A 4096 x 1 static bipolar RAM

1977 IEEE International Solid-State Circuits Conference. Digest of Technical Papers Pub Date : 1900-01-01 DOI:10.1109/ISSCC.1977.1155629

W. Herndon, W. Ho, R. Ramirez

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引用次数: 9

Abstract

is shown in Figure 1. By eliminatingemitter base spacing, device size is significantly reduced, resulting in a memory cell size of only three square mils per cell, and a 4K RAM chip of 23,650 square mils. A photomicrograph of the chip appears in Figure 2. The small size compares very favorably with the state-ofthe-art MOS static RAM cell size. Furthermore, parasitic capacitances are reduced, improving memory performance. The cell has an emitter base capacitance of 0.05 pF, collector base capacitance of 0.09pF and collector substrate capacitance of 0.255pF. The architecture is conventional. A block diagram of the chip is shown in Figure 4. A chip select input is provided for logic flexibility. The read and write operat ics are controlled by the state of the active low write enable, WE. With R7E held low and the chip selected, the data at Din is written into the addressed location To read, WE is held high and the chip selected. Data in the specified location are presented at the data output. ECL design techniques are used throughout the internal circuitry for better speed power product. Design features are shown in Figure 5. Word line discharge circuitry provides fast word line switching. Each bit line current sink is shared by 4 bit line pairs to reduce power. Performance and power allocation of developmental samples manufactured to date are summarized in Table I and Table 11. With typical address access time of around 35 ns, these devices should find application in high performance main memory in addition to the more traditional role of scratch pad memories. Cross section of a typical walled emitter Isoplanar transistor

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4096 × 1静态双极RAM

如图1所示。通过消除发射极基间距，器件尺寸显着减小，导致每个单元的存储单元尺寸仅为3平方密耳，而4K RAM芯片的尺寸为23,650平方密耳。芯片的显微照片如图2所示。小尺寸与最先进的MOS静态RAM单元尺寸相比非常有利。此外，减小了寄生电容，提高了存储性能。该电池的发射极基极电容为0.05 pF，集电极基极电容为0.09pF，集电极衬底电容为0.25 pF。建筑是传统的。芯片的框图如图4所示。芯片选择输入提供了逻辑灵活性。读写操作由活动低写使能WE的状态控制。当R7E保持低位并选择芯片时，Din处的数据被写入地址位置进行读取，WE保持高位并选择芯片。在数据输出中显示指定位置的数据。ECL设计技术在整个内部电路中使用，以获得更好的速度电源产品。设计特性如图5所示。字线放电电路提供快速字线切换。每个位线电流接收器由4位线对共享，以降低功耗。表1和表11总结了迄今为止生产的开发样品的性能和功率分配。由于典型的地址访问时间约为35 ns，这些器件应该在高性能主存储器中找到应用，除了更传统的刮擦板存储器的角色。典型的壁射极等平面晶体管的横截面

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1977 IEEE International Solid-State Circuits Conference. Digest of Technical Papers

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