Doing Projects in 1crore Project Centre is useful for the Engineering Final Year students as it provides knowledge about their topics. We do VLSI Projects in our 1crore Project Centre.

Projects in VLSI based system design are the projects which involve the design of various types of digital systems that can be implemented on a PLD device like a FPGA or a CPLD. The projects which deal with the semiconductor design are called as Projects in VLSI design. These are very difficult and expensive to implement in real time.

So far we 1crore Project Centre, have finished doing projects for more than 10,000 Engineering students. And we have experience in doing the Projects for 9 + years. The majority of our Projects are recognized by the companies which are needed as per their requirements

We endeavour for perfection and provide high quality solutions in this domain. Multi-platform Training will be gained by the students through Real time experience when you get the project done by 1crore project centre. Most of our Projects are identified by the industries which are suitable for their needs.

Our Faculties have 6+ years well versed experienced in this field and they are very flexible to the students in explaining them their projects until the student understand their concepts.

While we, 1crore project commits the Project, you will receive an Abstract and base paper, documentation, and while getting project delivered, source code, explanation and software installation / Hardware installation done for you.

We will deliver your project in on-time after completion. We 1crore Project Centre will give you Project Acceptance Letter, Project Attendance letter and Technology Learning certificate. The students will receive Project Completion Experience Certificate.

Our faculties at 1crore Project Centre will give you excellent support throughout your project done.

Call / Mail / SMS your requirements, or directly visit our office with your friends for more queries.

So get the knowledge availability from our 1crore Project Centre and use it in your project works.

Our bond with our engineering students is been around for many years build on mutual trust, respect and benefiting the student career.


  • A Modified Partial Product Generator for Redundant Binary Multipliers.
  •   An Efficient Hardware Implementation of Canny Edge Detection Algorithm.
  •   Approximate Radix-8 Booth Multipliers for Low-Power and High-Performance Operation.
  •   A High-Performance FIR Filter Architecture for Fixed and Reconfigurable Applications.
  •   The Serial Commutator (SC) FFT.
  •   An Improved Signed Digit Representation Approach for Constant Vector Multiplication.
  •   High-Speed and Energy-Efficient Carry Skip Adder Operating Under a Wide Range of Supply Voltage Levels.
  •   A New XOR-Free Approach for Implementation of Convolutional Encoder.
  •   Energy and Area Efficient three-input XOR/XNORs With Systematic Cell Design Methodology.
  •   Approximate Radix-8 Booth Multipliers for Low-Power and High-Performance Operation.
  •   Implementation of a PID control PWM Module on FPGA.
  •   Built-in Self Testing of FPGAs.
  •   An FPGA-Based Cloud System for Massive ECG Data Analysis.
  •   Distributed Sensor Network-on-Chip for Performance Optimization of Soft-Error-Tolerant Multiprocessor System-on-Chip.
  •   VLSI Implementation of Fully Parallel LTE Turbo Decoders.
  •   A High Throughput List Decoder Architecture For Polar Codes.
  •   High-Performance NB-LDPC Decoder With Reduction of Message Exchange.
  •   A High-Speed FPGA Implementation of an RSD-Based ECC Processor.
  •   Low-Power ECG-Based Processor for predicting Ventricular Arrhythmia.
  •   In-Field Test for Permanent Faults in FIFO Buffers of NoC Routers.
  •   Configurable Parallel Hardware Architecture for efficient Integral Histogram Image Computing.
  •   Input-Based Dynamic Reconfiguration of Approximate Arithmetic Units for Video Encoding.
  •   A Normal I/O Order Radix-2 FFT Architecture to ProcessTwin Data Streams for MIMO.
  •   Unequal-Error-Protection Error Correction Codes for the Embedded Memories in Digital Signal Processors.
  •   A High-Performance FIR Filter Architecture forFixed and Reconfigurable Applications.
  •   Hybrid LUT/Multiplexer FPGA Logic Architectures.
  •   A Dynamically Reconfigurable Multi-ASIP Architecture for multistandard and Multimode Turbo Decoding.
  •   Low-Power Split-Radix FFT Processors Using Radix-2 Butterfly Units.
  •   A Fully Digital Front-End Architecture for ECGAcquisition System With 0.5 V Supply.
  •   A Low-cost and Modular Receiver for MIMO SDR.
  •   High-Speed, Low-Power, and Highly Reliable Frequency Multiplier for DLL-Based Clock Generator.
  •   Frequency-Boost Jitter Reduction for Voltage-Controlled Ring Oscillators.
  •   Low-Energy Power-ON-Reset Circuit for Dual Supply SRAM.
  •   Low-Power Variation-Tolerant Nonvolatile Lookup Table Design.
  •   A Low-Power Robust Easily CascadedPentaMTJ-Based Combinational and Sequential Circuits.
  •   A 0.1–3.5-GHz Duty-Cycle Measurement and Correction Technique in 130-nm CMOS.
  •   Full-Swing Local Bitline SRAM ArchitectureBased on the 22-nm FinFET Technology for Low-Voltage Operation.
  •   A Robust Energy/Area-Efficient Forwarded-ClockReceiver With All-Digital Clock and Data Recovery in 28-nm CMOS for High-Density Interconnects.
  •   OTA-Based Logarithmic Circuit for ArbitraryInput Signal and Its Application.
  •   A Single-Ended With Dynamic Feedback Control8T Subthreshold SRAM Cell.
  •   Graph-Based Transistor Network GenerationMethod for Supergate Design.
  •   Implementing Minimum-Energy-Point SystemsWith Adaptive Logic.
  •   A 0.52/1 V Fast Lock-in ADPLL for Supporting DynamicVoltage and Frequency Scaling.