This repository presents the design of a 10 Bit Potentiometric Digital to Analog Converter with 3.3V analog voltage, 1.8V digital voltage and 1 off-chip external reference using the sky130 technology.The specifications of the design can be found here.
- 1. Introduction
- 2. Pre Layout Simulations
- 3. Observation
- 4. Steps to install the tools and execute the pre layout design
- 5. Layout
- 6. Executing the postlayout design simulations
- 7. Further Work
- 8. Contributors
- 9. Acknowledgements
Most of the signals around us, in the world we live in are not digital in nature, rather they are analog. The digital systems can understand only digital signals, not analog. Hence, it becomes important to interface the digital systems we the external analog world. The analog input signals are to be converted to digital signals using Analog to Digital Converters at the input end of the digital system. After the processing by the system, the digital signals are to be converted back into analog signals using Digital to Analog Converters.
A n-bit Digital to Analog Converter (DAC) takes a n-bit digital word and converts it into a proportional analog voltage with respect to the reference voltage. The potentiometric DAC uses the concept of Voltage Divider. In an N-bit DAC, the analog voltage range, i.e. the Vref (here 3.3 V) is equally divided into 2^N voltage values. This is achieved by a series on 2^N equal resistors and taps are provided across each R. The combination of switches to tap the values is designed using the N-bit digital word as input. An example of N-bit potentiometric DAC is shown in the figure below.
The switches are designed as shown in the figure below. The digital voltage of 1.8V or 0V is given at the digital input port for logic 1 and 0 respectively. If the digital input is logic 1, then Vin1 appears at the output port, else Vin2 appears at the output. Hence this switch circuit replaces two switches in same level as it takes into account both the swiches of complemented and uncomplemented bit.
These designs are used for pre layout simulations.
The block diagram of the required 10bit DAC is as shown below:
Parameter | Description | Min | Type | Max | Unit | Condition |
---|---|---|---|---|---|---|
RL | Load resistance | 50 | Mohm | T=-40 to 85C | ||
CL | Load capacitance | 1 | pF | T=-40 to 85C | ||
VDDA | Analog supply | 3.3 | V | T=-40 to 85C | ||
VDD | Digital supply voltage | 1.8 | V | T=-40 to 85C | ||
VREFH | Reference voltage high | 3.3 | V | T=-40 to 85C | ||
VREFL | Reference voltage low | 0 | V | T=-40 to 85C | ||
RES | Resolution | 10 | bit | T=27C | ||
VFS | Full Scale Voltage | 0 | 3.291627 | V | T=27C |
Name | Pin No. | I/O | Description |
---|---|---|---|
D [0:9] | 1-10 | I | Digital inputs |
EN | 11 | I | Enable pin |
VDD | 12 | I | Digital power supply (1.8) |
VSS | 13 | I | Digital ground |
OUT | 14 | O | DAC analog voltage output |
VDDA | 15 | I | Analog voltage supply (3.3) |
VSSA | 16 | I | Analog ground |
VREFH | 17 | I | Reference voltage high for DAC(3.3) |
VREFL | 18 | I | Reference voltage low for DAC |
The tools used for these simulations are:
- eSim
- ngspice
The schematics for a switch circuit and a 2 bit DAC were designed in eSim. As the analog input voltage was 3.3V, the vdd and vref was set to 3.3V. For the voltage divider circuit, a series of 4 resistors of 250ohm each were used.
The switch circuit mentioned above was designed using eSim. The screenshots of the schematic are as shown below:
The result of transient analysis of the switch is shown below:
The file switchfinal.spice was used. Here, in the spice file, the higher reference voltage was set to 2.5V and the lower reference voltage was set to 2.2V just for the purpose of verifying the circuit. Here it can be observed that when the digital input for the switch is high (1.8V), the higher reference voltage appears at the output; when the digital input for the switch is low(0V), the lower reference voltage appears at the output. So, it was concluded that the switch circuit is working properly.
For the 2 bit DAC, switch circuit was included as a subcircuit. After creating the schematics, the spice netlist was extracted. The necessary model files of sky130 tt transistors were included in the netlist and transient analysis was performed.
The schematic of 2 bit DAC is as shown below:
The result of the transient analysis of the 2bit DAC is shown below:
The spice file 2bitDAC.spice was used. The two bit digital inputs were given as 11, 10, 01 and 00. It can be observed that when the inputs are 1 1, 2.47V appears at the output. When the inputs are 1 0, 1.57 V appears at the output. Similarly, for the inputs 0 1 and 0 0, 0.76V and 0 V appear at output respectively. Thus, the 2 bit digital input is converted to corresponding analog values with reference voltage of 3.3 V.
For the 3 bit DAC, the subcircuits 2bit_DAC.sub and switch.sub were used. The schematic is as shown below:
The result of transient analysis of 3 bit DAC is shown below:
Here, there are 3 digital input bits and hence 8 steps in the analog output.
The subcircuit of 3bit DAC was created which included the 2bit DAC and switch subcircuits.
For the 4 bit DAC, the subcircuits 3bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
The result of the transient analysis of the circuit is shown below:
Here, there are 4 digital input bits and hence 16 steps in the analog output.
The subcircuit of 4 bit DAC was created which included 3bit DAC and switch.
For the 5 bit DAC, the subcircuits 4bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
The result of the transient analysis of the circuit is shown below:
Here, there are 5 digital input bits and hence 32 steps in the analog output.
The subcircuit of 5 bit DAC was created which included 4bit DAC and switch.
For the 6 bit DAC, the subcircuits 5bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
The result of the transient analysis of the circuit is shown below:
Here, there are 6 digital input bits and hence 64 steps in the analog output.
The subcircuit of 6 bit DAC was created which included 5bit DAC and switch.
For the 7 bit DAC, the subcircuits 6bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
The result of the transient analysis of the circuit is shown below:
Here, there are 7 digital input bits and hence 128 steps in the analog output.
The subcircuit of 7 bit DAC was created which included 6bit DAC and switch.
For the 8 bit DAC, the subcircuits 7bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
Here, there are 8 digital input bits and hence 256 steps in the analog output.
The subcircuit of 8 bit DAC was created which included 7bit DAC and switch.
For the 9 bit DAC, the subcircuits 8bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
The transient response of this schematic could not be obtained. The ngspice session got killed.
However, the subcircuit of 9 bit DAC was created which included 8bit DAC and switch.
For the 10 bit DAC, the subcircuits 9bit_DAC.sub and switch.sub were used. The eSim schematic is as shown below:
The transient response of this schematic is as shown below:
It was observed that with increase in the resolution of DAC, the number of steps were increased, the stepsize reduced leading to a smoother step waveform.
- Install the eSim tool using this website. Note: You can also refer to the eSim Spoken Tutorial.
- The subcircuits of lower DACs is present in the subcircuits folder. Copy its contents to the eSim subcircuit library (C:\FOSSEE\eSim\library\SubcircuitLibrary) in order to use the subcircuits in the schematic.
- Clone this repository using the commands:
$ sudo apt install -y git
$ git clone https://github.com/vsdip/avsddac_3v3_sky130_v2.git
-
Change diectory to avsddac_3v3_sky130_v2 by typing
$ cd avsddac_3v3_sky130_v2
-
Got to the respective DAC folder by using the command
$ cd nbit_DAC/
-
To run the schematic, run the command:
$ ngspice <nbit_DAC1.cir.out>
The simulations of higher bit DACs consume more time.
The layout of these circuits is to be drawn in magic using sky130 tech file.
The layout for resistor was drawn as shown below:
The resistance of this resistor was found to be 517.89 ohm.
The layout for switch was drawn as shown below:
The layout for 2bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 3bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 4bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 5bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 6bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 7bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 8bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 9bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
The layout for 10bit DAC was drawn as shown below:
The spice file was extracted and the output was observed as shown below:
- Clone this repository using the commands:
$ sudo apt install -y git
$ git clone https://github.com/vsdip/avsddac_3v3_sky130_v2.git
-
Change directory to avsddac_3v3_sky130_v2 by typing
$ cd avsddac_3v3_sky130_v2/
-
Go to the Post Layout Simulation folder by using the command
$ cd Post\ Layout\ Simulation/
-
Run the command
$ git clone https://foss-eda-tools.googlesource.com/skywater-pdk/libs/sky130_fd_pr
to download the sky130_fd_pr folder. -
Then, to run the spice file, run the command:
$ ngspice <nbit_DAC.spice>
The simulations of higher bit DACs consume more time.
Further work would be to obtain the simulatios of 9 bit DAC and 10 bit DAC and calculate INL and DNL for 10 bit DAC.
- Sameer S Durgoji , B.Tech (Electronics and Communication Engineering), National Institute of Technology Karnataka - [email protected]
- Kunal Ghosh, Co-Founder of VLSI System Design (VSD) Corp. Pvt. Ltd. - [email protected]
- Kunal Ghosh, Co-Founder of VLSI System Design (VSD) Corp. Pvt. Ltd. - [email protected]