High speed bus system and method for using voltage and...

Electrical computers and digital data processing systems: input/ – Intrasystem connection – Bus access regulation

Reexamination Certificate

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C710S104000, C710S110000

Reexamination Certificate

active

06513080

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates generally to computer signal communication, and more particularly to an integrated circuit interface and method for high speed block transfer signaling of data, control and address signals between multiple integrated circuits on a bus or point-to-point with reduced power consumption.
2. Description of the Background Art
Semiconductor integrated circuits used in digital computing and other digital applications often use a plurality of Very Large Scale Integration (VLSI) interconnected circuits for implementing binary communication across single or multi-segmented transmission lines. Conventional transmission lines include traces, which are formed on a suitable substrate, such as a printed circuit board. Each transmission line may be designed, for example, using so-called micro-strip traces and strip line traces to form a transmission line having a characteristic impedance on the order of about 50-70 ohms. Alternatively, each transmission line may have its opposite ends terminated in their characteristic impedance. The output load on a driver for such a transmission line may be as low as 25-35 ohms.
To consume reasonable power, high frequency signaling requires small amplitude signals. For a receiver to detect voltage swings (e.g., 0.8 v to 1.2 v) easily in a noisy environment like GTL, HSTL, SSTL or RAMBUS, the current must also be very large (e.g., on the order of 50 to 60 milliamps per driver). A typical receiver uses a comparator with a voltage reference (VREF) signal configured midway between input high voltage (VIH) and input low voltage (VIL). The VREF signal is a high impedance DC voltage reference which tracks loosely with power supplies over time, but cannot respond to instantaneous noise. Conventionally, High Output Voltage (VOH) and Low Output Voltage (VOL) denote signals emerging from the transmitting source, and VIL and VIH denote signals arriving at the input of the receiving device, although they can be considered the same signal.
FIG. 1A
is a block diagram illustrating a prior art receiver
10
using RAMBUS technology. The system
10
includes a pad
100
coupled via signal lines
103
to internal input receivers
110
. A VREF signal
105
is coupled to each internal receiver
110
. VREF is generated from the power supply. Usually, the DC value of the power supply varies by five percent (5%). FIG. IB is a timing diagram
125
illustrating an example signal relative to a high reference voltage (VREFh) and a low reference voltage (VREFl). The VREFh and VREFl values typically depend on power supply variation used to generate the VREF signal. The large voltage swing, i.e., the difference between a high voltage signal (VIH) and a low voltage signal (VIL), and stable signal levels above and below the VREF signal are required for reliable detection of signal polarity. The voltage swing of current single-ended signaling technologies is conventionally around 0.8 v.
FIG. 1C
is a block diagram illustrating schematics of a prior art receiver
150
using RAMBUS technology. The receiver
150
samples the level of input signal
167
and of the VREF signal
154
until the signal reaches a stable level, at which time the pass gates
160
and
165
turn off. Once the pass gates
160
and
165
turn off, the sense gate
172
is enabled to eliminate current injection.
FIG. 1D
is a timing diagram
175
illustrating operation of the receiver
150
for an example signal. The receiver
150
samples the input reference and input signal until the signal reaches a stable level, e.g., a low logic level (VIL), and, while the input signal is stable, the receiver
150
senses the value of the input signal. As stated above, for reliable signal detection, the signal voltage swing must be fast enough to allow all the receivers
150
to sample a stable signal with an adequate margin for set-up and hold time. This voltage swing should occur in less than 30% of the minimum cycle time to allow margin for signal skew, set-up and hold-times. As the minimum cycle time reduces below 1 nanosecond, the margins reduce for signal skew, set-up time and hold-time, with the additional burden on the driver current in a high capacitance loading environment operating at high frequency. Low voltage differential signaling (LVDS) used by IEEE P1596.3 can overcome these problems by using a 250 mv voltage swing at the expense of running complimentary signals. Running complementary signals inevitably increases the pin count and package size.
Further, computer systems typically utilized a bus system in which several devices are coupled to the bus. Most of them use a clock to validate data, address and control signals.
FIG. 21
illustrates a prior art system
2100
for RDRAM, which uses a clock line
2130
having two segments
2136
and
2130
. One segment
2136
extends from one end of a data bus to a turnaround point
2137
near the second end of the bus. The other clock segment
2138
extends from the turnaround
2137
back to the first end of the data bus. The signal bus
2120
carries data, address and control signals. This topology ensures that the signal sent on the bus
2120
always travels contemporaneously with end in the same direction as the clock
2132
used by the device to receive the signal. This works fine if the loading off all signals and the clock is almost identical and the clock
2132
is used to sample and receive the signal. However, sometimes the system might require twice the data bandwidth, in which case this type of bus system needs to double the number of signals even though the address and control signals are identical, and could have been shared.
Accordingly, there is a need for low power drivers and reliable receivers for high frequency operation of a large number of single-ended signals in existing technology for low cost VLSI digital systems.
SUMMARY AND OBJECTS OF THE INVENTION
A system of the present invention uses small swing differential source synchronous voltage and timing reference signals (SSVTR and /SSVTR) to compare single-ended signals of the same swing generated from the same integrated circuit for high frequency signaling. It will be appreciated that “/” is being used to indicate a logical NOT. All signals are terminated with their characteristic impedance on both ends of the transmission lines. SSVTR and /SSVTR toggle every time the valid signals are driven by the transmitting integrated circuit. Each signal receiver includes two comparators, one for comparing the signal against SSVTR and the other for comparing the signal against /SSVTR. A present signal binary value determines which comparator is coupled, optionally by using exclusive-OR logic with SSVTR and /SSVTR. Until SSVTR and /SSVTR have changed their binary value, the coupled comparator in the receiver detects whether a change in signal binary value occurred. Again, it will be appreciated that SSVTR and /SSVTR change their binary value every time the signal can change its binary value. SSVTR and /SSVTR are preferably synchronized with the signal.
The method of the present invention includes the steps of obtaining an oscillating source synchronous voltage and timing reference and its complement (SSVTR and /SSVTR), and receiving an incoming single-ended signal. The method compares the oscillating reference against the incoming signal by a first comparator to generate a first result, and compares the complement against the incoming signal by a second comparator to generate a second result. The method then selects one of the first result or the second result as an output signal based on the previous signal. The step of selecting one of the results includes comparing the output signal to the reference (SSVTR) and to the complement (/SSVTR). The step of selecting further includes manipulating the output signal from the previous signal towards the first result or second result, based on the comparator which is currently coupled. If the incoming signal changes, the step of selecting includes maintaining the same comparator coupled. If the in

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