Electrical computers and digital processing systems: support – Synchronization of clock or timing signals – data – or pulses
Reexamination Certificate
1999-09-03
2003-12-16
Lee, Thomas (Department: 2185)
Electrical computers and digital processing systems: support
Synchronization of clock or timing signals, data, or pulses
C370S902000, 37, C714S731000
Reexamination Certificate
active
06665807
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an information processing apparatus such as personal computers and work stations, and in particular to protocols of buses of these information processing apparatuses and internal buses of LSIs used in the information processing apparatus.
2. Description of the Related Art
As for the conventional technique concerning buses used in an information processing apparatus such as personal computers and work stations, and concerning control methods of the buses, there is known a technique described in U.S. Pat. No. 5,428,753 assigned to the present assignee. As described therein, a synchronous bus has become a main stream since the design of the interface circuit is facilitated. In the synchronous bus, a plurality of modules connected to the bus conduct data transmission and reception control in synchronism with common clock timing. A typical synchronous bus configuration and its timing chart are shown in
FIGS. 13 and 14
, respectively. In
FIG. 13
, numeral
1300
denotes a clock generator for distributing a common system clock among modules, Numerals
1301
,
1302
and
1303
denote modules on a bus. Numeral
1301
denotes a master module serving as a transfer source of data. Numeral
1303
denotes a slave module serving as a transfer destination of data, and numeral
1304
denotes a data bus. With reference to
FIGS. 13 and 14
, numerals
1400
and
1401
denote timing relations between a system clock and output data observed on an output pin of the master module
1301
serving as the transfer source of data. Numerals
1402
and
1403
denote timing relations between the system clock and input data observed on an input pin of the slave module
1303
serving as the transfer destination of data. The clocks
1400
and
1402
are distributed from the clock generator
1300
of
FIG. 13
with the same phase. Data on the input pin of the slave module
1303
is delayed from that on the output pin of the master module
1301
by a propagation delay time on the data bus
1304
. Since data must be transferred from the master module to the slave module in one cycle, the maximum operation frequency is typically determined on a synchronous bus by a maximum propagation delay time of the bus.
SUMMARY OF THE INVENTION
For solving this problem and further raising the frequency, a bus of a “source clock synchronous system” (or a source clock synchronous bus) is conceivable. In the “source clock synchronous system”, a module serving as a transfer source transmits a latch clock to be used in a module of a transfer destination together with transfer data. A bus configuration and a timing chart of a typical source clock synchronous system are shown in
FIGS. 15 and 16
, respectively. In
FIG. 15
, numeral
1500
denotes a signal line for a source clock which is transmitted from a master module serving as a transfer source to a slave module serving as a transfer destination. With reference to
FIG. 16
, numerals
1600
and
1601
denote timing relations between a source clock and output data observed on an output pin of the master module serving as the transfer source of data. Numerals
1602
and
1603
denote timing relations between the source clock and input data observed on an input pin of the slave module serving as the transfer destination of data. If a source clock line and a data line are mounted on similar wiring paths in the bus of the source clock synchronous system, the source clock and the data are delayed by the same phase, and consequently failures of data acquisition are reduced. In other words, the maximum operation frequency of the bus is not reflected at the time of data propagation delay. (Because data are further delayed in a remote module, but the latch clock is also delayed by the same phase.) Typically, the bus of the source clock synchronous system is such a bus that the operation frequency can be raised easily.
However, the synchronous bus is more excellent in easiness of design. A control method of signals of an acknowledge type for each transfer cycle as described in, for example, U.S. Pat. No. 5,428,753 will now be considered.
FIG. 17
shows transfer timing of the synchronous bus with a protocol of the acknowledge type. In
FIG. 17
, numeral
1700
denotes a system clock common to modules on the bus, numeral
1701
denotes transfer data timing, and numeral
1702
denotes acknowledge signal timing. If it is determined in the synchronous bus that a signal of the acknowledge type is issued necessarily two cycles after the data transfer cycle, association of transfer data with the report of the acknowledge type is very easy. As for the protocol of the acknowledge type, there are, for example, an acknowledge for notifying the master side that the slave side has certainly received data, a retry request for requesting the master side to retransfer data later because the slave side is not ready to receive data, and an error report for notifying the master side that data received by the slave side contained an error (such as a parity error). In the bus of the source clock synchronous system allowing data transfer at a clock frequency unique to an individual module, there is a possibility that the master side and the slave do not have the same clock system. Therefore, there is a problem that it is difficult to add a protocol of the acknowledge and the retry request.
A first object of the present invention is to provide a bus of source clock synchronous system with a protocol of an acknowledge type in order to operate the bus with high reliability and a high efficiency.
Furthermore, an information processing apparatus adopting a synchronous bus which has formed the mainstream has the following problem. Components and modules having different operation clock frequencies cannot be used mixedly. For example, if the frequency of a processor is raised, a chip set such as a companion chip must also be replaced with that having the same frequency as that of the processor. This results in a problem of an increased cost.
A second object of the present invention is to make it possible to mixedly use components and modules having different operation clock frequencies.
In order to solve the first problem, in the present invention, there is provided a source clock signal dedicated to acknowledge type signals on a signal line of a bus in order to transfer the acknowledge type signals as well by using the source clock synchronous system. Furthermore, in order to make possible control even if there are mixedly modules having different operation frequencies, an acknowledge signal is not provided for each cycle, but is provided for each basic transfer block having a substantial number of cycles. Since the acknowledge type signals are also transferred in the source clock synchronous system by using a source clock signal dedicated to the acknowledge type signals in the present invention system, a failure, on the master side, of acquisition of an acknowledge type signal from the slave side is prevented. Furthermore, since an acknowledge signal is provided for each basic transfer block having a substantial number of cycles, control becomes possible even if there are mixedly modules having different operation frequencies.
In order to solve the second problem, in the present invention, a system is constructed by providing respective modules with synchronization circuits therein so as to be able to conduct data reception and data transmission with different clocks. When transferring data in the present invention system, the latch clock to be used in the transfer destination module is transmitted by itself. Therefore, data can be transferred irrespective of the clock frequency of the transfer destination. Furthermore, when receiving data, the data can be latched uneventfully with the source clock transmitted from the transfer source. In addition, since the synchronization circuit for synchronizing data to the clock of its own module is provided in its own module, data can be received irrespective of the clock frequency of the
Kawasaki Ikuya
Kondo Nobukazu
Noguchi Koki
Antonelli Terry Stout & Kraus LLP
Hitachi , Ltd.
Lee Thomas
Patel N C
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