Exp.1: Linear Variable Differential Transformer (LVDT) Transducers
... Record your readings in the third column in your table. Record the position where the output voltage is zero. Using your results, plot a graph of output against position for the whole range of movement. Draw it on the same graph you did the ac graph. We are going to perform the same operations on it ...
... Record your readings in the third column in your table. Record the position where the output voltage is zero. Using your results, plot a graph of output against position for the whole range of movement. Draw it on the same graph you did the ac graph. We are going to perform the same operations on it ...
An Integrated Subharmonic Coupled-Oscillator Scheme for a 60-GHz Phased-Array Transmitter
... chip with antennas. In [5], array scalability originally motivated investigation into a coupled-oscillator topology. This paper expands on the design details of the coupled-oscillator array by describing the interconnect structure for subharmonic injection locking, as well as the circuit implementat ...
... chip with antennas. In [5], array scalability originally motivated investigation into a coupled-oscillator topology. This paper expands on the design details of the coupled-oscillator array by describing the interconnect structure for subharmonic injection locking, as well as the circuit implementat ...
MAX2059 - Maxim Integrated
... Operating Temperature Range (Note A) .............-40°C to +85°C Junction Temperature ......................................................+150°C θJC ....................................................................................10°C/W θJA ...................................................... ...
... Operating Temperature Range (Note A) .............-40°C to +85°C Junction Temperature ......................................................+150°C θJC ....................................................................................10°C/W θJA ...................................................... ...
FEATURES BASIC BLOCK DIAGRAM
... The PLL translates the R-divider output to a frequency within the operating range of the VCO (3.35 GHz to 4.05 GHz) based on the value of the feedback divider (N). The VCO prescaler (P0) reduces the VCO output frequency by an integer factor from 5 to 11, resulting in an intermediate frequency in the ...
... The PLL translates the R-divider output to a frequency within the operating range of the VCO (3.35 GHz to 4.05 GHz) based on the value of the feedback divider (N). The VCO prescaler (P0) reduces the VCO output frequency by an integer factor from 5 to 11, resulting in an intermediate frequency in the ...
Resonant LLC Converter: Operation and Design
... Ratio of total primary inductance to resonant inductance ...
... Ratio of total primary inductance to resonant inductance ...
DS4M125/DS4M133/DS4M200 3.3V Margining Clock Oscillator with LVPECL/LVDS Output General Description
... oscillators with LVPECL or LVDS outputs. They are designed to fit in a 5mm x 3.2mm ceramic package with an AT-cut fundamental-mode crystal to form a complete clock oscillator. The circuit can generate the following frequencies and their ±5% frequency deviations: 125MHz, 133.33MHz, and 200MHz. The DS ...
... oscillators with LVPECL or LVDS outputs. They are designed to fit in a 5mm x 3.2mm ceramic package with an AT-cut fundamental-mode crystal to form a complete clock oscillator. The circuit can generate the following frequencies and their ±5% frequency deviations: 125MHz, 133.33MHz, and 200MHz. The DS ...
unit-2: dc motor
... 11. Briefly explain the significance of chording and distribution factors. Develop the emf 12. Equation for a synchronous generator having fractional pitch and distributed windings. 13. Explain the methods adopted to eliminate harmonics in the voltage in an alternator 14. A 3Φ, 50 Hz, star connected ...
... 11. Briefly explain the significance of chording and distribution factors. Develop the emf 12. Equation for a synchronous generator having fractional pitch and distributed windings. 13. Explain the methods adopted to eliminate harmonics in the voltage in an alternator 14. A 3Φ, 50 Hz, star connected ...
A 24-GHz CMOS Passive Subharmonic Mixer/Downconverter for Zero-IF Applications , Member, IEEE
... In use as a direct-conversion mixer, the second-order intermodulation intercept point (IIP2) plays an important role. Ideally, in a completely balanced mixer, the second-order nonlinearities are common mode and cancel out when measured differentially. However, mismatches in the component values can ...
... In use as a direct-conversion mixer, the second-order intermodulation intercept point (IIP2) plays an important role. Ideally, in a completely balanced mixer, the second-order nonlinearities are common mode and cancel out when measured differentially. However, mismatches in the component values can ...
A 60-GHz Superheterodyne Downconversion Mixer in Silicon
... a single-balanced Gilbert mixer intended for use in a superheterodyne receiver with an RF input of 57–64 GHz and a variable IF in the range of 8.3–9.1 GHz, as shown in the simplified schematic of Fig. 1. This is one of the first reports of silicon-based active mixers at this frequency. Earlier, we r ...
... a single-balanced Gilbert mixer intended for use in a superheterodyne receiver with an RF input of 57–64 GHz and a variable IF in the range of 8.3–9.1 GHz, as shown in the simplified schematic of Fig. 1. This is one of the first reports of silicon-based active mixers at this frequency. Earlier, we r ...
The following should be included in your experimental checklist
... The output of this circuit is the derivative of the input INVERTED and multiplied by RC. For a sinusoidal input, the magnitude of the gain for this circuit depends on the values of the components and also the input frequency. It is equal to (RC). The circuit will also cause a phase shift of -90. I ...
... The output of this circuit is the derivative of the input INVERTED and multiplied by RC. For a sinusoidal input, the magnitude of the gain for this circuit depends on the values of the components and also the input frequency. It is equal to (RC). The circuit will also cause a phase shift of -90. I ...
Bode plot
In electrical engineering and control theory, a Bode plot /ˈboʊdi/ is a graph of the frequency response of a system. It is usually a combination of a Bode magnitude plot, expressing the magnitude of the frequency response, and a Bode phase plot, expressing the phase shift. Both quantities are plotted against a horizontal axis proportional to the logarithm of frequency.