Download Overview

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Electrical substation wikipedia , lookup

Decibel wikipedia , lookup

Rectifier wikipedia , lookup

Power inverter wikipedia , lookup

Variable-frequency drive wikipedia , lookup

Power factor wikipedia , lookup

Standby power wikipedia , lookup

Three-phase electric power wikipedia , lookup

Wireless power transfer wikipedia , lookup

Spectral density wikipedia , lookup

Islanding wikipedia , lookup

History of electric power transmission wikipedia , lookup

Power over Ethernet wikipedia , lookup

Voltage optimisation wikipedia , lookup

Electric power system wikipedia , lookup

Electrification wikipedia , lookup

Audio power wikipedia , lookup

Distribution management system wikipedia , lookup

Power electronics wikipedia , lookup

Buck converter wikipedia , lookup

Amtrak's 25 Hz traction power system wikipedia , lookup

Power engineering wikipedia , lookup

Alternating current wikipedia , lookup

Rectiverter wikipedia , lookup

Pulse-width modulation wikipedia , lookup

Mains electricity wikipedia , lookup

Power supply wikipedia , lookup

Switched-mode power supply wikipedia , lookup

AC adapter wikipedia , lookup

Transcript
Radar Interface Design Project
Critical Design Review
Sponsor: Scott Faulkner,
Lockheed Martin
Group #1
Catherine Donoso
Diego Rocha
Keith Weston
Overview
Lockheed Martin sponsored project
Advisor is RF Engineer, Scott Faulkner
Power Supply (PS) for transceiver in Joint Air to Ground Missile
(JAGM) seeker
PS must include control unit
PS system must generate specific voltages
PS system must use power sequencing
Goals
Provide solutions to the next generation transceiver
power supply design flaws by using innovative ideas
Low EMI
Low thermal characteristics
Smaller circuit card than used before
Find alternative parts utilizing new technology
Provide FPGA loads for future use
Requirements
Lowest EMI possible
Lowest possible power
No heat sink available
directly on board, only for
system
limited airflow
Preferrable non-Rohs
Compliant
32V, 1.5V and 3.3V provided
Specifications
3W dissipation for each part
Preferable military grade temperature, -55 to +125
6 sq. in board, any shape
High power architecture
+6V
load- less than 50% duty cycle and applied no longer than 100us
pulse repetition rate from 1 to 100 kHz
Signal
Output Voltage
Output Current
Regulation
Ripple Voltage
Low power architecture
load-continuous
6XMIT
6VDC
11 A
3%
1mV
9XCVR
+9VDC
100mA
3%
100uV
6XCVR
+6VDC
1000mA
3%
100uV
4XCVR
-4VDC
250mA
3%
100uV
-4V, +6V, +9V
FPGA
Power sequencing--4V,+6,+9,+6(high)
Power Sequence
Power UP sequence
-4V, +6V(low), +9V, +6V(High)
exact opposite for power down
Power up Sequence
SWPS for both high power and low power uses
PGOOD pin to send high or low signal to FPGA
-4
FPGA will send signal at least 2.5V to RUN pin
to turn ON/OFF SWPS
LDO and charge pump send Vout signal to ADC
onboard FPGA
FPGA will send signal to pull up or down SHDN
pin to turn ON/OFF parts, must use pull-up
resistor. probably transistor for switch
Failure Mode
FPGA must power down all power supplies in
exact opposite order
+6XCVR
+9
+6XMIT
Power down Sequence
-4
+6XCVR
+9
+6XMIT
Noise Consideration and
Solution
Power supply to transceiver must have clean signal as to avoid
possible malfunction because of noise
Must use low noise parts
Difficult to use low noise parts in a power supply-many parts use
switching to step-down voltage
Challenge-avoid noisy parts or isolate noisy parts from
transceiver
Use filtering
Use mu-metal for magnetic shielding
Temperature Consideration
Tjamax = 150 degrees celsius
Tamax = 59 degrees celsius (found from voltage values given max. Tjamax)
[Iout*(Vin-Vout)] + (Ignd)Vin.
Ignd can be found from the graph below.
•
Very important to narrow the delta between Vin and Vout. SWPS needs step-down voltage as much as possible
•
SWPS heat dissipation not as severe as LDO
Low Power Design
SWPS: LTM8032
was LTM4612
low noise
SHDN
32Vin
Switching
Power
supply 2
Line ar
Regulator 1
9XCVR
smaller than other models
SHDN
handles large step-down delta
Switching
power
supp ly 3
Line ar
Regulator 2
6XCVR
LDO: LTM1963
heat dissipation
Switching
Power
supply 4
Charge
pump 1
RUN
used as filter
Charge pump: LT1054
was LT3704 and ripple attenuator
inverts
steps down
small
least noisy of power supplies that invert
Charge
pump 2
RUN
4XCVR
Simulation and Experimental
Noise Results
SA proved low noise for SWPS,8032
LTSpice Simulation proved no noise for
LDO
LDO useful as a filter
Board Space Consideration and
Challenge
Only 6 sq. in., or 3850 sq. mm. in
rectangular shape
Power supply requires multiple parts for
proper function
Part #
Amount Used
Area
Total Area
LTM 4612
4
675
2700
LT1963
2
65.28
130.56
HMC-VVD104
1
3.67155
3.67155
LTC3704
1
15.671304
15.671304
Fusion
1
100
100
TOTAL AREA
Now, main parts occupy 2950 sq. mm.
Parts will be installed only on topside
Est. # of layers is 5-6
A couple signal layers will be needed to
support amount of traces on small surface
area for large # of parts
What can be eliminated? Replaced?
P ads
Ground
Signal
Signal
Power
2950
Proving the Design
Will not be installed in missile seeker, therefore needs to be proven to work outside of actual
system
Mock loads must be created to effectively test power supply
High power architecture will have separate test card
Prototype only purpose, test card will be implemented on same board
Low power architecture will have onboard test card
3.3V
Power
supply
Logic analyzer used to time power sequence
2 in.
Low Signal Test Card
5 in.
32V
Power
supply
J2
32Vin
from
power
supply
P1
J1
J3
P2
32Vin
Filtered
32Vin
3.3V
Logic
Analyzer
Connector
J4
JTAG
6 sq. in.
UUT
3 in.
Computer
6 in.
Logic
Analyzer
High Power Section





Process power as required by the load.
Efficiency must fit in the 90 percentile range.
Meet power sequencing.
Meet EMI requirements.
Testing prototype to debug and prove its functionality.
6XMIT Power Supply
•
•
•
6XMIT will drive the transceiver with load durations ranging
from 1k Hz to 100k Hz with a duty cycle no greater than
50%.
6XMIT 6 VDC @ 11 Amps peak 3% Regulation 1 mV noise.
Implementation of DC/DC converters turns out to be a must
in order to meet specs.
LT uModule Family
•
•
•
To facilitate switching power supply Linear
Technology has designed 8 dc/dc uModules.
LGA package for these family has been designed with
very low thermal resistance thus increasing heat
dissipation.
The ultralow noise design has the lowest EMI for
DC/DC converter modules.
LTM4612
•
•
•
•
•
5V to 36 V input voltage range.
5A DC, 7A peak output current.
Parallel/ Current sharing
Voltage and current protection
Programmable soft-start
Efficiency
•
•
Theoretically dc/dc converters
are capable of achieving 100
% efficiency.
The LTM4612 ultra-low noise
dc/dc buck converter can
achieve efficiencies up to 92
%.
Paralleling LTM4612
•
•
•
Polyphase
configuration lowers
ripple.
Spreading the
spectrum lowers EMI
Current sharing
allows converters to
be paralleled
Spreading Spectrum
Frequency Spectrum using technique
Frequency Spectrum without using
technique
Testing Prototype
TI 2808 DSP
•
•
•
Familiarity with 2808 DSP
board facilitates test set up.
PWM pins have been coded
to generate waveforms that
can range between 1kHz to
100kHz with a duty cycle that
can be varied from 0 to 50%.
200kW resistor load bank
available for testing.
Test set up
J1
U3
U4
3
0
1
2
2
1
4
1
2
11
12
25
3
4
C1
1uF
5
+VIN
+VOUT
-VIN
-VOUT
C3
1
C2
330uF
6XMIT
Power supply 32V
+
3
330uF
0
C1
Three prong
U3
4
5
+VIN
-VIN
+VOUT
-VOUT
3
C3
1
C2
330uF
6XMIT
Connection
Coming from the
6XMIT
+
-
1
4
2
3
Terminal Block
Shunt inside the Newton Power Analy zer
+
6V ~1mV
-
R1
ripple
R1
0.5
Q1
2N3459
Controlled signal from DSP board
1-100 kHz
with duty
cycle < 50%
Pulsed load
330uF
-