Design and Application of Power Optimized High-Speed CMOS Frequency Dividers.
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Transcript of Design and Application of Power Optimized High-Speed CMOS Frequency Dividers.
![Page 1: Design and Application of Power Optimized High-Speed CMOS Frequency Dividers.](https://reader038.fdocuments.net/reader038/viewer/2022103022/56649ca65503460f94968bf1/html5/thumbnails/1.jpg)
Design and Application of Power Optimized High-Speed
CMOS Frequency Dividers
![Page 2: Design and Application of Power Optimized High-Speed CMOS Frequency Dividers.](https://reader038.fdocuments.net/reader038/viewer/2022103022/56649ca65503460f94968bf1/html5/thumbnails/2.jpg)
Outline
Approach2
Conclusion4
Application33
Background31
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PLLDDSRF circuit…
AApplication
Circuit PartitionArchitectureSelect FF
CSolution
High FrequencyP = CVdd2fα
BChallenge
Background-high speed frequency divider
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Approach-register based frequency dividers
First stage
1.Sense Amplifer have small Tdq delay
2.Only two FF
3.Only one differential logic control state
Counter-based approach require a lot of registers
Divide by two
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Approach-register based frequency dividers
Second Stage
1.MSFF have small power dissipation
2.Only three MSFF
3.Only one logic eliminate forbidden state
Divide by 5
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Approach-register based frequency dividers
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90-nm technology
1.1V Power Supply
5.5GHz
190 uW/GHZReduce 3/4
Approach-register based frequency dividers
Result
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Edge triggered FF Data to Q delay is to long
Conventional MS latch Be at risk of race condition
Single ended structure Cannot produce precise phase skew signal
Fully Differential high speed low power divider based on CMOS logic
Conventional IQ divider with 90 degree phase skew
Approach-high speed IQ divider architecture
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Approach-high speed IQ divider architecture
First Part: Pulse Generator
High frequency input signal Interconnection is simple
Differential feedback structure Low error rate
Low power dissipation No static current source
Disadvantage
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Approach-high speed IQ divider architecture
Second Part: Post processing stage Signal diagram
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Approach-high speed IQ divider architecture
PSPICE simulation
The worst process corner
Conditions: 1 Voltage 7GHz input signal
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Approach-high speed IQ divider architecture
The complete circuit does not contain any current sources
The circuit does not require full swing signals at the internal nodes.
The circuit is absolutely symmetric.
Advantages
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Approach-performance evaluation
The high accuracy of the phase skew can be achieved only if the symmetry of the circuit is maintained in the layout of the divider block(wiring and layout).
Structure : Two sense-amplifiers One shifter core Two SR latches
Implementation of divider in 90 nm CMOS technology
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Approach-performance evaluation
The divider consumes 0.36 mW/GHz at 1.0 V and1.02 mW/GHz at 1.6 V at a maximum operationfrequency of 12.4 GHz.
Sensitive curves
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Application-phase rotator and application in dual modulus pre scaler
Conventional approach
Additional phase synthesizer
Asymmetric layout
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Application-phase rotator and application in dual modulus pre scaler
Proposed divider
Dynamic coupling stage
phase generator and selector in one circuit block
Symmetric architecture
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Application-phase rotator and application in dual modulus pre scaler
Pre scaler using proposed IQ divider
master-slave toggle flip-flops
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Application-phase rotator and application in dual modulus pre scaler
Performance
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Application-signal generation for IQ signal mixer
Performance Process variations and supply noise do not degrade the signal quality excessively
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Conclusion
A high-speed low-power divider topology without static current sources has been proposed for a 90-nm low-power CMOS technology. A maximum input frequency of 12.4 GHz is achieved with a maximum power consumption of 1.02 uW/GHz. The fully symmetric circuit allows for the generation of output signals with a highly precise phase skew of 90 deg.
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