Abstract: A digital image signal processing apparatus includes a digital signal processing unit, a plurality of display units, and a display driving unit. The digital signal processing unit provides a plurality of pieces of image data that respectively form a plurality of images. The plurality of display units display images corresponding respectively to the plurality of pieces of the image data. The display driving unit includes a display memory that records the plurality of pieces of image data, a recording address unit that controls the plurality of pieces of image data to be recorded in the display memory, and a plurality of display address units that respectively read the recorded pieces of image data and provide the recorded pieces of image data respectively to the display units. Accordingly, a photographer may directly display a desired image to a photographed person as a high-quality filtered image without a separate selection operation.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of row and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: A capacitor includes a lower electrode structure which includes a sidewall, an upper surface and a rounded surface between the sidewall and the upper surface. The capacitor further includes a ferroelectric layer pattern disposed on the lower electrode structure, and an upper electrode structure is provided on the ferroelectric layer pattern. The ferroelectric layer pattern is formed on the upper surface, the sidewall and the rounded surface of the lower electrode structure. The effective area between the lower electrode structure and the ferroelectric layer pattern may be increased, and the crystalline structure of the ferroelectric layer pattern may be improved. Accordingly, the capacitor may provide enhanced capacitance and electrical characteristics.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of row and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of rows and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of rows and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: Disclosed is a triple metal line 1T/1C ferroelectric memory device and a method to make the same. A ferroelectric capacitor is connected to the transistor through a buried contact plug. An oxidation barrier layer lies between the contact plug and the lower electrode of the capacitor. A diffusion barrier layer covers the ferroelectric capacitor to prevent diffusion of material into or out of capacitor. As a result of forming the oxidation barrier layer, the contact plug is not exposed to the ambient oxygen atmosphere thereby providing a reliable ohmic contact between the contact plug and the lower electrode. Also, the memory device provides a triple interconnection structure made of metal, which improves device operation characteristics.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of rows and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of rows and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of rows and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: A method of manufacturing a semiconductor device including a ferroelectric capacitor is provided. A conductive plug is formed in a first insulating layer on a semiconductor substrate. A first lower metal layer is formed overlying the conductive plug. A lower metal oxide layer is formed on the first lower metal layer. A second lower metal layer is formed on top of the lower metal oxide layer. A ferroelectric layer is formed from a ferroelectric material on the lower electrode layer at a crystallizing temperature of approximately 700° C. A first upper metal layer is formed on top of the ferroelectric layer. Thereafter, a heat treatment higher than the crystallizing temperature is performed. An upper metal oxide layer is formed on top of the first upper metal layer. A second upper metal layer is formed on top of the upper metal oxide layer.

Abstract: A ferroelectric capacitor with a multilayer ferroelectric film to prevent degradation of its ferromagnetic characteristics, wherein the ferroelectric film is made of a lower layer of PZT or PLZT formed on a lower electrode and an upper, titanium rich, layer of PZT, PLZT, or PbTiO3, an upper electrode formed on the upper layer of the ferroelectric film and a protective layer formed to cover the ferroelectric capacitor.

Abstract: A ferroelectric capacitor with a ferroelectric film having a relatively larger amount of titanium constituent than zirconate constituent improves ferroelectric characteristics. The method for fabricating the ferroelectric capacitor includes the step of performing a heat treatment in an oxygen atmosphere after forming a contact opening in an insulating layer which covers an already formed ferroelectric capacitor. This heat treatment in an oxygen atmosphere can minimize undesirable side effects resulting from a platinum electrode oxidizing the ferroelectric film components.

Abstract: A ferroelectric memory device includes a microelectronic substrate and a plurality of ferroelectric capacitors on the substrate, arranged as a plurality of rows and columns in respective row and column directions. A plurality of parallel plate lines overlie the ferroelectric capacitors and extend along the row direction, wherein a plate line contacts ferroelectric capacitors in at least two adjacent rows. The plurality of plate lines may include a plurality of local plate lines, and the ferroelectric memory device may further include an insulating layer disposed on the local plate lines and a plurality of main plate lines disposed on the insulating layer and contacting the local plate lines through openings in the insulating layer. In some embodiments, ferroelectric capacitors in adjacent rows share a common upper electrode, and respective ones of the local plate lines are disposed on respective ones of the common upper electrodes.

Abstract: Disclosed is a triple metal line 1T/1C ferroelectric memory device and a method to make the same. A ferroelectric capacitor is connected to the transistor through a buried contact plug. An oxidation barrier layer lies between the contact plug and the lower electrode of the capacitor. A diffusion barrier layer covers the ferroelectric capacitor to prevent diffusion of material into or out of capacitor. As a result of forming the oxidation barrier layer, the contact plug is not exposed to the ambient oxygen atmosphere thereby providing a reliable ohmic contact between the contact plug and the lower electrode. Also, the memory device provides a triple interconnection structure made of metal, which improves device operation characteristics.

Abstract: Disclosed is a triple metal line 1T/1C ferroelectric memory device and a method to make the same. A ferroelectric capacitor is connected to the transistor through a buried contact plug. An oxidation barrier layer lies between the contact plug and the lower electrode of the capacitor. A diffusion barrier layer covers the ferroelectric capacitor to prevent diffusion of material into or out of capacitor. As a result of forming the oxidation barrier layer, the contact plug is not exposed to the ambient oxygen atmosphere thereby providing a reliable ohmic contact between the contact plug and the lower electrode. Also, the memory device provides a triple interconnection structure made of metal, which improves device operation characteristics.

Abstract: A ferroelectric capacitor with a multilayer ferroelectric film to prevent degradation of its ferroelectric characteristics. The ferroelectric film is made of a lower PZT layer formed on a lower electrode and an upper titanium rich PZT or PbTiO3 layer. An upper electrode is formed on the second ferroelectric layer and a protection layer is formed to cover the ferroelectric capacitor.

Abstract: Integrated circuit ferroelectric memory devices are manufactured by forming a first patterned conductive layer on an integrated circuit substrate, to define a lower capacitor electrode and a gate electrode that is spaced apart therefrom. A source region and a drain region are formed on opposite sides of the gate electrode. A ferroelectric layer is formed on the lower capacitor electrode. An upper capacitor electrode is formed on the ferroelectric layer opposite the lower capacitor electrode, to thereby form a ferroelectric capacitor. After forming the upper capacitor electrode, an interconnect layer is formed that electrically connects the top electrode and the source region. A bit line is formed that electrically contacts the drain region. Preferably, both the interconnect layer and the bit line are formed from the same conductive layer.

Abstract: A semiconductor device including a ferroelectric capacitor and manufacturing method thereof are provided. The semiconductor device using a triple layered structure of metal layer/metal oxide layer/metal layer as an electrode of a capacitor is provided. According to the manufacturing method, a conductive plug electrically connected to a semiconductor substrate is formed by penetrating through a first insulating layer on the semiconductor substrate. An adhesive layer is formed on the conductive plug to form a first lower metal layer made of noble metals such as iridium that is electrically connected to the conductive plug and prevents diffusion of oxygen into the conductive plug on the first insulating layer. A conductive lower metal oxide layer is formed on the first lower metal layer, and a second lower metal layer for inducing interface lattice matching is preferably formed of platinum to form a lower electrode layer of a capacitor.

Abstract: Integrated circuit ferroelectric memory devices are manufactured by forming a first patterned conductive layer on an integrated circuit substrate, to define a lower capacitor electrode and a gate electrode that is spaced apart therefrom. A source region and a drain region are formed on opposite sides of the gate electrode. A ferroelectric layer is formed on the lower capacitor electrode. An upper capacitor electrode is formed on the ferroelectric layer opposite the lower capacitor electrode, to thereby form a ferroelectric capacitor. After forming the upper capacitor electrode, an interconnect layer is formed that electrically connects the top electrode and the source region. A bit line is formed that electrically contacts the drain region. Preferably, both the interconnect layer and the bit line are formed from the same conductive layer.