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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a DRAM (dynamic random access memory) for
a page memory and a controller used in a printer for a color multivalued
image, a scanner for a color multivalued image, etc.
2. Description of the Related Art
A controller used in a printer for a color multivalued image, a scanner for
a color multivalued image, etc. generally has a DRAM (dynamic random
access memory) for a page memory within this controller. The controller
has a large-sized circuit structure to transfer data at a high speed and
perform complicated control operations according to various kinds of
operating modes.
As mentioned above, various kinds of operating modes are required for the
controller. For example, when an object unit is constructed by a printer,
there is an operating mode in which output processing of data transmitted
to the printer is performed and three primary colors of yellow, magenta
and cyan (YMC) of light are used as color objects and data of these three
primary colors are simultaneously transmitted in a data transfer method.
In contrast to this, when the object unit is constructed by a scanner,
there is another operating mode in which input processing of data
transmitted to the scanner is performed and different three primary colors
of red, green and blue (RGB) of light are used as color objects and data
of these three primary colors are transferred every one color in a data
transfer method.
A memory (DRAM) having a large capacity is required for this controller.
For example, this memory has the following contents.
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paper size A3 A3
image density 400 dpi 400 dpi
gradation 2.sup.2 values
2.sup.8 values
color data 32 MB 128 MB
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In this case, the color data are provided in the case of YMCK.
However, in the general DRAM for a page memory and the general controller
for each of a printer and a scanner, the width of a data bus of the used
DRAM is fixedly set. Therefore, a using method of the DRAM is fixed so
that there is a problem of low extendability that this DRAM cannot be
easily used in an extended way. For example, when a DRAM of 32 MB
(constructed by 16 DRAMs of 15M bits) is mounted, it is possible to select
a first access method for providing size A3 and color gradation of 2.sup.2
values, and a second access method for providing size A5 and color
gradation of 2.sup.8 values. In the first access method, color data are
accessed in a unit of 2 bits every color. In the second access method,
color data are accessed in a unit of 8 bits every color. When the first or
second access method is selected, it is impossible to use the DRAM in
another access method.
Further, since the width of a data bus of the used DRAM is fixedly set, it
is necessary to dispose a complicated bus-converting circuit for
performing a high speed access operation by using a two-bank interleaving
method. In the two-bank interleaving method, the DRAM is physically
divided into two memory sections and data of these two memory sections are
alternately accessed.
As mentioned above, three primary colors (YMC) of light or different three
primary colors (RGB) of light are used. In the case of YMC, white color is
provided when all color data show value "0". In contrast to this, in the
case of RGB, white color is provided when all color data show value "1".
Accordingly, logics of the white data are reverse to each other in the
cases of YMC and RGB. Therefore, processings corresponding to the reverse
logics of the white data such as clear processing of DRAM data, etc. are
performed by using software, thereby increasing a processing time of the
DRAM.
SUMMARY OF THE INVENTION
It is therefore a first object of the present invention to provide a DRAM
and a controller in which a plurality of access methods can be used with
respect to a single DRAM so that extendability of the DRAM is improved and
a high speed access operation is performed.
A second object of the present invention is to provide a DRAM and a
controller in which it is possible to cope with reverse logics of white
data with respect to data of YMC (yellow, magenta, cyan) and RGB (red,
green, blue) by a simplified circuit structure and a short processing
time.
In accordance with a first structure of the present invention, the above
first object can be achieved by a DRAM comprising bus-width selecting
means for selecting the width of a data bus on the basis of a mode signal
for designating the bus width.
In accordance with a second structure of the present invention, the above
second object can be achieved by a DRAM comprising inverting means for
inverting writing data and reading data on the basis of a mode signal for
designating inversion of data.
In accordance with a third structure of the present invention, the above
first object can be also achieved by a controller comprising n-DRAMs each
having bus-width selecting means for selecting the width of a data bus on
the basis of a mode signal for designating the bus width where n is a
positive integer; a first buffer for inputting and outputting data with
respect to the n-DRAMs; a second buffer for inputting and outputting data
with respect to the n-DRAMs; and access switching means for switching
first and second access operations by controlling a setting operation of
the mode signal and selection of an accessed DRAM; the controller being
constructed such that bus-width full data as 2.sup.N data of one DRAM
among the n-DRAMs are accessed through the first buffer in the first
access operation where N is a non-negative integer; and data of m-DRAMs
(m.ltoreq.n) extended with the data bus of each of the DRAMs as one bit
are accessed through the second buffer in the second access operation
where m is a positive integer.
In accordance with a fourth structure of the present invention, the above
second object can be also achieved by a controller comprising DRAMs each
having inverting means for inverting writing data and reading data on the
basis of a mode signal for designating inversion of data; and inverting
control means for writing value "0" to all the DRAMs by positive logic by
controlling the mode signal when a page memory is cleared; the inverting
control means processing color data by the positive logic as it is in the
case of YMC and logically inverting color data in the case of RGB.
In accordance with a fifth structure of the present invention, the above
second object can be also achieved by a controller comprising a DRAM
having first inverting means for inverting writing data and reading data
on the basis of a mode signal for designating inversion of data; a pull-up
resistor for pulling-up output data of the DRAM; second inverting means
for inverting the pulled-up output data of the DRAM; and inverting control
means for inverting and outputting the output data of the DRAM by
controlling the mode signal when no YMC-data are read from the DRAM.
In accordance with a sixth structure of the present invention, the above
first object can be also achieved by a controller having n-DRAMs where n
is a positive integer, the controller comprising n-bus-width selecting
means respectively arranged with respect to the n-DRAMs to select the
width of a data bus; a first buffer for inputting and outputting data with
respect to the n-DRAMs; a second buffer for inputting and outputting data
with respect to the n-DRAMs; and access switching means for switching
first and second access operations by selecting the data bus width through
the bus-width selecting means; the controller being constructed such that
bus-width full data as 2.sup.N data of one DRAM among the n-DRAMs are
accessed through the first buffer in the first access operation where N is
a non-negative integer; and data of m-DRAMs (m.ltoreq.n) extended with the
data bus of each of the DRAMs as one bit are accessed through the second
buffer in the second access operation where m is a positive integer.
In accordance with a seventh structure of the present invention, the above
second object can be also achieved by a controller having DRAMs,
comprising inverting means for inverting writing data and reading data
with respect to each of the DRAMs; and inverting control means for writing
value "0" to all the DRAMs by positive logic by controlling an operation
of the inverting means when a page memory is cleared; the inverting
control means processing color data by the positive logic as it is in the
case of YMC and logically inverting color data in the case of RGB.
In accordance with an eighth structure of the present invention, the above
second object can be also achieved by a controller comprising a DRAM;
first inverting means for inverting writing data and reading data with
respect to the DRAM; a pull-up resistor for pulling-up output data of the
DRAM; second inverting means for inverting the pulled-up output data of
the DRAM; and inverting control means for inverting and outputting the
output data of the DRAM by controlling an operation of the first inverting
means when no YMC-data are read from the DRAM.
In the first structure of the DRAM in the present invention, the bus-width
selecting means switches a data bus width on the basis of a mode signal
inputted from the exterior of the DRAM such that the data bus width is set
to 1 bit, 2 bits, 4 bits, 8 bits, according--to 2.sup.N where N is a
non-negative integer.
In the second structure of the present invention, the inverting means
inverts writing data and reading data based on a mode signal inputted from
the exterior of the DRAM.
In each of the third and sixth structures of the present invention, the
access switching means switches first and second access operations by
controlling a setting operation of the mode signal and selection of an
accessed DRAM. In the first access operation, bus-width full data as
2.sup.N data of one DRAM among the n-DRAMs are accessed through the first
buffer where N is a non-negative integer. In the second access operation,
data of m-DRAMs (m.ltoreq.n) extended with the data bus of each of the
DRAMs as one bit are accessed through the second buffer where m is a
positive integer.
In each of the fourth and seventh structures of the present invention, the
inverting control means writes value "0" to all the DRAMs by positive
logic by controlling the mode signal when a page memory is cleared. The
inverting control means processes color data by the positive logic as it
is in the case of YMC and logically inverts color data in the case of RGB.
In each of the fifth and eighth structures of the present invention, the
inverting control means inverts and outputs output data of the DRAM by
controlling the mode signal when no YMC-data are read from the DRAM.
In these structures, a plurality of access methods can be used with respect
to a single DRAM so that extendability of the DRAM is improved and a high
speed access operation is performed. Further, it is possible to cope with
reverse logics of white data with respect to data of YMC (yellow, magenta,
cyan) and RGB (red, green, blue) by a simplified circuit structure and a
short processing time.
Further objects and advantages of the present invention will be apparent
from the following description of the preferred embodiments of the present
invention as illustrated in the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an explanatory view showing the construction of a DRAM in
accordance with a first embodiment of the present invention;
FIG. 2 is an explanatory view showing the construction of a controller in
the first embodiment of the present invention;
FIG. 3 is an explanatory view showing an example in which the controller
shown in FIG. 2 is used as a printer controller;
FIG. 4 is an explanatory view showing a method for transmitting data to an
LBP engine in the first embodiment;
FIG. 5 is an explanatory view showing the construction of a controller in
accordance with a second embodiment of the present invention;
FIG. 6 is an explanatory view showing a detailed construction of the
controller in the second embodiment of the present invention; and
FIG. 7 is an explanatory view showing a method for transmitting data to an
LBP engine in the second embodiment.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The preferred embodiments of a DRAM and a controller in the present
invention will next be described in detail in an order of first and second
embodiments with reference to the accompanying drawings.
FIG. 1 shows the construction of a DRAM (dynamic random access memory) 100
in accordance with a first embodiment of the present invention. The DRAM
100 is constructed by a memory section 101, a multiplexer (MPX) 102, an
inverting circuit 103 and a non-inverting circuit 104. The memory section
101 stores data transferred through a data bus 105. The multiplexer 102
selects a width of the data bus 105 based on a mode signal for designating
the bus width. The mode signal is shown by a MODE0 signal in the following
description. The inverting circuit 103 inverts writing data and reading
data based on a mode signal for designating inversion of data. This mode
signal is shown by a MODE1 signal in the following description. The
non-inverting circuit 104 stops transmission of non-inverted data at an
inverting time and passes or transmits data at a non-inverting time on the
basis of the MODE1 signal.
The multiplexer 102 selects the data width of the data bus 105 by the MODE0
signal as follows such that data are constructed by one bit or 8 bits.
MODE0=0 DATA=DATA [7:0] (8 bits)
MODE0=1 DATA=DATA [0] (1 bit)
The inverting circuit 103 and the non-inverting circuit 104 are switched by
the MODE1 signal so that writing data and reading data respectively
written and read from the memory section 101 can be selected by inversion
and non-inversion.
MODE1=0 DATA=DATA (non-inversion)
MODE1=1 DATA=!DATA (inversion)
FIG. 2 shows the construction of a controller in the first embodiment. FIG.
2 shows only a constructional portion of the controller relative to the
present invention. The controller in the first embodiment has four DRAMs
100A to 100D, an X-directional R/W buffer 201, a Z-directional R/W buffer
202 and a control section 203. Each of the DRAMs 100A to 100D is equal to
the DRAM 100 shown in FIG. 1. The X-directional R/W buffer 201 is used to
input and output data to each of the DRAMs 100A to 100D. The Z-directional
R/W buffer 202 is used to input and output data to each of the DRAMs 100A
to 100D. The control section 203 controls an operation for setting a mode
signal such as the MODE0 signal and the MODE1 signal and controls
selection of an accessed DRAM. In this embodiment, an X-direction shows a
dot. A Y-direction shows an address and a Z-direction shows a gradation.
An operation of the above controller will next be described. The control
section 203 controls an operation for setting a mode signal such as the
MODE0 signal and the MODE1 signal and controls the selection of an
accessed DRAM. Thus, in a first access operation, bus-width full data
(2.sup.N data) of one DRAM among the four DRAMs are accessed through the
X-directional R/W buffer 201. In a second access operation, data of m
(m.ltoreq.n) DRAMs extended with a data bus of each of the DRAMs as one
bit are accessed through the Z-directional R/W buffer 202. The control
section 203 switches the first and second access operations by controlling
the above mode signal setting operation and the above DRAM selection.
For example, in the first access operation, the width of the data bus of
each of the DRAMs 100A to 100D is set to 4 bits by control of the control
section 203 when MODE0=0. When a DRAM 100B is further designated by a
control signal for designating an accessed DRAM, data of the DRAM 100B
among the DRAMs 100A to 100D are accessed through the X-directional R/W
buffer 201. In this embodiment, the four DRAMs are arranged, but the
present invention is not especially limited to the four DRAMs. Data are
extended in a unit of four dots by extending the DRAMs so that it is
effective to treat a bit map of binary data. It is also possible to make a
bit map suitable for a case in which gradation data are processed as a
packed pixel.
In the second access operation, the width of the data bus of each of the
DRAMs 100A to 100D is set to one bit by control of the control section 203
when MODE0=1. When four DRAMs are further designated by a control signal
for designating an accessed DRAM, data of four DRAMs 100A to 100D as the
four DRAMs are accessed through the Z-directional R/W buffer 202. In this
case, extension of the DRAMs results in extension of gradation in one
frame unit so that it is effective to use the DRAM data as a bit map of
multivalued data.
According to another embodiment of the present invention, a plurality of
buffers can be provided. For example, data in the X and Z directions can
be simultaneously accessed by arranging X-directional R/W buffers 201 such
that the number of X-directional R/W buffers 201 is equal to the number of
DRAMs. Concretely, the width of the data bus of each of the DRAMs 100A to
100D is set to 4 bits by control of the control section 203 when MODE0=0.
Further, four DRAMs are designated by the control signal for designating
an accessed DRAM. Thus, data of four DRAMs 100A to 100D as the designated
four DRAMs are accessed through four X-directional R/W buffers 201. In
this case, it is effective to develop monochromatic font data at a high
speed.
FIG. 3 shows an example in which the controller shown in FIG. 2 is used as
a printer controller. A controller 302 receives code data from a host
computer 301 such as a personal computer, etc. There is a case in which
the code data include image data, graphic data, etc. The controller 302
changes these code data to a bit map image and transmits data of the bit
map image to an LBP engine 303 as an image forming engine.
At this time, when data of both RGB (red, green, blue) and YMC (yellow,
magenta, cyan) are processed in color data processing, clearing operations
of a bit map image memory (i.e., a DRAM) are different from each other in
the RGB and YMC cases. Namely, in the case of RGB, white color is provided
in the clearing operation when all DRAM data show value "1". In contrast
to this, in the case of YMC, white color is provided in the clearing
operation when all DRAM data show value "0". Accordingly, when RGB and YMC
modes are changed in delimitation of pages, a page clearing operation is
again required so that it takes time to perform the page clearing
operation. For example, when the bit map image memory (DRAM) having 128 MB
is mounted, entire processing of the DRAM is greatly influenced by only a
time for performing the page clearing operation. For example, when it
takes a time of 20 nsec with respect to one byte, a time required to
perform the page clearing operation with respect to 128 MB is equal to
about 2.5 sec.
The DRAM 100 shown in FIG. 1 is used in the first embodiment. Accordingly,
when the memory section 101 as a page memory is cleared, value "0" is
written to all DRAMs by positive logic by control of the MODE1 signal
using the control section 203. In the case of YMC, YMC color data are
processed in the positive logic as it is. In contrast to this, the
positive logic is inverted in the case of RGB. Accordingly, it is possible
to cope with a situation in which logics of white data with respect to
YMC-data and RGB-data are reverse to each other, thereby reducing a data
processing time of the DRAM.
There are two methods for transmitting data to the LBP engine 303 shown in
FIG. 3. In a first method, a signal indicative of an effective data region
is transmitted to this effective data region in parallel with these data.
In a second method, only data in the effective data region are transmitted
to the LBP engine 303 and white data are transmitted to the LBP engine 303
except for the effective data region. In the second method, a data control
operation is simplified, but a problem is caused when the logics of white
data with respect to YMC-data and RGB-data are reverse to each other in
the case of colors as mentioned above. Therefore, the controller shown in
FIG. 4 has a pull-up resistor 401 for pulling-up output data of a DRAM 100
and has an inverting circuit 402 for inverting the pulled-up output data.
The output data of the DRAM 100 are inverted and outputted by control of a
MODE1 signal using the control section 203 when no YMC-data are read from
the DRAM 100.
A data bus of the DRAM 100 is normally wired-OR-connected so that this data
bus has high impedance when no data are read from the DRAM 100. Further,
this data bus is pulled up by the pull-up resistor 401 so that this data
bus logically shows value "1".
Value "0" shows white color with respect to all the YMC-data. When no data
are read from the DRAM 100, white color can be provided by inverting the
output data of the DRAM 100 and again inverting these output data by the
inverting circuit 402 until a front stage of video output data transmitted
to the LBP engine 303.
A controller in accordance with a second embodiment of the present
invention will next be described.
As shown in FIG. 5, the controller in the second embodiment has a DRAM 501
as a general DRAM, a multiplexer (MPX) 502, an inverting circuit 503 and a
non-inverting circuit 504. The DRAM 501 is used instead of the DRAM 100 in
the first embodiment. The multiplexer (MPX) 502 is arranged outside the
DRAM 501. The inverting circuit 503 inverts writing data and reading data
based on a mode signal for designating inversion of data. In this
embodiment, the mode signal is set to a MODE1 signal. The non-inverting
circuit 504 stops transmission of non-inverted data at an inverting time
and passes or transmits data at a non-inverting time on the basis of the
MODE1 signal.
FIG. 6 shows a detailed construction of the controller in the second
embodiment. FIG. 6 shows only a constructional portion of the controller
relative to the present invention. The controller in the second embodiment
has four DRAMs 501A to 501D, four multiplexers 502A to 502D, an
X-directional R/W buffer 601, a Z-directional R/W buffer 602 and a control
section 603. The four multiplexers 502A to 502D are respectively arranged
to select a data bus width with respect to the four DRAMs 501A to 501D.
The X-directional R/W buffer 601 is disposed to input and output data with
respect to the DRAMs 501A to 501D. The Z-directional R/W buffer 602 is
also disposed to input and output data with respect to the DRAMs 501A to
501D. The control section 603 controls an operation for setting a mode
signal such as MODE0 and MODE1 signals and controls selection of an
accessed DRAM. In this second embodiment, an X-direction shows a dot. A
Y-direction shows an address and a Z-direction shows a gradation.
An operation of the above controller will next be described. The control
section 603 controls the setting operation of a mode signal such as MODE0
and MODE1 signals and controls the selection of an accessed DRAM. Thus, in
a first access operation, bus-width full data (2.sup.N data) of one DRAM
among the four DRAMs are accessed through the X-directional R/W buffer
601. In a second access operation, data of m (m.ltoreq.n) DRAMs extended
with a data bus of each of the DRAMs as one bit are accessed through the
Z-directional R/W buffer 602. The control section 603 switches the first
and second access operations by controlling the above mode signal setting
operation and the above DRAM selection. The control section 603 transmits
a control signal for designating an accessed DRAM among the DRAMs 501A to
501D. The control section 603 also transmits a MODE0 signal to each of the
multiplexer 502A to 502D. The control section 603 further transmits a
MODE1 signal to each of inverting circuits 503A to 503D and each of
non-inverting circuits 504A to 504D. For example, in a first access
operation, MODE0=0 is transmitted to each of the multiplexers 502A to 502D
and the width of a data bus of each of the DRAMs 501A to 501D is set to 4
bits by control of the control section 603. When the control section 603
transmits a control signal for designating an accessed DRAM to the DRAMs
501A to 501D and a DRAM 501A is designated, data of the DRAM 501A among
the DRAMs 501A to 501D are accessed through the X-directional R/W buffer
601.
In a second access operation, MODE0=1 is transmitted to each of the
multiplexers 502A to 502D and the width of a data bus of each of the DRAMs
501A to 501D is set to one bit by control of the control section 603. When
the control section 603 transmits a control signal for designating an
accessed DRAM to the DRAMs 501A to 501D and four DRAMs are designated,
data of the DRAM 501A to 501D as the designated four DRAMs are accessed
through the Z-directional R/W buffer 602.
According to another embodiment of the present invention, a plurality of
buffers can be provided. For example, when X-directional R/W buffers 601
can be arranged such that the number of X-directional R/W buffers 601 is
equal to the number of DRAMs. In this case, data data in the X and Z
directions can be simultaneously accessed.
In such access operations, effects similar to those in the controller in
the first embodiment can be obtained.
The controller shown in FIG. 7 has a pull-up resistor 701 and an inverting
circuit 702. The pull-up resistor 701 pulls up output data of a
multiplexer 502, i.e., output data of a DRAM 501. The inverting circuit
702 inverts the pulled-up output data. The output data of the DRAM 501 are
inverted and pulled up by control of a MODE1 signal using the control
section 603 when no YMC-data are read from the DRAM 501. Thereafter, these
output data are again inverted by the inverting circuit 702 until a front
stage of video output data transmitted to an LBP engine 703. Thus, similar
to the first embodiment, white color can be provided by YMC-data when no
YMC-data are read from the DRAM 501.
As mentioned above, in accordance with a first structure of the present
invention, a DRAM has bus-width selecting means for selecting the width of
a data bus on the basis of a mode signal for designating the bus width. In
the first structure, a plurality of access methods can be used with
respect to a single DRAM so that extendability of the DRAM can be improved
and data of the DRAM can be accessed at a high speed.
In accordance with a second structure of the present invention, a DRAM has
inverting means for inverting writing data and reading data on the basis
of a mode signal for designating inversion of data. In the second
structure, it is possible to cope with a situation in which logics of
white data with respect to YMC (yellow, magenta, cyan) data and RGB (red,
green, blue) data are reverse to each other by using a simplified
structure and a short processing time.
In accordance with a third structure of the present invention, a controller
has n-DRAMs each having bus-width selecting means for selecting the width
of a data bus on the basis of a mode signal for designating the bus width
where n is a positive integer; a first buffer for inputting and outputting
data with respect to the n-DRAMs; a second buffer for inputting and
outputting data with respect to the n-DRAMs; and access switching means
for switching first and second access operations by controlling a setting
operation of the mode signal and selection of an accessed DRAM; the
controller being constructed such that bus-width full data as 2.sup.N data
of one DRAM among the n-DRAMs are accessed through the first buffer in the
first access operation where N is a non-negative integer; and data of
m-DRAMs (m.ltoreq.n) extended with the data bus of each of the DRAMs as
one bit are accessed through the second buffer in the second access
operation where m is a positive integer. In the third structure, a
plurality of access methods can be used with respect to a single DRAM so
that extendability of the DRAM can be improved and data of the DRAM can be
accessed at a high speed.
In accordance with a fourth structure of the present invention, a
controller has DRAMs each having inverting means for inverting writing
data and reading data on the basis of a mode signal for designating
inversion of data; and inverting control means for writing value "0" to
all the DRAMs by positive logic by controlling the mode signal when a page
memory is cleared; the inverting control means processing color data by
the positive logic as it is in the case of YMC and logically inverting
color data in the case of RGB. In the fourth structure, it is possible to
cope with a situation in which logics of white data with respect to YMC
(yellow, magenta, cyan) data and RGB (red, green, blue) data are reverse
to each other by using a simplified structure and a short processing time.
In accordance with a fifth structure of the present invention, a controller
has a DRAM having first inverting means for inverting writing data and
reading data on the basis of a mode signal for designating inversion of
data; a pull-up resistor for pulling-up output data of the DRAM; second
inverting means for inverting the pulled-up output data of the DRAM; and
inverting control means for inverting and outputting the output data of
the DRAM by controlling the mode signal when no YMC-data are read from the
DRAM. In the fifth structure, it is possible to cope with a situation in
which logics of white data with respect to YMC (yellow, magenta, cyan)
data and RGB (red, green, blue) data are reverse to each other by using a
simplified structure and a short processing time.
In accordance with a sixth structure of the present invention, a controller
having n-DRAMs where n is a positive integer comprises n-bus-width
selecting means respectively arranged with respect to the n-DRAMs to
select the width of a data bus; a first buffer for inputting and
outputting data with respect to the n-DRAMs; a second buffer for inputting
and outputting data with respect to the n-DRAMs; and access switching
means for switching first and second access operations by selecting the
data bus width through the bus-width selecting means; the controller being
constructed such that bus-width full data as 2.sup.N data of one DRAM
among the n-DRAMs are accessed through the first buffer in the first
access operation where N is a non-negative integer; and data of m-DRAMs
(m.ltoreq.n) extended with the data bus of each of the DRAMs as one bit
are accessed through the second buffer in the second access operation
where m is a positive integer. In the sixth structure, a plurality of
access methods can be used with respect to a single DRAM so that
extendability of the DRAM can be improved and data of the DRAM can be
accessed at a high speed.
In accordance with a seventh structure of the present invention, a
controller having DRAMs comprises inverting means for inverting writing
data and reading data with respect to each of the DRAMs; and inverting
control means for writing value "0" to all the DRAMs by positive logic by
controlling an operation of the inverting means when a page memory is
cleared; the inverting control means processing color data by the positive
logic as it is in the case of YMC and logically inverting color data in
the case of RGB. In the seventh structure, it is possible to cope with a
situation in which logics of white data with respect to YMC (yellow,
magenta, cyan) data and RGB (red, green, blue) data are reverse to each
other by using a simplified structure and a short processing time.
In accordance with an eighth structure of the present invention, a
controller has a DRAM; first inverting means for inverting writing data
and reading data with respect to the DRAM; a pull-up resistor for
pulling-up output data of the DRAM; second inverting means for inverting
the pulled-up output data of the DRAM; and inverting control means for
inverting and outputting the output data of the DRAM by controlling an
operation of the first inverting means when no YMC-data are read from the
DRAM. In the eighth structure, it is possible to cope with a situation in
which logics of white data with respect to YMC (yellow, magenta, cyan)
data and RGB (red, green, blue) data are reverse to each other by using a
simplified structure and a short processing time.
Many widely different embodiments of the present invention may be
constructed without departing from the spirit and scope of the present
invention. It should be understood that the present invention is not
limited to the specific embodiments described in the specification, except
as defined in the appended claims.
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