1. A multi-port volatile memory device, comprising:
a first port configured for data transfer tofrom an external host system and the device;
a volatile main memory core configured to store data received thereat and read requested stored data thereform;
a volatile sub memory core configured to store data received thereat and read requested stored data therefrom;
a main interface circuit coupled to the first port and configured to provide data tofrom the volatile main memory core and the first port in a master mode and configured to provide data tofrom the volatile sub memory core and the first port in a slave mode;
a second port configured for data transfer tofrom an external non-volatile memory device and the device; and
a sub interface circuit coupled to the second port and configured to provide data tofrom the volatile sub memory core and the second port in the slave mode.
2. A multi-port volatile memory device according to claim 1 wherein the main interface circuit comprises:
a command decoder configured to decode a command provided from the external host system to generate at least one internal command control signal;
an address buffer configured to generate at least one internal address control signal based on an address signal provided from the external system;
a data inputoutput buffer configured to transfer data between the external host system and the volatile main memory core in the master mode and configured to transfer data tofrom the external host system and the volatile sub memory core in the slave mode; and
a controller configured to control the volatile main memory core and the volatile sub memory based on first control data provided through the address buffer and the data inputoutput buffer in response to a masterslave mode select signal provided from the external host system.
3. A multi-port volatile memory device according to claim 1 wherein the main interface circuit further comprises:
a power management circuit configured to enabledisable a power supply voltage to the volatile sub memory core and the sub interface circuit in response to the at least one internal command control signal provided from the command decoder.
4. A multi-port volatile memory device according to claim 2 wherein a capacity of the volatile sub memory core corresponds comprises at least one page of memory or one block of memory, the flash memory being accessed in a unit of one page of memory or one block of memory.
5. A multi-port volatile memory device according to claim 1 wherein the sub interface circuit includes a NAND type flash controller configured to control data transfer between the sub memory core and the flash memory coupled to the second port in response to second control data provided from the controller.
6. A multi-port volatile memory device according to claim 1 wherein the non-volatile memory, the volatile main memory core, and the volatile sub memory core are included in a single package.
7. A multi-port volatile memory device according to claim 1 wherein the second port is configured to couple to a NAND type flash memory and the device comprises a synchronous DRAM.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. Hydraulic unit for slip-controlled braking systems comprising:
an accommodating member for accommodating inlet and outlet valves in several valve accommodating bores of a first and a second valve row, said inlet and outlet valves opening into a first housing surface of the accommodating member that is disposed at right angles to a second housing surface into which several braking pressure generator ports open,
a pump accommodating bore arranged in the accommodating member, wherein said pump accommodating bore is directed transversely to the direction the valve accommodating bores, wherein the valve accommodating bores for the outlet valves are arranged in the second valve row that is directly adjacent to the pump accommodating bore,
a motor accommodating bore arranged in the accommodating member and directed vertically to the pump accommodating bore,
an accumulator accommodating bore opening arranged in the accommodating member, wherein the accumulator member includes several pressure fluid channels that connect the accommodating bores for the valve, the pump and the accumulator, wherein the several pressure fluid channels enable a hydraulic communication between a braking pressure generator and several wheel brakes, wherein the inlet valves are arranged in the valve accommodating bores of the first valve row which is spatially separated from the second valve row accommodating the outlet valves by the pump accommodating bore, wherein several valve accommodating bores of a third valve row remote from the pump accommodating bore open directly between the second valve row and the braking pressure generator ports into the first housing surface of the accommodating member,
an electric change over valve for effecting hydraulic communication between at least one braking pressure generator port and a suction-side connection of the pump accommodating bore wherein said electric change-over valve is closed in its basic position in at least one valve accommodating bore of the third valve row, wherein the hydraulic communication between said changeover valve and the pump accommodating bore is established by way of a portion of a suction channel, the length thereof being determined by the distance between the pump accommodating bore and the third valve row,
wherein a closure member is mounted into the suction channel as a transverse bore from the direction of the second housing surface in order to prevent a short-circuit current between a first and a fourth portion of the suction channel.
2. Hydraulic unit as claimed in claim 1, wherein a pressure-side outlet of the pump accommodating bore opens into a noise damping chamber that is arranged adjacent to the first valve row in the accommodating member remote from the second and third valve row.
3. Hydraulic unit as claimed in claim 1, wherein the valve accommodating bore of the third valve row accommodating the electric changeover valve is designed as a blind-end bore which extends from the direction of the first housing surface up to the bottom of the blind-end bore, which is crossed by the suction channel and is tangent thereto in the area of bottom, and wherein one of the braking pressure generator ports opens at a vertical distance from the bottom into the valve accommodating bore of the third valve row in such a manner that depending on the valve switch position of the electric change-over valve associated with the valve accommodating bore, there is a direct pressure fluid connection of the suction channel between the braking pressure generator port and the pump accommodating bore by way of the valve accommodating bore.
4. Hydraulic unit as claimed in claim 1, wherein the valve accommodating bore provided for the electric change-over valve is configured as a blind-end bore that extends from the direction of the first housing surface to the bottom of the blind-end bore, and in that in the area of the bottom the suction channel is continued linearly until the braking pressure generator port.
5. Hydraulic unit as claimed in claim 4, wherein a first and a fourth portion of the suction channel is produced by a drilling operation directed into the second housing surface, wherein said fourth portion of the suction channel extends up to the pump accommodating bore, wherein a second portion of the suction channel is produced by another drilling operation that is directed into a third housing surface disposed opposite the first housing surface, said second portion opening into the first portion of the suction channel produced by the first drilling operation, and wherein the second channel portion of the suction channel is interposed directly between the valve accommodating bore of the electric change-over valve and the braking pressure generator port.
6. Hydraulic unit as claimed in claim 5, further including a third channel portion that opens from the direction of the second housing surface into the valve accommodating bore of the electric change-over valve in parallel to the braking pressure generator port is introduced into the valve accommodating bore of the electric change over valve, said third channel portion extending from there to the pump accommodating bore by way of a fourth channel portion that is continued coaxially to the first portion of the first suction channel.
7. Hydraulic unit as claimed in claim 1, wherein the closure member is positioned in the portion of the transverse bore disposed between the valve accommodating bore and a second channel portion of the suction channel.
8. Hydraulic unit as claimed in claim 7, wherein the closure member is designed as a ball that is press-fitted into the channel bore from the direction of the braking pressure generator port.
9. Hydraulic unit for slip-controlled braking systems comprising:
an accommodating member for accommodating inlet and outlet valves in several valve accommodating bores of a first and a second valve row, said inlet and outlet valves opening into a first housing surface of the accommodating member that is disposed at right angles to a second housing surface into which several braking pressure generator ports open,
a pump accommodating bore arranged in the accommodating member, wherein said pump accommodating bore is directed transversely to the direction the valve accommodating bores, wherein the valve accommodating bores for the outlet valves are arranged in the second valve row that is directly adjacent to the pump accommodating bore,
a motor accommodating bore arranged in the accommodating member and directed vertically to the pump accommodating bore,
an accumulator accommodating bore opening arranged in the accommodating member, wherein the accumulator member includes several pressure fluid channels that connect the accommodating bores for the valve, the pump and the accumulator, wherein the several pressure fluid channels enable a hydraulic communication between a braking pressure generator and several wheel brakes, wherein the inlet valves are arranged in the valve accommodating bores of the first valve row which is spatially separated from the second valve row accommodating the outlet valves by the pump accommodating bore, wherein several valve accommodating bores of a third valve row remote from the pump accommodating bore open directly between the second valve row and the braking pressure generator ports into the first housing surface of the accommodating member,
an electric change over valve for effecting hydraulic communication between at least one braking pressure generator port and a suction-side connection of the pump accommodating bore wherein said electric change-over valve is closed in its basic position in at least one valve accommodating bore of the third valve row, wherein the hydraulic communication between said change-over valve and the pump accommodating bore is established by way of a portion of a suction channel, the length thereof being determined by the distance between the pump accommodating bore and the third valve row,
wherein the valve accommodating bore provided for the electric change-over valve is configured as a blind-end bore that extends from the direction of the first housing surface to the bottom of the blind-end bore, and in that in the area of the bottom the suction channel is continued linearly until the braking pressure generator port,
wherein a first and a fourth portion of the suction channel is produced by a drilling operation directed into the second housing surface, wherein said fourth portion of the suction channel extends up to the pump accommodating bore, wherein a second portion of the suction channel is produced by another drilling operation that is directed into a third housing surface disposed opposite the first housing surface, said second portion opening into the first portion of the suction channel produced by the first drilling operation, and wherein the second channel portion of the suction channel is interposed directly between the valve accommodating bore of the electric change-over valve and the braking pressure generator port.
10. Hydraulic unit as claimed in claim 9, further including a third channel portion that opens from the direction of the second housing surface into the valve accommodating bore electric change-over valve in parallel to the braking pressure generator port is introduced into the valve accommodating bore of the electric change-over valve, said third channel portion extending from there to the pump accommodating bore by way of a fourth channel portion that is continued coaxially to the first portion of the first suction channel.