Evaluates: MAX1832–MAX1835 MAX1833 Evaluation Kit General Description Features
... MAX1833 high-efficiency, step-up DC-DC converter for portable hand-held devices. The EV kit accepts a positive input voltage between 1.5V to VOUT and converts it to a 3.3V output for currents up to 150mA. The EV kit provides ultra-low quiescent current and high efficiency for maximum battery life. T ...
... MAX1833 high-efficiency, step-up DC-DC converter for portable hand-held devices. The EV kit accepts a positive input voltage between 1.5V to VOUT and converts it to a 3.3V output for currents up to 150mA. The EV kit provides ultra-low quiescent current and high efficiency for maximum battery life. T ...
Introduction - facstaff.bucknell.edu
... Many electronic devices and systems require a source of pulses, often called a “clock signal,” for proper operation. One example is the clock circuit found in all computers that controls the timing of the digital signals within the CPU. Another is the signal generator on your lab bench. The waveform ...
... Many electronic devices and systems require a source of pulses, often called a “clock signal,” for proper operation. One example is the clock circuit found in all computers that controls the timing of the digital signals within the CPU. Another is the signal generator on your lab bench. The waveform ...
VIPer100 - Hobbielektronika.hu
... wide voltage range input off-line single switch Flyback, working at 100kHz and allows the user to choose between primary and secondary regulation. Primary regulation is carried out by the auxiliary winding which delivers the low level supply voltage on the Vdd pin of the device. Secondary regulation ...
... wide voltage range input off-line single switch Flyback, working at 100kHz and allows the user to choose between primary and secondary regulation. Primary regulation is carried out by the auxiliary winding which delivers the low level supply voltage on the Vdd pin of the device. Secondary regulation ...
High Frequency Amplifier Evaluation Board
... C5, C8, and C10 should be 10nF disc ceramics with a selfresonant frequency greater than 10MHz. The polarized capacitors (C2, C4, C7, and C9) should be 1µF to 10µF tantalums. Most 10nF ceramics are self-resonant well above 10MHz, and 4.7µF solid tantalums (axial leaded) are self-resonant at 1MHz or b ...
... C5, C8, and C10 should be 10nF disc ceramics with a selfresonant frequency greater than 10MHz. The polarized capacitors (C2, C4, C7, and C9) should be 1µF to 10µF tantalums. Most 10nF ceramics are self-resonant well above 10MHz, and 4.7µF solid tantalums (axial leaded) are self-resonant at 1MHz or b ...
... since I VR R . Since I is maximized, the magnitude of both VC and VL are individually at maximum, although 180o out of phase with each other. When the frequency is not near the resonant frequency, the phasors representing VC, and VL do not cancel, so VR is less for a given Vs. It is convenient to ...
... square wave appear to be in phase, i.e. both are high in the same part of the cycle. This is not the true relationship, as observed in part a). Since we are triggering on channel 1, both wave forms have a positive slope at the trigger point. Notice that the 1-volt signal in channel 2 is displayed in ...
74VHCT574A Octal D-Type Flip-Flop with 3-STATE Outputs 7 4
... CMOS technology. It achieves the high speed operation similar to equivalent Bipolar Schottky TTL while maintaining the CMOS low power dissipation. This 8-bit D-type flipflop is controlled by a clock input (CP) and an Output Enable input (OE). When the OE input is HIGH, the eight outputs are in a hig ...
... CMOS technology. It achieves the high speed operation similar to equivalent Bipolar Schottky TTL while maintaining the CMOS low power dissipation. This 8-bit D-type flipflop is controlled by a clock input (CP) and an Output Enable input (OE). When the OE input is HIGH, the eight outputs are in a hig ...
FIN1031 3.3V LVDS 4-Bit High Speed Differential Driver FI N1031
... utilizing Low Voltage Differential Signaling (LVDS) technology. The driver translates LVTTL signal levels to LVDS levels with a typical differential output swing of 350mV which provides low EMI at ultra low power dissipation even at high frequencies. This device is ideal for high speed transfer of c ...
... utilizing Low Voltage Differential Signaling (LVDS) technology. The driver translates LVTTL signal levels to LVDS levels with a typical differential output swing of 350mV which provides low EMI at ultra low power dissipation even at high frequencies. This device is ideal for high speed transfer of c ...
L6376
... Once the UV signal has been removed, the supply voltage must decrease below the lower threshold (i.e. Vsth-Vshys) before it is turned on again. The hysteresis Vshys is provided to prevent intermittent operation of the device at low supply voltages that may have a superimposed ripple around the avera ...
... Once the UV signal has been removed, the supply voltage must decrease below the lower threshold (i.e. Vsth-Vshys) before it is turned on again. The hysteresis Vshys is provided to prevent intermittent operation of the device at low supply voltages that may have a superimposed ripple around the avera ...
UML1N
... No technical content pages of this document may be reproduced in any form or transmitted by any means without prior permission of ROHM CO.,LTD. The contents described herein are subject to change without notice. The specifications for the product described in this document are for reference only. Up ...
... No technical content pages of this document may be reproduced in any form or transmitted by any means without prior permission of ROHM CO.,LTD. The contents described herein are subject to change without notice. The specifications for the product described in this document are for reference only. Up ...
Current Transducer LTSR 6-NP I = 6 At
... impedance = 600 W. For most applications you need to buffer this output to feed it into an ADC for example. 4) To overdrive the REF (1.9 V .. 2.7 V) max ± 1 mA is needed. 5) IS = IP/NS. 6) Only due to TCR IM. ...
... impedance = 600 W. For most applications you need to buffer this output to feed it into an ADC for example. 4) To overdrive the REF (1.9 V .. 2.7 V) max ± 1 mA is needed. 5) IS = IP/NS. 6) Only due to TCR IM. ...
Phys 345 Electronics for Scientists
... 4. Keep burning as brightly as it did before the switch was opened 5. Flare up brightly, then dim and go out ...
... 4. Keep burning as brightly as it did before the switch was opened 5. Flare up brightly, then dim and go out ...
Lab #1: Ohm’s Law (and not Ohm’s Law)
... waveform generator is 2 ohms. (50+-2) • C-1 at low frequency, wave form can be ugly. Measure to the average over the “features”. So, need to use cursors, not “measure” • C-1 don’t assume V0 does not change, monitor it and check that it does not change • C-1 note phase shift changes sign. ...
... waveform generator is 2 ohms. (50+-2) • C-1 at low frequency, wave form can be ugly. Measure to the average over the “features”. So, need to use cursors, not “measure” • C-1 don’t assume V0 does not change, monitor it and check that it does not change • C-1 note phase shift changes sign. ...
LTSR 15-NP
... impedance = 600 W. For most applications you need to buffer this output to feed it into an ADC for example. 4) To overdrive the REF (1.9 V .. 2.7 V) max ± 1 mA is needed. 5) IS = IP/NS. 6) Only due to TCR IM. ...
... impedance = 600 W. For most applications you need to buffer this output to feed it into an ADC for example. 4) To overdrive the REF (1.9 V .. 2.7 V) max ± 1 mA is needed. 5) IS = IP/NS. 6) Only due to TCR IM. ...
Dynamic Volt-Amp Reactive (D-VAR®) Compensation
... D-VAR systems stabilize and regulate voltage and power factor on T&D networks and at industrial operations. The system detects and rapidly compensates for voltage disturbances by injecting leading or lagging reactive power at key points on transmission and distribution grids. Each D-VAR solution is ...
... D-VAR systems stabilize and regulate voltage and power factor on T&D networks and at industrial operations. The system detects and rapidly compensates for voltage disturbances by injecting leading or lagging reactive power at key points on transmission and distribution grids. Each D-VAR solution is ...
R4905103107
... Design of a Sample and Hold Circuit using Rail to Rail Low Voltage Compact Operational Amplifier and bootstrap Switching Annu Saini , Prity Yadav (M.Tech. Student, Department of Electronics, JSS academy of Technical ...
... Design of a Sample and Hold Circuit using Rail to Rail Low Voltage Compact Operational Amplifier and bootstrap Switching Annu Saini , Prity Yadav (M.Tech. Student, Department of Electronics, JSS academy of Technical ...
Schmitt trigger
In electronics a Schmitt trigger is a comparator circuit with hysteresis implemented by applying positive feedback to the noninverting input of a comparator or differential amplifier. It is an active circuit which converts an analog input signal to a digital output signal. The circuit is named a ""trigger"" because the output retains its value until the input changes sufficiently to trigger a change. In the non-inverting configuration, when the input is higher than a chosen threshold, the output is high. When the input is below a different (lower) chosen threshold the output is low, and when the input is between the two levels the output retains its value. This dual threshold action is called hysteresis and implies that the Schmitt trigger possesses memory and can act as a bistable multivibrator (latch or flip-flop). There is a close relation between the two kinds of circuits: a Schmitt trigger can be converted into a latch and a latch can be converted into a Schmitt trigger.Schmitt trigger devices are typically used in signal conditioning applications to remove noise from signals used in digital circuits, particularly mechanical contact bounce. They are also used in closed loop negative feedback configurations to implement relaxation oscillators, used in function generators and switching power supplies.