Phase Locked Loop Circuits

Transistor Technologies for High Efficiency and Linearity

Differential Topology • Double the available voltage swing • Even-order harmonic suppression • Double the frequency of current injection into substrate –Reduce the potential for LO-pulling • The tail current source is removed from the standard differential pair (this is a “quasi-differential” structure) –DC current set by the biasing of input devices

ADS Tutorial Stability and Gain Circles ECE145A/218A

equations. The syntax is: gp_circle(S, gain, # points on circle) where S is the S-parameter matrix. Let’s illustrate. In the example below, a table is used to display frequency, maximum stable gain (MSG), the stability factor, k, and the magnitude of delta. The gain circles are at MSG (MaxGain1 in this case), and 1 and 2 dB below MSG.

  Stability, Gain, Tutorials, Circle, Tutorial stability and gain circles ece145a, Ece145a, Gain circles

Audio Amplifier Circuit - UC Santa Barbara

Week #1: Audio amplifier Week #2: Microphone circuit The audio amplifier project is more difficult and time-consuming than the microphone pre-amp, so part of week #2 may be used to finish the audio amp. All breadboarding and testing can and should be done in lab. Soldering and hardwiring can and should be done outside lab.

  Audio

Harmonic Balance Simulation on ADS

Harmonic Balance Simulation on ADS General Description of Harmonic Balance in Agilent ADS 1 Harmonic balance is a frequency-domain analysis technique for simulating nonlinear circuits and systems. It is well-suited for simulating analog RF and microwave circuits, ... function is driven to a given small value), then the resulting voltage ...

  Simulation, Driven

Quality factor, Q

When a resonant circuit is connected to the outside world, its total losses (let’s call them RP or GP) are combined with the source and load resistances, RS and RL. For example, Here is a parallel resonant circuit (C,L and RP)connected to the outside. The total Q of this circuit is called the loaded Q or QL and is given by

  Parallel, Resonant, Parallel resonant

Latches, the D Flip-Flop & Counter Design

February 6, 2012 ECE 152A - Digital Design Principles 2 Reading Assignment Brown and Vranesic 7Flip-Flops, Registers, Counters and a Simple Processor 7.1 Basic Latch 7.2 Gated SR Latch 7.2.1 Gated SR Latch with NAND Gates 7.3 Gated D …

  Latch, Sr latch

Flip-Flops and Sequential Circuit Design

11 Latches and Flip-Flops 11.5 S-R Flip-Flop 11.6 J-K Flip-Flop 11.7 T Flip-Flop 11.8 Flip-Flops with Additional Inputs 11.9 Summary 12 Registers and Counters 12.5 Counter Design Using S-R and J-K Flip-Flops 12.6 Derivation of Flip-Flop Input Equations – Summary

  Flip, Flops, Latches, Latches and flip

BASICS OF THE SPECTRUM ANALYZER - UC Santa Barbara

Fourier ⋅ π → − + + Now instead of a bank of narrow filters, we shall have one narrow filter centered at a fixed frequency, say fI, and we shall scan the signal spectrum across this filter by multiplying x(t) by a sinusoid of varying frequency f0. See Figure 1. …

  Basics, Spectrum, Analyzer, Fourier, Spectrum analyzer

Mealy and Moore Machines

February 22, 2012 ECE 152A - Digital Design Principles 5 Finite State Machines Two types (or models) of sequential circuits (or finite state machines) Mealy machine Output is function of present state and present input Moore machine Output is function of present state only Analysis first, then proceed to the design of

  States, Design, Machine, Finite, Finite state

Number Representation and Computer Arithmetic

One way to encode decimal digits using binary signals is to encode each of the digits 0-9 by means of its 4-bit binary representation. The resulting binary-coded decimal (BCD) representation is shown below:

  Medical, Coded, Binary, Arithmetic, Binary coded decimal

ECE 546 Lecture 28 High Speed Links

frequency due to large phase‐noise + jitter. 4. Can only accept digital signals. 1.High‐power, not integrable. 2. Occupieslarge die‐area. 3. Greatphase‐noise and jitter performance at high frequency. 4. Can acceptanalog and digital signals. Ring v/s Tank Architecture

  Lecture, Frequency, Ece 546 lecture

Single chip 2.4 GHz Transceiver nRF24L01

The transceiver consists of a fully integrated frequency synthesizer, a power amplifier, a crystal oscillator, a demodulator, modulator and Enhanced ShockBurst™ protocol engine. Output power, frequency channels, and protocol setup are easily programmable through a SPI interface. Current consumption is very low, only 9.0mA

  Frequency, Synthesizer, Nrf24l01, Frequency synthesizer

3.5 GSPS Direct Digital Synthesizer with 12-Bit DAC Data ...

The AD9914 is a direct digital synthesizer (DDS) featuring a 12-bit DAC. The AD9914 uses advanced DDS technology, coupled with an internal high speed, high performance DAC to form a digitally programmable, complete high frequency synthesizer capable of generating a frequency-agile analog output sinusoidal waveform at up to 1.4 GHz.

  Frequency, Synthesizer, Frequency synthesizer

Direct Modulation/Fast Waveform Generating, 13 GHz ...

ADF4159 is a 13 GHz, fractional-N frequency synthesizer with modulation and both fast and slow waveform generation capability. The part uses a 25-bit fixed modulus, allowing sub hertz frequency resolution. The . ADF4159. consists of a low noise digital phase frequency detector (PFD), a precision charge pump, and a programmable reference divider.

  Frequency, Synthesizer, Frequency synthesizer