The present invention relates generally to memory systems. More particularly, the present invention relates to an apparatus and a method for producing device identifiers for a serial interconnection of devices of mixed type.
Current consumer electronic equipment uses memory devices. For example, mobile electronic devices such as digital cameras, portable digital assistants, portable audio/video players and mobile terminals continue to require mass storage memories, preferably non-volatile memory with ever increasing capacities and speed capabilities. Non-volatile memory and hard disk drives are preferred since data is retained in the absence of power, thus extending battery life.
While existing memory devices operate at speeds sufficient for many current consumer electronic devices, such memory devices may not be adequate for use in future electronic devices and other devices where high data rates are desired. For example, a mobile multimedia device that records high definition moving pictures is likely to require a memory module with a greater programming throughput than one with current memory technology. While such a solution appears to be straightforward, there is a problem with signal quality at such high frequencies, which sets a practical limitation on the operating frequency of the memory. The memory communicates with other components using a set of parallel input/output (I/O) pins, the number of which depends on the desired configuration. The I/O pins receive command instructions and input data and provides output data. This is commonly known as a parallel interface. High speed operation may cause deleterious communication effects such as, for example, cross-talk, signal skew and signal attenuation, which degrade signal quality.
In order to incorporate higher density and faster operation on the system boards, there are two design techniques: serial interconnection and multi-drop configurations. These design techniques may be used to overcome the density issue that determines the cost and operating efficiency of memory swapping between a hard disk and a memory system. However, multi-drop configurations have shortcomings relative to the serial interconnection of memory systems. For example, if the number of multi-drop memory systems increases, as a result of loading effect of each pin, delay time also increases so that the total performance of multi-drop is degraded by the multi-drop connection caused by the wire resistor-capacitor loading and the pin capacitance of the memory device. A serial link in a device such as a memory device may utilize a single pin input that receives all addresses, commands, and data serially. The serial link may provide a serial interconnection configuration to control command bits, address bits, and data bits effectively through the serial interconnection. By providing a serial interconnection configuration, a device identifier is assigned to each of the connected devices.
In accordance with one aspect of the present invention, there is provided a system comprising a plurality of memory devices including at least first and second devices in a serial interconnection configuration, the first device having serial input and output connections, the second device having a serial input connection, the serial input connection of the first device being coupled to a serial output connection of a previous device, the serial output connection of the first device being coupled to the serial input connection of the second device. The first device includes: a receiver for receiving a device identifier (ID) and a device type (DT) through the serial input connection thereof; a determiner for determining the device type from the received DT; and an ID assignor for assigning an ID in response to a determination result.
For example, the ID assignor includes a calculator for performing the calculation of the ID based on the received ID and a pre-defined value. The calculator may be an adder that adds one to the ID or a subtractor that subtracts one from the ID.
The first device may further include a device information provider for providing device type information (DTI) of the device. For example, the determiner includes a comparator for comparing the DT with the provided DTI to provide the determination result.
Advantageously, the ID assignor includes a selector for selecting one of the calculated ID and the received ID depending upon the determination result. The selected ID is outputted through the serial output connection of the device. The device information provider may include an information storage for storing the device type information on types of the plurality of memory devices, the device type information being provided in parallel manner to the selector.
Advantageously, the plurality of memory devices in the serial interconnection configuration includes mixed type memory devices, the memory devices including, such as random access memories (e.g., DRAMs, SRAMs, MRAMs) and Flash memories (e.g., NAND-type, NOR-type, AND-type Flash memories). The information storage may include a storage that is capable of storing the device type information of the mixed type memory devices and providing one of the device type information corresponding to a selected one of the memory devices.
In accordance with another aspect of the present invention, there is provided a method for assigning a device identifier at a first device coupled to a second device in a serial interconnection configuration, the first device having a serial input connection coupled to a serial output connection of a previous device in the serial interconnection configuration, the second device having a serial input connection coupled to a serial output connection of the first device. The method includes: receiving device identifier (ID) and a device type (DT) through the serial input connection of the first device; determining the DT of the device from the received DT; and providing an ID in response to a determination result.
Advantageously, the step of providing the ID includes performing the calculation of the received ID with a pre-defined value to provide a calculated ID. The method may include the step of providing device type information (DTI) of the device.
Advantageously, the step of determining the DT includes comparing the DT with the provided DTI to provide the determination result. The step of providing the ID includes selecting one of the received ID and the calculated ID depending upon the determination result. The selected ID is outputted as a new ID through the serial output connection of the device.
In accordance with a further aspect of the present invention, there is provided an apparatus for producing a device identifier at a first device coupled to a second device in a serial interconnection configuration, the first device having a serial input connection coupled to a serial output connection of a previous device in the serial interconnection configuration, the second device having a serial input connection coupled to a serial output connection of the first device. The apparatus includes: a receiver for receiving a device identifier (ID) and a device type (DT) through the serial input connection of the first device; a determiner for determining the DT of the device from the received DT; and an ID producer for producing an ID in response to a determination result.
The ID producer may include a calculator for performing the calculation of the received ID with a pre-defined value. The apparatus may include a device type producer for providing device type information (DTI) of the device.
For example, the determiner includes a comparator for comparing the received DT with the provided DTI to provide the determination result. The ID producer further includes a selector for selecting one of the received ID and the calculated ID depending upon the determination result. The selected ID is outputted through the serial output connection of the device.
Advantageously, the receiver includes: a register for registering the received ID and DT in serial manner; and an output provider for outputting each of the registered ID and DT in parallel manner. The ID and DT are provided separately by the receiver for calculating the ID and for selecting one of the pre-calculated ID and the calculated ID, respectively.
The apparatus may further include: a storage that is capable of storing the device type information on types of the plurality of memory devices; and a provider for providing the device type information of the devices for the determination.
In accordance with yet a further aspect of the present invention, there is provided a method for determining a device identifier of one of a plurality of devices in a serial interconnection configuration, the method comprising: receiving a first value corresponding to a device identifier (ID) and a second value corresponding to a device type (DT); comparing the second value to a device type number (DTN) stored at a first device; and producing a match signal that indicates whether the second value corresponds to the DTN.
The method may further include generating an ID responsive to the received ID. One of the generated ID and the received ID is selected to output a selected ID. A signal corresponding to the selected ID is transmitted to a second device.
Advantageously, in response to the match signal, the generated ID or the received ID is written into an ID register at the first device.
In accordance with yet a further aspect of the present invention, there is provided an apparatus for assigning a device identifier for use in a plurality of mixed type memory devices in a serial interconnection configuration, a first device having a serial input connection coupled to a serial output connection of a previous device, a second device having a serial input connection coupled to a serial output connection of the first device. The apparatus includes: a determiner for determining a received device type (DTsi) based on a device type (DT) in the serial interconnection configuration; and an ID producer for producing a device identifier (ID) in response to a determination result.
The apparatus may further include a receiver for receiving the ID and the DT through the serial input connection of the device. Advantageously, the ID producer includes a calculator for performing the calculation of the received ID with a pre-defined value. The apparatus may further include a device information provider for providing device type information (DTI) of the first device.
For example, the determiner includes: a comparator for comparing the DTsi with the provided DTI to provide the determination result. The ID producer includes a selector for selecting one of the received ID and the calculated ID depending upon the determination result. The selected ID is outputted through the serial output connection of the device.
For example, the device information provider includes a storage that is capable of storing the device type information of the memory devices and is capable of providing the device type information corresponding to a selected one of the memory devices. The device type information of the memory devices may include DRAM, SRAM, MRAM and NAND-, NOR- and AND-type Flash memories.
In accordance with yet a further aspect of the present invention, there is provided a method for assigning a device identifier at a first device coupled to a second device in a serial interconnection configuration, the first device having a serial input connection coupled to a serial output connection of a previous device in the serial interconnection configuration, the second device having a serial input connection coupled to a serial output connection of the first device. The method includes: receiving a device type (DT) through the serial input connection of the first device; determining the DT of the first device from the received DT; receiving a device identifier (ID) through the serial input connection of the first device; and producing an ID in response to the determination result.
The method may further include: holding the received DT; and holding the received ID. For example, the step of determining the DT includes providing a reference DT of the first device. The reference DT is compared with the held DT to provide the determination result. Advantageously, in response to the determination result, the calculation of the received ID with a pre-defined value is performed to provide a calculated ID. One of the held ID and the calculated ID is selected depending upon the determination result. The selected ID is outputted as a new ID through the serial output connection of the first device.
In accordance with yet a further aspect of the present invention, there is provided a method for assigning a device identifier for a plurality of mixed type memory devices in a serial interconnection configuration, a first device having a serial input connection coupled to a serial output connection of a previous device, a second device having a serial input connection coupled to a serial output connection of the first device. The method includes: receiving a device type (DT); holding the received DT at each of the devices; determining whether the DT matches a reference DT associated with each of the devices; providing a device identifier (ID) to one of the devices, through the serial input connection of the device; and at the device wherein the ID is provided, conducting an ID assignment in response to the determination result at that device.
Advantageously, the step of providing an ID includes providing the DT to the devices by serially transferring it from one device to a last device. For example, the step of holding the received DT is performed after the step of providing the DT. The step of determining the match is performed before the step of conducting the ID assignment at all of the devices. At each of the devices, the step of conducting the ID assignment is performed based on the previous determination result.
In some embodiments, the step of holding the received DT is performed after the step of providing the DT. The step of conducting the ID assignment is performed at each of the devices in response to the determination result. The step of conducting the ID assignment may include performing the calculation of the ID based on the provided ID and a pre-defined value; and passing the provided ID without altering it. Advantageously, at the device wherein the ID is provided, the calculated ID is outputted for another device (e.g., a next device) and the non-altered ID is outputted for the device.
In accordance with yet a further aspect of the present invention, there is provided a system comprising: a control signal provider for providing control signals; and a plurality of memory devices in a serial interconnection configuration, a first device having a serial input connection coupled to a serial output connection of a previous device, a second device having a serial input connection coupled to a serial output connection of the first device, the devices being controlled in response to the control signals.
In accordance with an embodiment of the present invention, there is provided an ID generation with skip function for serially interconnected memory devices of mixed type, in accordance with the device types.
Other aspects and features of the present invention will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments of the invention in conjunction with the accompanying figures.
Embodiments of the present invention will now be described, by way of example only, with reference to the attached figures, wherein:
In the following detailed description of embodiments of the present invention, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration of specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those of ordinary skill in the art to practice the present invention, and it is to be understood that other embodiments may be utilized and that logical, electrical, and other changes may be made without departing from the scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims.
Generally, the present invention provides an apparatus and a method for processing and capturing serial input data with ID generation in serially interconnected devices.
Some memory subsystems employ multiple Flash devices with serial interfaces. Here, the command string may be fed to all of the devices even though the command may only be performed on one of the devices. To select the device on which the command is to be performed, the command string may contain a device identifier (ID) that identifies the Flash device to which the command is directed. Each device receiving the command string compares the ID contained in the command string to an ID associated with the device. If the two match, the device assumes that the command is directed to itself and executes the command.
A problem with the above-described arrangement involves establishing an ID for each device. One technique that may be used to establish an ID for a device is to hardwire an internal unique ID into the device. One drawback with this approach, however, is that if large numbers of devices are used, the size of the ID may have to be quite long in order to ensure that each device contains a unique ID. Managing a large-sized device ID may add significant complexity to the device, which in turn may increase the cost of producing the device. In addition, reclaiming device IDs that are associated with devices that are no longer in use may further add to the complexity of this scheme.
Another approach to assigning IDs to devices involves externally hardwiring an ID for each device. Here, the ID may be specified by wiring various pins on the device to certain states to establish an ID for the device. The device reads the wired state of the pins and establishes its ID from the read state. One drawback with this approach, however, is that external wiring is needed to assign the ID for each device. This may add to the complexity of, e.g., printed circuit boards (PCBs) that hold the memory devices. Another drawback with this approach is that it may require pins to be dedicated for the assignment of the ID. This may consume precious resources that may be otherwise better used. In addition, dedicating pins for the assignment of the ID may require a greater footprint for the device than if pins were not used to assign the ID.
At least some embodiments of the present invention address at least some of these shortcomings. At least some example embodiments automatically establish an ID for a device, for example, in a serial interconnection arrangement, in a manner that does not require special internal or external hardwiring of the ID. According to one aspect of the techniques described herein, an input signal is transmitted through a serial interconnection to a first device in an arrangement including multiple devices (e.g., a serial interconnection arrangement) using inputs that are also used by the first device to input other information to the device (e.g., data, commands, control signals). A generator generates a device ID in response to the input signal. A transferor then transfers an output signal associated with the ID to a second memory device through a serial output of the first device. The serial output may also be used by the first device to output other information (e.g., signals, data) to other devices in the arrangement.
In an embodiment of the techniques described herein, a write ID operation is initiated at a device in a serial interconnection arrangement to cause the device to establish an ID. A first device receives a first value by acquiring the state of one or more inputs of the first device. The first device then establishes a device ID from the first value, which may include placing the first value in storage (e.g., a device ID register) associated with the device. The first device generates a second value from the acquired state of the inputs. The first device outputs the second value from the first device via outputs of the first device to a second device in the serial interconnection. The second device inputs the value output by the first device and repeats this process to establish an ID.
Embodiments of the present invention will now be described in conjunction with a MISL (multiple independent serial link). A MISL product is an item in the Flash memory area that enhances the operation performance without change to the core structure. It is an innovation of interface and data processing of Flash memories. Due to the restriction of Flash cell structure and limited performance of the cell, the enhancement of Flash performance has been a key issue to be resolved in the memory industry. Most products including Flash memory core have parallel ports that latch simultaneously all address bits, all command bits, and all data bits, respectively. A serial link utilizes a single pin input for receiving all address, command, and data serially. Details of MISL are described in U.S. patent application Ser. No. 11/324,023 filed Dec. 30, 2005; U.S. Provisional Patent Application No. 60/787,710 entitled “Serial interconnection of Memory Devices” filed Mar. 28, 2006; and U.S. Provisional Patent Application No. 60/802,645 entitled “Serial interconnection of Memory Devices” filed May 23, 2006, the contents of which are entirely incorporated herein by reference.
Referring to
In addition, the device 120-i has an input port enable input IPE, an output port enable input OPE, an input port enable output IPEQ and an output port enable output OPEQ. The IPE is used to input the input port enable signal SIPEi to the device 120-i. The signal SIPEi is used by the device to enable the SIP such that when the IPE is asserted, information is serially input to the device 120-i via the SIP. Likewise, the OPE is used to input the output port enable signal SOPEi to the device 120-i. The signal SOPEi is used by the device to enable the SOP such that when the OPE is asserted, information is serially output from the device 120-i via the SOP. The IPEQ and the OPEQ are outputs that output the signals SIPEQi and SOPEQi, respectively, from the device 120-i. The /CS and the CLK are coupled to separate links which distribute the chip select signal /SCS and the clock signal SCLK, respectively, to four devices 120-1-120-4, as described above.
The SIP and the SOP are coupled from previous device 120-(i−1) to next device 120-(i+1) in the serial interconnection arrangement, as described above. Moreover, the IPEQ and the OPEQ of the previous device 120-(i−1) are coupled to the IPE and the OPE, respectively, of the present device 120-i in the serial interconnection. This arrangement allows the signals SIPE and SOPE to be transferred from one device to the next (e.g., device 1, 120-1, to device 2, 120-2) in the serial interconnection configuration.
Information transmitted to the devices 120-1-120-4 can be latched at different times of the clock signal SCLK fed to the CLK. For example, in a single data rate (SDR) implementation, information input to the device 120-i at the SIP can be latched at either the rising or falling edge of the clock signal SCLK. Alternatively, in a double data rate (DDR) implementation, both the rising and falling edges of the clock signal SCLK can be used to latch information input at the SIP.
Referring to
In this example, N is 32. In other embodiments, N can be any other integer.
The ID stored in the ID register is according to the sequence and ID number itself. For example, if the ID register is 10-bits in length and OPE has a 5-cycle “high” state, then five bits are included in the ID generation and a signal corresponding to the 5-bit result is transferred to the next device. The remaining bits are ignored and “zero” values are kept in the ID registers. In the example shown in
The ID generator 333 generates a sequence of device ID numbers with consecutive integers from low to high. The resulting device ID assignment is shown in Table 2.
Alternatively, the sequence of device ID numbers could be any other numeral sequence, provided that the adder 333 is replaced with an alternative operator that enables the sequence. For example, the ID calculator 353 could be replaced with a subtractor for performing “−1 operation” of device ID, thereby enabling a sequence of consecutive integers from high to low.
The controller/processor 432 also provides an ID write enable signal 433 derived from the output port enable signal SOPE. In response to the ID write enable signal 433 and the determination result from the ID generator 434, the ID register 431 registers the received IDii contained in an ID signal 435 from the ID generator 434, as an ID for the present device 410-i. The registered ID is held until powered-off. The ID registration by the ID register 431 occurs only when the received DT, DTsi, matches the reference DT, DTref. In the case of no matching between DTsi and DTref, no ID registration occurs and the ID register 431 holds a reset value (e.g., “zero” state).
Referring to
The device type number assignment and the definition of device types in Table 3 above can be changed. More device types can be added.
The ID generator 434 also includes a serial input buffer 437 for receiving the serial input SIi through SIP of the device. The received SIi in the ID generation mode setting operation includes a value corresponding to a device type (DT), DTsi, which is a number of m-bits (e.g., eight bits). The received SIi in the ID generation operation includes a value corresponding to a device ID, IDii, which is a number of n-bits (e.g., eight bits). The clock signal SCLK is fed to a temporary ID register 440 and a device type (DT) clock generator 441. A DT register clock signal is internally generated in response to the clock signal SCLK. Each of the temporary ID register 440 and the DT register 439 is a serial-to-parallel register that registers the input serial data therein in response to the input clocks. In the ID generation mode setting operation, the m-bit DTsi contained in the SI is serially shifted into the register 439 in response to the DT register clock signal and held therein. In the ID generation mode, the n-bit IDii contained in the SI is serially shifted into the register 440 in response to the clock signal SCLK and held therein.
The m-bit DTsi and n-bit IDii separately held in the registers 439 and 440 are outputted in parallel as m-bit signal 445 and n-bit signal 447, respectively. The n-bit signal 447 is fed to a selector 452 and an adder 450 that provides a calculation signal 451 having a +1 operation value. The m-bit signal 445 is fed to a comparator 448 that also receives m-bit DT number, DTref, contained in a DT signal 443 from the DT number storage/provider 442. The comparator 448 includes an m-bit DT comparator 461 and a comparison result register 463. In response to the ID generation control signal 421 at determination time Tdti, the DT comparator 461 compares the DTsi to the DTref to provide a comparison result signal 465 to the comparison result register 463. Thus, the DT match determination result is held in the comparison result register 463 that provides a DT match signal 449. If DTsi and DTref are identical, the DT match signal 449 will become “high,” indicating a match between the two numbers of the device types DTsi, and DTref. Otherwise, the DT match signal 449 will become “low,” indicating that the received DTsi specifies a type of device that is different from that of the present device (410-i). The comparator 448 outputs the “high” DT match signal having a pulse width Tm, when a device type match occurs. Storing time period Tm is selected as the +1 operation is completed and the addition result is transferred to the parallel-to-serial register 454. The DT match signal 449 transits to “low” in response to the ID generation mode exit signal 422 from the controller/processor 432. Thus, Tm ends as the ID generation mode exits.
The adder 450 adds “1” to IDii, thereby producing the calculation signal 451 containing an ID, IDii+1, for another device (e.g., a next device) in a sequence of IDs in the serial interconnection. The adder 450 provides an appropriate function for ID generation when the selected sequence of ID numbers are consecutive integers from low to high. Alternatively, the sequence of ID numbers could be any other numeral sequence, provided that the adder 450 is replaced with an alternative operator that enables the sequence. For example, the adder 450 could be replaced with a subtractor that subtracts “1” from the ID, IDii, thereby enabling a sequence of consecutive integers from high to low.
The selector 452 selects one of the two inputs (effectively “added ID, IDii+1” and “non-added ID, IDii”) according to the DT match signal 449. If the DT match signal 449 is “high” (corresponding to a match between the DTsi and the DTref), then the selector 452 selects input “1”, which receives the signal 451 of “added IDii+1” from the adder 450. If the DT match signal 449 is “low” (corresponding to a difference between the DTsi and the DTref), then the selector 452 selects input “0”, which receives the signal 447 of “non-added IDii” from the serial-to-parallel register 440. The selected output signal of n-bits is fed to a parallel-to-serial register 454 that is enabled to register the selected n-bit ID data therein immediately before the expiration of the time period Tm, in response to an enable signal (not shown). The parallel-to-serial register 454 outputs the registered data in a serial manner as the serial output ID signal 455, in response to the clock signal SCLK. The serial output ID signal 455 is fed to a selector 456 of the output signal provider 436. The selector 456 also receives the processed data signal 425 provided by the controller/processor 432 accessing the memory 420-i (NAND or NOR Flash memory) of that device 410-i. In response to the ID generation enable signal 423 derived from the generation command by the controller/processor, the selector 456 selects the serial output ID signal 455 or the processed data signal 425 when the ID generation enable signal 423 is “high” (an ID generation mode) and “low” (the normal mode), respectively. A selected signal from the selector 456 is outputted through a serial output buffer 458 to the next device (410-(i+1)) in the serial interconnection.
It is noted that the aforementioned selector 452 is shown for selecting a single bit of IDii or a single bit of IDii+1. Accordingly, there are n duplicate selectors to select the n-bit signal 451 or 447 and output the selected n-bit signal, in response to the DT match signal 449.
The ID generator 434 provides the ID signal 435 containing the n-bit ID, IDii, to the ID register 431. In response to the ID write enable signal 433 from the device controller 430-i, the ID register 431 registers or latches the received ID, IDii, for the present device 410-i. The registered ID is held until powered-off. The ID register 431 is initially reset to the zero state and thus, if no ID latch occurs, the ID register 431 will hold the zero state.
With reference to
After step 518, the ID number or value is then altered by a “+1” operation (step 519), resulting in a new device ID, IDj. The new device ID, IDj, is converted to a serial signal (step 520) for transmission to the next device DV(i+1) (e.g., device 3) in the serial interconnection. As a result, the next device DV(i+1) receives the ID number, IDii. As the device DV(i+1) already received and held the device type DTsi in its DT register, the same ID generation process starts.
If the values of the DTsi and the DTref do not match (a negative determination at step 512), then no flag is set and no DT determination result is registered, so that the DT match signal 449 is “low”. This signal indicates to the device not to store the received device ID number, IDii, with no adding operation (step 521), and to transfer the device ID number to the next device in the serial interconnection (step 520). Upon completion of step 520, the ID generation process at the device DVi ends (step 522). The process shown in
Alternatively, steps 518 and 519 can be reversed, wherein the “new” device ID number (resulting from the “+1” operation) is stored at a device register. As a result, the device ID established for the device is the resulting “new” device ID number instead of the received device ID number. Accordingly, a memory controller may be configured to address the memory devices in the serial interconnection according to the device IDs established at each device.
When each device in the serial interconnection has completed the process, all devices with a matching DT number have established a device ID (step 518), and all other devices have refrained from establishing a device ID (step 521). To establish device IDs for these other devices, the process can be repeated for all devices, wherein the device type DTsi is replaced with a value matching the device type number of some or all of the other devices. For example, a first process, with DTsind matching a NAND Flash device, could be completed at all devices, thereby establishing a device ID at each NAND Flash device in the serial interconnection. Afterwards, a second process, with DTsinr matching a NOR Flash device, could be completed at all devices, thereby establishing a device ID at each NOR Flash device in the serial interconnection. The process may be further repeated for other device types (e.g., DRAM, SRAM) in the serial interconnection. As a result, each device in the serial interconnection can be uniquely identified in subsequent commands by specifying the device ID and device type DT of that device.
In a case where the stored reference device type DTref of the DT number storage/provider 442 is chosen for the NAND Flash memory, the device type DT is “00h” (see Table 3 above). In the process shown in
In a case where the stored DT of the DT number storage/provider 442 is chosen for the NOR Flash memory, the DT is “01h” (see Table 3 above). In the process shown in
Resulting device ID/device type assignment is shown in Table 5.
Referring to
The SI contains the device type DT (DTsi), the device identifier ID (initial ID (‘000’)) and a “write ID entry” command. In this example, the DT is DTnd for the NAND Flash memory and its DT number or code is ‘00h’, as shown in Table 3. During the ID generation mode setting time period TCS1, by the “write ID entry” command, IPE catches input streams which consists of command bits, Device type bits, Device ID bits (initial ‘000’). Thereafter, during TCS2 timing period, OPE catches an input stream, which consists of the same cycles as a total number of ID bits, e.g., three cycles. The ID bits are established by the size of an internal ID register. After the completion of the processes during the ID generation mode setting time period TCS1, the ID generation operation starts at time T1 and ends with an expiration of time period TIDG. With an expiration of one chip select cycle TCS2, TIDEX (e.g., five cycles or five rising edges of the clock pulse) after T2 the ID generation operation period TIDG expires at time T3. Devices 1, 3 and 5 provides the “high” device type match signals at determination times Tdt1, Tdt3 and Tdt5, respectively. Devices 2 and 4 do not, however, provide “high” match signal. In response the “high” DT match signals 449 (see
Referring to
Referring to
If there is no match between the DTsi and the DTref (a negative determination at step 914), the DT match signal will be “low”. The device does not store the received device ID number, IDii, with no adding operation (step 919). The non-altered IDii, as a new IDj, is transferred to the next device (step 918). Upon completion of step 918, the ID generation process at the device DVi ends (step 920). The process shown in
There are variations to the above-described embodiments. The configuration of the devices 120-1-120-4 in
In the above-described embodiments, the operation has been described based on the active “high” signals for the purpose of simplicity. They may be designed to perform the operation based on the “low” active signals, in accordance with a design preference. The control signals may have two bytes or more than two bytes in accordance with operation code assignment. Timing control can be changed from the sequential and multiple clocks enabled by command type to the single clock with additional control signals to activate the selected serial registers. The sequence of issuing multiple clocks can be varied in accordance with the specification of timing, arrangement of addresses, and the length of addresses. As mentioned before, it can apply the serial Flash memory or a product with serial input bit stream control.
In the embodiments described above, the device elements and circuits are connected to each other as shown in the figures, for the sake of simplicity. In practical applications of the present invention to apparatus, devices, elements, circuits, etc., they may be connected directly to each other. As well, devices, elements, circuits etc., may be connected indirectly to each other through other devices, elements, circuits, interfaces, etc., necessary for operation of the apparatus. Thus, in actual configuration, the elements and devices are directly or indirectly coupled with or connected to each other.
It is apparent to those of ordinary skill in the art that the ID generators or producers, the controllers, the processors and the other device elements and the memory controllers may be achieved by hardware and software.
The above-described embodiments of the present invention are intended to be examples only. Alterations, modifications and variations may be effected to the particular embodiments by those of skill in the art without departing from the scope of the invention, which is defined solely by the claims appended hereto.
This application claims the benefit of priority of U.S. Provisional Patent Application No. 60/870,892 entitled “IP Production for Serially Interconnected Devices of Varying Type” filed Dec. 20, 2006, the disclosure of which is expressly incorporated herein by reference in its entirety.
Number | Date | Country | |
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20080155179 A1 | Jun 2008 | US |
Number | Date | Country | |
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60870892 | Dec 2006 | US | |
60868773 | Dec 2006 | US |