Reference no: EM131957358

Assignment -

Aim: Design a two-stage inverter circuit shown in Fig.1. The work will initially involve calculating respective dimensions of the different devices within the circuit (i.e. A, B, C and R_L), using appropriate equations and parameters/constants provided below. Subsequently, respective layouts for each of the devices, and the overall circuit including interconnects and contact pads, needs to be generated accurately, on scaled or graph paper/s with stipulated scale (e.g. 1µm = 1cm). Make sure to accurately include the alignment error between layouts and utilise minimal area by arranging the layouts appropriately. All dimensions and areas of the layouts must be expressed in terms of the minimum feature size given below.

Description: The circuit in Fig. 1 consists of a two-stage inverter, where the intermediated output from the 1^st inverter V_o' feds into the input gate of the 2^nd inverter. The input and output of this circuit is V_in and V_out respectively. The driver of both of the inverters consists of enhancement type n-MOS transistors A and B. It can assume that these transistors have the same aspect ratio (W/L), and threshold voltage of 0.3 V.

The load device of the 1^st inverter is an (active) saturated n-MOS transistor C, whilst the 2^nd inverter has a (passive) implanted resistor load R_L. Note the resistance of C can be assumed to be equal to that of R_L, and similarly, the resistance of A is identical to the resistance of B, when the transistors are on. However note the dimension of C is not the same as R_L since they are different devices. Refer to the p-n junction (passive load) notes to work out dimensions for R_L, assuming a sheet resistance for the technology given below.

And to assist you with the calculation for the transistor dimensions, assume a logic 1 input to A, and thus select appropriate value for the intermediate output voltage V_o', to correspond to logic 0. Note this value of V_o' for logic0 needs to be lower than threshold voltage of the driver B so as to ensure that the transistor remains off at logic 0.

Note for the layouts you must take into account the alignment accuracy λ_a, which can also be assumed to be equal to the minimum feature size or multiple of it. Below are respective parameter values to be used in the calculation:

i. Minimum feature size λ_m = 0.5 µm

ii. Supply voltage V_DD = 5V (Logic 1 input)

iii. Threshold voltage of transistors, V_T = 0.3 V

iv. Sheet resistance 150 Ω/square

v. Device constant is given as below; note mobility μ and gate capacitance C_o can be assumed to be the same for all transistors.

β = (μC_o) W/L = (β_o)W/L, where β_o = 1.8 x 10^-4 AV^-2.

Report: Provide a brief description of the circuit operation in Fig. 1. Include all calculations and justification to any assumptions made. Represent all respective individual design layouts for A, B, C and R_L, and the overall layout on scaled graph papers, and in terms of the minimum feature size. Use different shading to indicate different regions and include appropriate alignment errors between respective layouts. Make sure to utilise the area effectively particularly on the overall layout where the interconnects and contact pads need to be included.

Useful hints:

1. Initially focus on the first inverter and assume a logic 1 input. Note load C is always on and saturated, whilst with a logic 1 input to the driver A, this transistor is also on, and thus the current flowing between the two devices will be the same. Consequently, using appropriate drain current expressions for the two transistors, determine the ratio of the aspect ratios of the driver to the load. You will need to select appropriate values, ensuring the same ratio is maintained.

2. The resistance values for the two loads are the same i.e. R_C = R_L. To determine their dimensions i.e. L and W, of the implanted resistor RL, use the given the sheet resistance and consequently calculate the number of squares required.