`performed well by the DRAM control circuit. Then, when
`the power supply voltage is further lowered and tends to
`drop below the voltage at which the DRAM control circuit
`can operate normally, the outputs (RAS signal and CAS
`signal) of the drive circuit are brought to a low level by a
`second detection signal. Thereby, the RAS signal and the
`CAS signal are held low while the content stored in the
`DRAM is retained by the auxiliary power supply and thus
`the self-refresh mode is maintained.
`Since the drive circuit is made up of a general drive circuit
`having a normal output impedance that is high and having
`extra pull-down resistors, a logic circuit is not required and
`the number of component parts can be reduced.
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`FIG. 1 is a block diagram of a first embodiment of the
`memory control circuit of the invention.
`FIG. 2 is a timing chart when the main power supply is cut
`off in the first embodiment.
`FIG. 3 is a block diagram of a second embodiment of the
`memory control circuit of the invention.
`FIG. 4 is a sequence diagram of self-refresh starting
`operations in the invention.
`FIG. 5 is a timing chart similar to FIG. 2 showing the
`correspondence between various voltage levels and the
`timing of the establishing of the self-refresh mode of a
`DRAM.
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENTS
`
`An embodiment of the invention will be described below
`in detail with reference to the accompanying drawings.
`FIG. 1 is a block diagram of a memory control circuit of
`a first embodiment of the invention. Referring to the figure,
`the system comprises a main power supply 1 such as a
`commercial power supply, main battery power supply or the
`like, an auxiliary power supply 2 such as a battery or the like,
`a main circuit 7, a DRAM control circuit 4, a memory
`module 6, a first power supply monitor 3 and a second power
`supply monitor 5. Memory module 6 is made up of a drive
`circuit 61, a DRAM 62, and pull-down resistors 63 and 64.
`A power supply line 12 supplies power to the memory
`module 6 and a power supply line 13 supplies power to the
`main circuit 7 (CPU). A data bus 14 is connected between
`main circuit 7 and DRAM 62. Output lines of the drive
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`circuit 61 are denoted by 65,66, and 67, of which 65 denotes
`a RAS signal, 66 denotes a CAS signal, and 67 other DRAM
`control signals such as an address signal, a write enable
`signal, and an output enable signal.
`The main power supply 1 supplies power required for
`system operation. The auxiliary power supply 2 supplies
`power for retaining the memory content of the DRAM in the
`case of the main power supply being cut off. Diodes 17 and
`16 are used for switching power from the main power supply
`1 and the auxiliary power supply 2 to be supplied to the
`power supply line 12 for the memory module 6. In normal
`operation, the voltage of the main power supply 1 is higher
`than the auxiliary power supply 2 and power is supplied
`from the main power supply. When the main power supply
`is cut off, the voltage of the main power supply 1 becomes
`lower than the auxiliary power supply 2 and power is
`supplied from the auxiliary power supply. A diode 15 keeps
`the power supply line 13 for the main circuit and the power
`supply line 12 substantially at the same potential.
`The first power supply monitor 3 sets its detection voltage
`at a voltage Vt1 which is slightly higher than the minimum
`voltage at which the main circuit 7 can normally perform
`data transfer for the DRAM. The second power supply
`monitor 5 sets its detection voltage at a voltage Vt2 which
`is slightly higher than the minimum voltage at which the
`DRAM control circuit 4 can normally operate. The reason
`why the voltages Vt1 and Vtz are set slightly higher than the
`respective minimum voltages (lowest voltages) is for ensur
`ing, as described later, that processes to be performed
`preceding the establishment of the self-refresh mode are
`performed well by the DRAM control circuit 4.
`FIG. 2 is a diagram showing the timing of each signal
`when the main power supply is cut off or switched over in
`the embodiment of FIG. 1. At this time, the voltage on the
`power supply line 13 for the main circuit changes as shown
`in FIG. 2. Further, when the main power supply is switched
`over, output signals 9 and 10 of the power supply monitors
`3 and 5 change as shown in FIG. 2 at the timing corre
`sponding to the changes in voltage on the power supply line
`13. The DRAM control circuit 4, when the output signal 9
`of the first power supply monitor 3 is at high level, performs
`usual DRAM refreshing control and further controls the
`DRAM control signal 11 in response to the memory access
`control signal 8 from the main circuit 7.
`When the output signal 9 is at low level, self-refresh
`starting operations are performed as shown in FIG. 4, i.e.,
`the following data transfer is stopped after a data transfer
`being executed has been completed (step 401). Then,
`refreshing is executed (step 402), and the self-refresh mode
`is established (step 403). The refreshing operation in step
`402 is an operation uniquely required of a DRAM and a
`necessary process to be performed prior to the establishment
`of the self-refresh mode in step 403. The self-refresh starting
`operations are commenced at the timing of the fall of the
`signal 9 in FIG. 2. Since the self-refresh starting operations
`are completed at the timing of the rise of the signal 10 in
`FIG. 2, the output signal 10 of the second power supply
`monitor 5 is allowed to function as a self-refresh start
`execution signal.
`Drive circuit 61 is performs the following operations
`according to the state of the signal 10. Namely, when the
`output signal 10 is at a high level, the drive circuit 61 has its
`output circuit exhibiting a high impedance (on the order of
`MQ) irrespective of the DRAM control signal 11. On the
`other hand, when the output signal 10 is at a low level, the
`drive circuit 61 outputs a signal at the same level as the
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`DRAM control signal 11 and drives the DRAM with it.
`Since the output signal lines for the RAS signal 65 and the
`CAS signal 66 are loaded with pull-down resistors 63 and 64
`(load resistors whose resistance values are lower than the
`output of the high impedance value), the RAS signal and the
`CAS signal are held low when the output signal 10 is at high
`level. When both the RAS signal and the CAS are low, it
`means that the self-refresh mode is set up and the self
`refresh mode of operation is maintained while both the
`signals are held low.
`As apparent from the above, the signal 9 is the signal used
`for stopping the data transfer (step 401) and executing the
`refreshing (step 402) as processes to be performed prior to
`establishment of the self-refresh mode when the main power
`supply is cut off. Further, signal 10 is the one used for
`establishing and maintaining the self-refresh mode. Since, at
`this time, the DRAM control circuit 4 is adapted to be
`operative at a power supply voltage lower than its normal
`operating voltage, it can operate for some period of time
`during which the voltage on the line 13 gradually lowers as
`the result of the main power supply being cut off and hence
`it is ensured that the preceding processes (step 401 and step
`402) are surely performed.
`In one case, wherein the main power supply 1 is a
`conventional power supply (110 volts), the pull-down resis
`tors 63 and 64 are set to be around 10 Q or, when they cannot
`be set to such a low value depending on the capability of the
`drive circuit, they can be set to 100 Q or above. In another
`case, the main power supply 1 can be a main battery power
`source for a portable device, for example, in which case the
`pull-down resistors 63 and 64 are set to be around 1k Q.
`Further, since the drive circuit 61 has an impedance higher
`than that of an ordinary driver in operation, it is vulnerable
`to crosstalk noise. In order to keep it from being effected by
`the crosstalk noise, other signal lines having changes when
`the main power supply is cut off or turned on should not be
`wired in parallel with (within 0.1 mm) the DRAM state
`control signals.
`In the structure of FIG. 1, in order that the DRAM control
`circuit 4 operates at a power supply voltage lower than the
`set voltage Vt1 of the power supply monitor 3, it has a
`CMOS design or the like such that no problem with the
`timing margin arises (such that there is sufficient timing
`margin even when the lower voltage is set to Vt2). Thus the
`self-refresh starting operations are performed reliably and
`steadily.
`According to the embodiment, since the DRAM control
`circuit 4 is structured to be operative at voltage down to the
`voltage Vt2 lower than the voltage at which data transfer is
`normally performed when the main power supply is cut off,
`it is ensured that the self-refresh starting operations (FIG. 4)
`are performed without fail in response to the detection signal
`9 (the self-refresh starting signal) output by the first power
`supply monitor, i.e., the transfer of the following data is
`stopped after the data being transferred has been normally
`transferred, the refreshing is executed, and the self-refresh
`mode is established. Thus, when the main power supply is
`cutoff, power of the backup auxiliary power supply 2 is only
`required to be supplied to the DRAM circuit of (memory
`module 6) made up of the DRAM 62 and the drive circuit 61.
`The backup auxiliary power supply 2 is not required to be
`supplied to other circuits such as the DRAM control circuit
`4 (power is required to be supplied also to the DRAM
`control circuit 4 in the ordinary refresh mode). Accordingly,
`data can be held and stored for a long time with low
`consumption of power supplied by the auxiliary power
`supply 2. When the power supply voltage is further lowered
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`below the lowest voltage at which the DRAM control circuit
`4 can normally operate (around Vt2), the self-refresh mode
`is established with the RAS signal 65 and the CAS signal 66
`brought to low levels by the detection signal 10 of the
`second power supply monitor 5.
`FIG. 5 shows the correspondence between the setting of
`the threshold voltages Vt1 and Vt2 and the voltages V1–V5,
`explained as follows. First, Vcc is the operating voltage
`supplied by the main power supply 1, which is 5.0 V
`(nominal) and which fluctuates by +3%, or +0.15 V from
`10
`4.85 V to 5.15 V. V1 is the lowest voltage normally supplied
`by the main power supply, which is 4.85 V. V2 is a minimum
`voltage value that relates to the data through rate and data
`transfer rate of the DRAM, because at V2, the data transfer
`will still successfully terminate if a data transfer operation is
`occurring when the supply voltage Vcc is cut off. V3 is a
`voltage value that is the lowest value at which the CPU can
`still function, so the data transfer must be successfully
`completed before the voltage drop along the curve shown in
`the figure reaches V3. If the data through rate is Tsr (ms/V)
`and the data transfer rate or time to complete one transfer
`cycle is Tir (s), then:
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`In the present embodiment, the drive circuit operating as
`described above can be realized by a simple circuit formed
`of only a combination of drive circuit 61 and pull-down
`resistors 63 and 64. Characteristic of the drive circuit 61 of
`the present invention is that in addition to performing the
`usual functions, the drive circuit is also provided with an
`enable pin 68, unlike conventional drive circuits. In response
`to the active low enable pin 68 receiving a high output signal
`10 from power supply monitor 5, the output impedance of
`the drive circuit becomes high enabling the RAS and CAS
`to be pulled low by pull-down resistors 63 and 64.
`FIG. 3 is a block diagram of a memory control circuit of
`a second embodiment of the invention. Since certain of the
`components of the circuit of FIG. 3 are similar to those
`shown in FIG. 1 and since they are denoted by like reference
`numerals, their description will be omitted.
`In the second embodiment, there is provided a power
`supply line 18 for the DRAM control circuit 4 separately
`from the power supply line 13 for the main circuit 7. Power
`supply line 18 is connected, as shown to a diode 19 and a
`capacitor 20. With this structure, the voltage drop at the time
`of the main power supply being cut off is delayed by the
`capacitor 20 and the self-refresh starting operations are
`thereby performed in a stabilized manner.
`Although it is designed in the first and second embodi
`ments that the RAS signal and CAS signals are brought to
`a low level by a combination of the drive circuit 61 whose
`output impedance becomes high when the signal 10 is output
`thereto and the pull-down resistors 63 and 64, or a logic
`circuit may, instead, be provided in the drive circuit 61
`bringing the RAS signal 65 and the CAS signal 66 to low
`level when the signal 10 is output. Further, while the
`detection signal 10 of the second power supply monitor 5 is
`used for maintaining the self-refresh mode in the above
`embodiments, a signal equivalent to the signal 10 may,
`instead, be generated from the output signal 9 of the first
`power supply monitor 3. For example, the signal 10 may be
`obtained by delaying the signal 9 for a predetermined period
`of time t1 (the period of time necessary for executing steps
`401 and 402).
`Further, the invention may be carried out in the following
`modes of operation.
`(1) In the memory control circuit, there is provided a
`DRAM control circuit performing its normal operation at a
`power supply voltage lower than the set voltage of the first
`power supply monitor.
`(2) In the memory control circuit, there is provided a
`power supply voltage holding circuit holding the power
`supply voltage for the DRAM control circuit at its normal
`operating voltage until the DRAM control circuit establishes
`the self-refresh mode when the main power supply voltage
`is lowered below the set voltage of the first power supply
`monitor.
`(3) In the memory control circuit, there is provided a
`DRAM control signal drive circuit whose output impedance
`is set to a high impedance value by a setting signal for
`establishing the self-refresh mode and there are provided
`pull-down resistors for the output circuit of DRAM state
`control signals (RAS signal and CAS signal) on the output
`side of the DRAM control signal drive circuit.
`(4) In the memory control circuit, there is provided a logic
`circuit within the DRAM control signal drive circuit, the
`logic circuit bringing the DRAM state control signals (RAS
`signal and CAS signal) to low level with a setting signal for
`establishing the self-refresh mode.
`(5) In the memory control circuit described in the mode of
`operation (3) above, there are provided a memory module
`
`V4 is a voltage value at the lowest voltage above which the
`Self-refreshing pretreatment function unique to DRAMs can
`be completed and the self-refreshing mode can be executed
`(Pretreatment & Start-treatment B, which is completed in
`elapsed time of Tb). Accordingly, V4 is related to Vtl, Ttr,
`Tsr and Tb as follows:
`
`V5 is a voltage value at the lowest voltage above which the
`DRAM control circuit 4 still executes correctly. In view of
`the above, the threshold voltages Vt1 and Vt2 are set in
`consideration of the following:
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`Reference is made to a specific example for purposes of
`illustration, but not for the purpose of limiting the scope of
`the embodiments of the invention. Suppose that V1 is 4.85
`V, Tsr is 1.0 (ms/V), Tir is 10 ps and V3 is 4.5 V, then:
`V2=4.51 V and Vtl ranges between 4.51 V and 4.85 V.
`Further, if Vtlis selected to be 4.60V, Tsr is 1.00 (ms/V) and
`Tb is 50 ps, then V4 is 4.54 V. So, according a referred
`embodiment, if V5=4.5V, then Vt2 is selected to be between
`4.5V and 4.54 V, or preferably 4.5 V. Although Vt.1 and Vt2
`are selected to be within the above stated ranges, the
`difference between the respective voltage values must be at
`least 1.0 mV (nanovolt). Further, according to another
`example, Vcc may be 3.3 V (nominal), not 5.0 V as
`discussed above.
`For a DRAM designed by an ASIC (application specific
`IC) technique, the CPU can execute correctly above 2.7 V,
`which is lower than the minimum CPU operating voltage
`V3, assumed above. Further, for a well designed circuit, the
`DRAM control circuit can operate at a voltage as low as
`V5=1.3 V. Still further, the TSr can be set to 100 (ms/V) or
`other values in consideration of the condenser and resistor
`element determined time constants, and Ttr may also be of
`a different value, such as 1 ms by executing a packet transfer
`mode, and it may even be several hundred ns, for example,
`when the circuit does not adopt a high speed page mode.
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`having the DRAM control signal drive circuit combined
`with pull-down resistors and a DRAM incorporating the
`self-refreshing function integrally mounted thereon.
`(6) In the memory module described in the mode opera
`tion (5) above, the resistance values of the pull-down
`resistors provided for the output circuit of the DRAM state
`control signals are set to be higher than 100 Q and the level
`of the output circuit is held low while the main power supply
`is cut off, and the wiring pattern is designed such that other
`signal lines whose signal levels change when the main
`power supply is cut off or the main power supply is turned
`on are not wired in parallel with (within 0.1 mm) of the
`output circuit of the DRAM state control signals.
`(7) There are provided a main power supply and an
`auxiliary power supply, of which the main power supply is
`supplied to the DRAM and the drive circuit and also to other
`circuits including the DRAM control circuit and the auxil
`iary power supply is supplied only to the DRAM and the
`drive circuit as backup power supply at the time when the
`main power supply is cut off or lowered.
`According to the present invention, as described above in
`detail, a first detection signal is detected while the power
`supply voltage is lowered but yet while data transfer is being
`performed normally and the DRAM control circuit is oper
`ating normally, so that it is thereby made sure that the
`DRAM control circuit is caused to surely perform preceding
`processes well (such as to have data transfer being executed
`transmitted completely, to stop the following data transfer, to
`execute refreshing, and to establish a self mode), and when
`the power supply voltage tends to fall, or has fallen, below
`the voltage at which the DRAM operates normally, a second
`detection signal is detected and the drive circuit is caused by
`the detection signal to set up and maintain the self-refresh
`mode for the DRAM. Accordingly, the complicated self
`refresh starting operations of the DRAM including the
`aforesaid preceding processes can be carried out surely and
`stably. Further, by the present invention, the drive circuit
`outputs (RAS signal and CAS signal) can be brought to low
`level when the main power supply is cut off with the use of
`a small number of component parts.
`I claim:
`1. A memory control circuit comprising a DRAM, a drive
`circuit for driving said DRAM, a DRAM control circuit for
`controlling operation of said DRAM through said drive
`circuit, a power supply connected to said DRAM, said
`DRAM control circuit and said drive circuit, a first detection
`circuit for generating a first detection signal that is output to
`said DRAM control circuit when the power supply voltage
`is lowered to a first predetermined voltage, and a second
`detection circuit for generating a second detection signal that
`is output to said drive circuit when the power supply voltage
`is lowered to a second predetermined voltage lower than
`said first predetermined voltage, wherein said DRAM con
`trol circuit, when said first detection signal is received, starts
`self-refreshing and, when said second detection signal is
`received, said drive circuit establishes a self-refresh mode
`for said DRAM.
`2. A memory control circuit according to claim 1, further
`including an auxiliary power supply that is connected to said
`drive circuit and said DRAM for providing power, thereto
`after said power supply is cut off in order to provide
`sufficient power for maintaining said established self-refresh
`mode.
`3. A memory control circuit according to claim 2, wherein
`said power supply is connected to said DRAM and said drive
`circuit through a power line having a first diode and wherein
`said auxilliary power supply is connected to said power line
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`between said first diode and said DRAM and said drive
`circuit through a second diode for switching between sup
`plying power from said power supply to supplying power
`from said auxilliary power supply over said power line.
`4. A memory control circuit according to claim 1, wherein
`said drive circuit has an output circuit having a first imped
`ance value when driving said DRAM that includes RAS and
`CAS output signals for controlling said DRAM, said RAS
`and CAS signals being connected to a pull down circuit,
`wherein when said second detection signal is received, said
`output circuit is switched from said first impedance value to
`a second impedance value higher than said first impedance
`value for pulling low said RAS and CAS signals with said
`pull down circuit to set the self refresh mode.
`5. A memory control circuit according to claim 4, wherein
`said drive circuit includes an enable pin that receives said
`second detection signal for controlling the switching of the
`output circuit between said first and second impedance
`values.
`6. A memory control circuit according to claim 2, further
`comprising a power line connecting said DRAM control
`circuit through a power line to said power supply, and a
`capacitor connected to said power line in parallel with said
`power Supply.
`7. A memory control circuit according to claim 6, wherein
`said first detection signal is connected to said power supply
`through a first diode, said power line is connected to said
`main power supply through a second diode, said DRAM and
`said drive circuit are connected to said to said power supply
`by another power line through a third diode and said
`auxiliary power supply is connected to said another power
`line between said third diode and Said DRAM and said drive
`circuit through a fourth diode.
`8. A memory control circuit, comprising: a main circuit,
`a DRAM, a drive circuit for driving said DRAM, a DRAM
`control circuit for controlling operation of said DRAM
`through said drive circuit, a first power supply supplying a
`power supply voltage to said main circuit, said DRAM, said
`DRAM control circuit and said drive circuit, a first detection
`circuit connected to said first power supply for monitoring
`the supply voltage and for generating a first detection signal
`that is output to said DRAM control circuit when the power
`supply voltage decreases below a first predetermined volt
`age, and a second detection circuit for generating a second
`detection signal that is output to said drive circuit when the
`power supply voltage is lowered to a second predetermined
`voltage lower than said first predetermined voltage, wherein
`said DRAM control circuit, when said first detection signal
`is received, stops data transfer and starts self-refreshing of
`said DRAM after completion of data transfer, means respon
`sive to said second detection signal being received by said
`drive circuit for setting a self-refresh mode for said DRAM,
`and a second auxilliary power supply that is connected to
`said drive circuit and said DRAM for providing power
`thereto after said power supply voltage is cut off in order to
`provide sufficient power for maintaining said self-refresh
`mode.
`9