Presentation is loading. Please wait.

Presentation is loading. Please wait.

High Speed, high common mode immunity communication interface Team May12-05 Chendong Yang Mengfei Xu Advisor: Nathan Neihart Client: RBC Medical Development.

Similar presentations


Presentation on theme: "High Speed, high common mode immunity communication interface Team May12-05 Chendong Yang Mengfei Xu Advisor: Nathan Neihart Client: RBC Medical Development."— Presentation transcript:

1 High Speed, high common mode immunity communication interface Team May12-05 Chendong Yang Mengfei Xu Advisor: Nathan Neihart Client: RBC Medical Development

2 Statement of Purpose  A high speed serial communication interface that would be capable of a high common mode immunity and high speed transmission.

3 Conceptual Sketch/ Block Diagram Transmitter Comparator V_pp = 300mV f = 40 MHZ USB Cable Serial LVCOMS CLK ADCADC

4 Functional Requirements  1. System is capable from 20MHz to1.12 GHz  2. The clock and associated circuitry will be electrically isolated from the rest of the system.  3.LVCMOS come in and same signal come out at the end of the system  4. at least 10 Volts Common mode voltage immunity  5. The system would also need to pass radiated emissions testing, tested at CISPR-11 Group 1 Class B.  6. The transmission distance should be at least 2 meter long.

5 Non-Functional Requirements  1. Stability  2. Budget restriction  3. Easy configuration.

6 Operating Environment and Constraints  The most important environment consideration is noise.  If the noise is bigger than the immunity voltage range, the output will be infected by the noise.

7 Estimate Cost ItemApprox. Cost Transmitter Board $200-$250 Receiver Board$200-$250 ADC Board$100-$200 Radiated Emission Test$200-$250 Unexpected Cost(i.e. damaged board, chip, electronic) $200 Total Cost$1000 - $1500

8 Schedule (This semester) Define Project Basic Block Diagram Transmitter Receiver Market Survey Schematic Test PCB Design Order PCB Aug. Sept. Oct.– Nov. Nov.- Dec.

9 Functional Decomposition NameFunctional TransmitterA device transform a signal line voltage input to double line Low voltage differential signal output ReceiverComparator which compares two voltages or currents and switches its output to indicate which is larger. USB cabletransmit the data from transmitter board to receiver board

10 Market Survey  Requirement: 1. High input toggle frequency, initially at least 40MHZ 2. Small falling/rising time, i.e. t<5ns 3. Affordable Price  Final Choose: DS90C031 from NationalSemiconductor 1.Rising/Falling time: 1.5 ns 2.Power supply : 5v 3.input switching frequency support: excess 77 MHZ 4.~$3 5.±350 mV differential signal

11 Test Constraints  To keep their business secretes, companies don’t provide Pspice models of the transmitters we need. We have tried many ways to solve this problem such like using some other models, translating ibis model to Pspice model, and testing the sample transmitter to see if it is capable for our transmitter part. we are still not able to simulate the transmitters. In that case, we only test the receiver part with input signal generated by the software.

12 Sample Test

13 Test result output when DS99R103 have finished transmitting the LVCOMS to LVDS, there are other 23bits signal in the LVDS Input A square wave with Vpp=3v,frequency=1.5 Mhz,Vdd=5v, clock is as twice fast as the data

14 Market Survey  Requirement: 1. Capability of a high common mode immunity, at least 10V, i.e. power supply range should be greater than 10V 2. High input toggle frequency, initially at least 40MHZ 3. Small falling/rising time, i.e. t<5ns 4. Affordable Price  Final Choose: LT 1711 from Linear Technology 1.High common mode rejection : 65-75dB 2.Rising/Falling time: 2ns 3.Power supply range : 14 V 4.Maximum input toggle frequency : 100 MHZ 5.~$5

15 Schematic Test (Ideal) Test Interface: Pspice Test Condition: 1.Square differential input Vpp = 300 mV, PW = 12.5n, f = 40MHZ 2. Common mode input voltage = 10V 3. V+ = 11V, V- = 0V 4. No noise consideration

16 Schematic

17 Result 1 st Graph: Vout+ 2 nd Graph: Green: Vin+, Red: Vin-

18 Add Noise

19 Schematic Test (Improvement) Test Condition: 1.Square differential input Vpp = 300 mV, PW = 12.5n, f = 40MHZ 2. Common mode input voltage = 10V 3. V+ = 11V, V- = 0V 4. Noise consideration: sine noise 5. Add Hysteresis 6. Line impedance = 100ohm

20 Result

21 USB Cable Test Input signal: Square wave f = 40 MHZ Vpp = 300mV High load impedence Output Conclusion: Normal USB cable can transmit 40MHZ, small differential voltage with tolerable distortion.

22 PCB Design(In progress) Test Interface: Eagle PCB design software PCB designed size: 80mm * 70mm

23 PCB Layout (Current Version)

24 Current Project Status Define Project Basic Block Diagram Transmitter Receiver Market Survey Schematic Test PCB Design Order PCB Issue Left 1.Optimize the PCB layout 2.Order the electronic element need for our PCB.

25 Individual Responsibility & Contribution Mengfei Xu: Team Leader Transmitter Designer Website design. Chendong Yang Communication Liaison Receiver Designer Document & File Arrangement

26 Schedule (Next semester) Transmitter PCB Setup Receiver PCB Setup Verification Test Whole System Verification Test Improvement Radiated emission Test Verification & Delivery Jan.- Feb Feb. March. April Aug.- May.

27 Questions?


Download ppt "High Speed, high common mode immunity communication interface Team May12-05 Chendong Yang Mengfei Xu Advisor: Nathan Neihart Client: RBC Medical Development."

Similar presentations


Ads by Google