Presentation is loading. Please wait.

Presentation is loading. Please wait.

Time Domain Circuits. Passive Filters GND V out R V in C C(dVout/dt) = (V in – V out ) / R  (dV out /dt) = (Vin – Vout)  = R * C Equate currents: GND.

Published byLizbeth Sherman Modified over 8 years ago

Similar presentations

Presentation on theme: "Time Domain Circuits. Passive Filters GND V out R V in C C(dVout/dt) = (V in – V out ) / R  (dV out /dt) = (Vin – Vout)  = R * C Equate currents: GND."— Presentation transcript:

1 Time Domain Circuits

2 Passive Filters GND V out R V in C C(dVout/dt) = (V in – V out ) / R  (dV out /dt) = (Vin – Vout)  = R * C Equate currents: GND V out C V in R C ( d(Vin – Vout)/dt) = Vout/R  (d(Vin – Vout)/dt) = Vout

3 Response of a linear system Behavior is independent of boundary conditions Boundary conditions only scale the result (double the input, double the output) Impulse response of a low-pass filter V = V(0)exp( -t /  ) V=(1)exp( -t/  ) V = (e -1 )exp( -t/  ) V = (e -2 )exp( -t/  )

4 Analysis of Diff-Pair

5 Basic Differential Amplifier

6 Transfer Functions

7 A Unity-Gain Follower

8

9 Amp Gain = A v Solving: V out = V in AvAv 1 + A v

10 A Unity-Gain Follower Amp Gain = A v Solving: V out ~ V in

11 A Unity-Gain Follower Amp Gain = A v Solving: V out ~ V in

12 A Low-Pass Filter C (dV out /dt) = I bias (  ) (Vin - Vout) /(2 UT) I bias tanh(  (Vin - Vout)/(2 UT) )

13 A Low-Pass Filter Time-constant changes with bias  = C U T /  I bias  (dV out /dt) + V out = V in C (dV out /dt) = I bias (  ) (Vin - Vout) /(2 UT)

14 C (dV out /dt) = I bias tanh(  (V in - V out )/(2 U T ) ) This is not linear…. “Small-signal analysis: How small is “small”? A Low-Pass Filter |V in - V out | < 2U T

15 Follower Integrator ( Simplest Gm-C Filter) I V out V in C1C1 GND dV out (t) dt By KCL: G m (V in - V out ) = C 1 Defining  = C 1 / G m dV out (t) dt V in = V out +  We can set Gm and build C sufficiently big enough (slow down the amplifier), or set by C (smallest size to get enough SNR), and change Gm. If an ideal op-amp, then V in = V out U T / k I bias

16 C (dV out /dt) = I bias tanh(  (V in - V out )/(2 U T ) ) This is not linear…. “Small-signal analysis: How small is “small”? A Low-Pass Filter |V in - V out | < 2U T |V in - V out | > 10U T tanh(X) = +/- 1

17 A Low-Pass Filter C (dV out /dt) =I bias I bias tanh(  (Vin - Vout)/(2 UT) ) Slew-Rate changes with bias Slew Rate = C / I bias (dV out /dt) = 1 / 

18 Tuning Frequency using Bias Current Bias CurrentTransconductanceCutoff Frequency 1mA 1/250  600MHz 1A1A1/25k  6MHz 1nA 1/25M  6kHz 1pA 1/25G  6Hz This approach is the most power-efficient approach for any filter. All electronically tunable: Advantage: we can electronically change the corner Disadvantage: we need a method to set this frequency (tuning) C = 1pF, W/L of input transistors = 30, I th ~ 10  A.

19 Comparing Low-Pass Filters GND V out R V in C Linear Filtering Requires no additional power Transistor Capacitor design Time-constant is electrically tunable No input current load

Download ppt "Time Domain Circuits. Passive Filters GND V out R V in C C(dVout/dt) = (V in – V out ) / R  (dV out /dt) = (Vin – Vout)  = R * C Equate currents: GND."

Similar presentations

Lecture 4 Operational Amplifiers—Non-ideal behavior

Lecture 4 Operational Amplifiers—Non-ideal behavior
Op-Amp Based Band Pass Filter. Equivalent DC (DC feedback)

Op-Amp Based Band Pass Filter. Equivalent DC (DC feedback)
1 Electronic Circuits OP AMPs. 2 Electronic Circuits Operational amplifiers are convenient building blocks that can be used to build amplifiers and filters.

1 Electronic Circuits OP AMPs. 2 Electronic Circuits Operational amplifiers are convenient building blocks that can be used to build amplifiers and filters.
Op-Amp- An active circuit element designed to perform mathematical operations of addition, subtraction, multiplication, division, differentiation and.

Op-Amp- An active circuit element designed to perform mathematical operations of addition, subtraction, multiplication, division, differentiation and.
Feedback Section 8.1. Topics General Feedback Examples of Feedback Circuits – Bandwidth Extension – Gain Sensitivity – Input and Output Impedance Types.

Feedback Section 8.1. Topics General Feedback Examples of Feedback Circuits – Bandwidth Extension – Gain Sensitivity – Input and Output Impedance Types.
Linearized MOSFET Resistors

Linearized MOSFET Resistors
APPENDIX B SPICE DEVICE MODELS AND DESIGN SIMULATION EXAMPLES USING PSPICE AND MULTISIM Microelectronic Circuits, Sixth Edition Sedra/Smith.

APPENDIX B SPICE DEVICE MODELS AND DESIGN SIMULATION EXAMPLES USING PSPICE AND MULTISIM Microelectronic Circuits, Sixth Edition Sedra/Smith.
3441 Industrial Instruments 1 Chapter 2 Analog Signal Conditioning

3441 Industrial Instruments 1 Chapter 2 Analog Signal Conditioning
Pnp transistor ECE Electronics - Dr. S. Kozaitis- Florida Institute of Technology – Fall 2002.

Pnp transistor ECE Electronics - Dr. S. Kozaitis- Florida Institute of Technology – Fall 2002.
Operational amplifier

Operational amplifier
1 Dr. Un-ki Yang Particle Physics Group or Shuster 5.15 Amplifiers and Feedback 1.

1 Dr. Un-ki Yang Particle Physics Group or Shuster 5.15 Amplifiers and Feedback 1.
Topic 3: Op-Amp: Golden Rules of OP Amp 1.i in =0, no current flow into op amp. 2.V + =V - Typically one end of op amp is connected to ground, therefore,

Topic 3: Op-Amp: Golden Rules of OP Amp 1.i in =0, no current flow into op amp. 2.V + =V - Typically one end of op amp is connected to ground, therefore,
Lecture 91 Loop Analysis (3.2) Circuits with Op-Amps (3.3) Prof. Phillips February 19, 2003.

Lecture 91 Loop Analysis (3.2) Circuits with Op-Amps (3.3) Prof. Phillips February 19, 2003.
Lecture 20: Frequency Response: Miller Effect

Lecture 20: Frequency Response: Miller Effect
Summer, 2003 Dr. H. Kaufman Consider the inverter shown in the Figure. A capacitor C = 10pF is connected between the output and ground. Let V DD = 5V,

Summer, 2003 Dr. H. Kaufman Consider the inverter shown in the Figure. A capacitor C = 10pF is connected between the output and ground. Let V DD = 5V,
Operational Amplifiers

Operational Amplifiers
A CMOS Low Power Current-Mode Polyphase Filter By Hussain Alzaher & Noman Tasadduq King Fahd University of Petroleum & Minerals KFUPM, Department of Electrical.

A CMOS Low Power Current-Mode Polyphase Filter By Hussain Alzaher & Noman Tasadduq King Fahd University of Petroleum & Minerals KFUPM, Department of Electrical.
Operational Amplifiers (Op Amps) Discussion D3.1.

Operational Amplifiers (Op Amps) Discussion D3.1.
Lecture 241 Circuits with Dependent Sources Strategy: Apply KVL and KCL, treating dependent source(s) as independent sources. Determine the relationship.

Lecture 241 Circuits with Dependent Sources Strategy: Apply KVL and KCL, treating dependent source(s) as independent sources. Determine the relationship.
Prof. Yasser Mostafa Kadah – www.k-space.org BASIC ELECTRONICS PART 4: OPERATIONAL AMPLIFIER.

Prof. Yasser Mostafa Kadah – BASIC ELECTRONICS PART 4: OPERATIONAL AMPLIFIER.

Similar presentations

Ads by Google