A fully integrated digital PLL (Phase Locked Loop) with on-chip CMOS oscillator is described. Nominal division number of the variable divider is automatically tuned in this digital PLL and this feature makes it possible to widen the pull-in range. In general, output jitter may increase if the pull-in range is widened. To overcome this problem, output jitter is reduced by utilizing the dual loop architecture. Wide pull-in range enables us on-chip oscillator, which is not so precise as the expensive crystal oscillator. This CMOS oscillator must be carefully designed to be stable against the temperature and the supply voltage variations. Using these digital PLL techniques, together with the on-chip CMOS oscillator, a fully integrated PLL can be achieved. Circuits are designed for 1.544 Mbit/s ISDN primary rate interface, and 6.25% pull-in range is obtained.

In this paper, we present a 10 Gbase Ethernet Transceiver that is suitable for 10 Gb/s Ethernet applications. The 10 Gbase Ethernet Transceiver LSI, which contains the high-speed interface and the fully integrated IEEE 802.3ae compliant logics, is fabricated in a 0.18 µm SOI/CMOS process and dissipates 2.9 W at 1.8 V supply. By incorporating the monolithic approach and the use of the advance CMOS process, this 10 GbE transceiver realizes a low power, low cost and compact solution for the exponentially increasing need of broadband network applications.

A new approach which implements a simple, high-speed phase detector with precharge logic will be presented. The minimum detectable phase difference is 40 psec, which is less than a half of conventional detectors. A current mode ring oscillator with a complementary-input bias generator has also been developed to enhance the dynamic range of the VCO under a low supply voltage. A fully CMOS PLL was designed using 0.5-µm technology. By virtue of this simple, fast detector, the wide operation range of 250 MHz at 1.5 V to 622 MHz at 3.0 V was achieved by simulation.

A new approach to implement queues for controlling ATM switch LSI is presented. In many conventional architecture, external FIFOs are provided for each output link and used to manage the address of the buffer in an ATM switch. We reduce the number of FIFOs by using a self-timed queue with a search circuit that finds the earliest entry for each output link. Using this architecture, number of the FIFOs is reduced to 1/N, where N is the switch size. Delay priority and multicasting can be supported without doubling the number of the queues. This new queue can also be utilized as an ATM switch by itself. Evaluation chip was fabricated using 0.5-µm CMOS process technology. Inter-stage transfer speed over 500 MHz and cycle time over 125 MHz was obtained. This performance is enough for a 622-Mbps 1616 ATM Switch.

A new shared multibuffer architecture for high-speed ATM (Asynchronous Transfer Mode) switch LSIs is described. Multiple buffer memories are located between two crosspoint switches. By controlling the input-side crosspoint switch so as to equalize the utilization rate of each buffer memory, these multiple buffer memories can be recognized as a single large shared buffer memory. High utilization efficiency of buffer memory can thus be achieved, and the cell loss ratio is minimized. By accessing the buffer memories in parallel via crosspoint switches, the time required to access the buffer memories is greatly reduced. This feature enables high-speed operation of the switch. The shared multibuffer architecture was implemented in a switch LSI using 0.8-µm BiCMOS process technology. Experimental results revealed that this chip can operate at more than 125 MHz. Bit-sliced eight switch LSIs operating at 78 MHz construct a 622-Mb/s 88 ATM switching system with a buffer size of 1,024 ATM cells. Power consumption of the switch LSI was 3 W.

A new ATM switch architecture, named shared multibuffering, features great advantages on memory access speed for a large switch, and overall size of buffer memories to achieve excellent cell-loss performance. We have developed a 622-Mb/s 88 shared multibuffer ATM switch with multicast functions and hierarchical queueing functions to accommodate 156-Mb/s, 622-Mb/s and 2.4-Gb/s interfaces. Implementation of the shared multibuffer ATM switch is described with respect to the four sorts of 0.8-µm BiCMOS LSIs and ATM switch boards. The switch board/type-1, with C1-LSI, allows to accommodate effectively 156-Mb/s and 622-Mb/s interfaces, which is suitable for an ATM access system. The switch board/type-2, with C2-LSI, can provide multicast functions and accommodate a 2.4-Gb/s interface. By using four switch boards, it is possible to apply them to a 2.4-Gb/s ATM loop system.