Global ETD Search

1	Design of an Operational Amplifier for High Performance Pipelined ADCs in 65nm CMOS Payami, Sima January 2012 (has links) In this work, a fully differential Operational Amplifier (OpAmp) with high Gain-Bandwidth (GBW), high linearity and Signal-to-Noise ratio (SNR) has been designed in 65nm CMOS technology with 1.1v supply voltage. The performance of the OpAmp is evaluated using Cadence and Matlab simulations and it satisfies the stringent requirements on the amplifier to be used in a 12-bit pipelined ADC. The open-loop DC-gain of the OpAmp is 72.35 dB with unity-frequency of 4.077 GHz. Phase-Margin (PM) of the amplifier is equal to 76 degree. Applying maximum input swing to the amplifier, it settles within 0.5 LSB error of its final value in less than 4.5 ns. SNR value of the OpAmp is calculated for different input frequencies and amplitudes and it stays above 100 dB for frequencies up to 320MHz. The main focus in this work is the OpAmp design to meet the requirements needed for the 12-bit pipelined ADC. The OpAmp provides enough closed-loop bandwidth to accommodate a high speed ADC (around 300MSPS) with very low gain error to match the accuracy of the 12-bit resolution ADC. The amplifier is placed in a pipelined ADC with 2.5 bit-per-stage (bps) architecture to check for its functionality. Considering only the errors introduced to the ADC by the OpAmp, the Effective Number of Bits (ENOB) stays higher than 11 bit and the SNR is verified to be higher than 72 dB for sampling frequencies up to 320 MHz. Pipelined ADC OpAmp Gain Boosting CMFB 2.5bps architecture Flash MDAC
2	A 65nm, Low Voltage, Fully Differential, SC Programmable Gain Amplifier for Video AFE / En 65 nm, fullt differentiell, programmerbar SC-förstärkare för video-AFE med låg matningspänning Aamir, Syed Ahmed January 2010 (has links) <p>Due to rapid growth of home entertainment consumer market, video technology has been continuously pushed to deliver sharper pictures with higher resolution. This has brought about stringent requirements on the video analog front end, which often coupled with the low power and low voltage regulations had to deal with short channel effects of the deep submicron CMOS processes.</p><p>This thesis presents the design of a fully differential programmable gain amplifier, as a subcircuit of a larger video digitizing IC designed at division of Electronic Systems. The switched capacitor architecture of the PGA does not only buffer the signal, but performs compensation for the sync-tip of analog video signal.</p><p>The pseudo differential OTA eliminates tail current source and maintains high signal swing and has efficient common mode feedforward mechanism. When coupled with a similar stage provides inherent common moode feedback without using an additional SC-CMFB block.</p><p>The PGA has been implemented using a 65 nm digital CMOS process. Expected difficulties in a 1.2 V OTA design make themselves evident in 65 nm, which is why cascaded OTA structures were inevitable for attaining gain specification of 60 dB. Nested Miller compensation with a pole shifting source follower, stabilizes the multipole system. The final circuit attains up to 200 MHz bandwidth and maintains high output swing of 0.85 V. High slew rate and good common mode and power supply rejection are observed. Noise requirements require careful design of input differential stage. Although output source follower stabilized the system, it reduces significant bandwidth and adds to second order non-linearity.</p> video analog low voltage SC CMFB OTA PGA Elektroteknik, elektronik och fotonik
3	A 65nm, Low Voltage, Fully Differential, SC Programmable Gain Amplifier for Video AFE / En 65 nm, fullt differentiell, programmerbar SC-förstärkare för video-AFE med låg matningspänning Aamir, Syed Ahmed January 2010 (has links) Due to rapid growth of home entertainment consumer market, video technology has been continuously pushed to deliver sharper pictures with higher resolution. This has brought about stringent requirements on the video analog front end, which often coupled with the low power and low voltage regulations had to deal with short channel effects of the deep submicron CMOS processes. This thesis presents the design of a fully differential programmable gain amplifier, as a subcircuit of a larger video digitizing IC designed at division of Electronic Systems. The switched capacitor architecture of the PGA does not only buffer the signal, but performs compensation for the sync-tip of analog video signal. The pseudo differential OTA eliminates tail current source and maintains high signal swing and has efficient common mode feedforward mechanism. When coupled with a similar stage provides inherent common moode feedback without using an additional SC-CMFB block. The PGA has been implemented using a 65 nm digital CMOS process. Expected difficulties in a 1.2 V OTA design make themselves evident in 65 nm, which is why cascaded OTA structures were inevitable for attaining gain specification of 60 dB. Nested Miller compensation with a pole shifting source follower, stabilizes the multipole system. The final circuit attains up to 200 MHz bandwidth and maintains high output swing of 0.85 V. High slew rate and good common mode and power supply rejection are observed. Noise requirements require careful design of input differential stage. Although output source follower stabilized the system, it reduces significant bandwidth and adds to second order non-linearity. video analog low voltage SC CMFB OTA PGA Elektroteknik och elektronik
4	Modelling active zone calcium dynamics at cerebellar mossy fibre boutons Jablonski, Lukasz 23 May 2018 (has links) The rate at which signals can be transmitted between single neurons limits the speed of information processing. Cerebellar mossy fibre boutons are able to maintain synchronous neurotransmitter release at very high action potential frequencies, up to ∼ 1 kHz . The neurotransmitter release occurs at the presynaptic active zone and is controlled by highly localised calcium signals. In order to allow reliable, fast synaptic transmission, calcium ions must be cleared from the active zone. However, the exact mechanisms of calcium clearance remain elusive. Despite the recent advances in imaging technology, it is not yet possible to measure localised calcium signals on the nanometre scale. Nevertheless, it is possible to address the impact of localised calcium signals on neurotransmitter release with use of computational modelling. In this study, I established an experimentally constrained model of an active zone of the cerebellar mossy fibre bouton. My simulations revealed that endogenous fixed buffers that have low calcium binding capacity ( ∼ 15 ) and low affinity for binding calcium in combination with mobile buffers with high affinity for binding calcium enable rapid clearance of calcium from the active zone during high-frequency firing. Moreover, during high-frequency firing, slow endogenous mobile buffers prevent build-up of the intracellular calcium concentration. The results presented in this work suggest that reduced calcium buffering speeds active zone calcium signalling, thus allowing high rates of synaptic transmission. info:eu-repo/classification/ddc/610 ddc:610
5	Low-voltage, low-power circuits for data communication systems Chen, Mingdeng 17 February 2005 (has links) There are growing industrial demands for low-voltage supply and low-power consumption circuits and systems. This is especially true for very high integration level and very large scale integrated (VLSI) mixed-signal chips and system-on-a-chip. It is mainly due to the limited power dissipation within a small area and the costs related to the packaging and thermal management. In this research work, two low-voltage, low-power integrated circuits used for data communication systems are introduced. The first one is a high performance continuous-time linear phase filter with automatic frequency tuning. The filter can be used in hard disk driver systems and wired communication systems such as 1000Base-T transceivers. A pseudo-differential operational transconductance amplifier (OTA) based on transistors operating in triode region is used to achieve a large linear signal swing with low-voltage supplies. A common-mode (CM) control circuit that combines common-mode feedback (CMFB), common-mode feedforward (CMFF), and adaptive-bias has been proposed. With a 2.3V single supply, the filters total harmonic distortion is less than 44dB for a 2VPP differential input, which is due to the well controlled CM behavior. The ratio of the root mean square value of the ac signal to the power supply voltage is around 31%, which is much better than previous realizations. The second integrated circuit includes two LVDS drivers used for high-speed point-to-point links. By removing the stacked switches used in the conventional structures, both LVDS drivers can operate with ultra low-voltage supplies. Although the Double Current Sources (DCS) LVDS driver draws twice minimum static current as required by the signal swing, it is quite simple and achieves very high speed operation. The Switchable Current Sources (SCS) LVDS driver, by dynamically switching the current sources, draws minimum static current and reduces the power consumption by 60% compared to the previously reported LVDS drivers. Both LVDS drivers are compliant to the standards and operate at data rates up to gigabits-per-second. Low voltage low power common-mode feedback (CMFB) common-mode feedforward (CMFF) OTA-C filters
6	Low-voltage, low-power circuits for data communication systems Chen, Mingdeng 17 February 2005 (has links) There are growing industrial demands for low-voltage supply and low-power consumption circuits and systems. This is especially true for very high integration level and very large scale integrated (VLSI) mixed-signal chips and system-on-a-chip. It is mainly due to the limited power dissipation within a small area and the costs related to the packaging and thermal management. In this research work, two low-voltage, low-power integrated circuits used for data communication systems are introduced. The first one is a high performance continuous-time linear phase filter with automatic frequency tuning. The filter can be used in hard disk driver systems and wired communication systems such as 1000Base-T transceivers. A pseudo-differential operational transconductance amplifier (OTA) based on transistors operating in triode region is used to achieve a large linear signal swing with low-voltage supplies. A common-mode (CM) control circuit that combines common-mode feedback (CMFB), common-mode feedforward (CMFF), and adaptive-bias has been proposed. With a 2.3V single supply, the filters total harmonic distortion is less than 44dB for a 2VPP differential input, which is due to the well controlled CM behavior. The ratio of the root mean square value of the ac signal to the power supply voltage is around 31%, which is much better than previous realizations. The second integrated circuit includes two LVDS drivers used for high-speed point-to-point links. By removing the stacked switches used in the conventional structures, both LVDS drivers can operate with ultra low-voltage supplies. Although the Double Current Sources (DCS) LVDS driver draws twice minimum static current as required by the signal swing, it is quite simple and achieves very high speed operation. The Switchable Current Sources (SCS) LVDS driver, by dynamically switching the current sources, draws minimum static current and reduces the power consumption by 60% compared to the previously reported LVDS drivers. Both LVDS drivers are compliant to the standards and operate at data rates up to gigabits-per-second. Low voltage low power common-mode feedback (CMFB) common-mode feedforward (CMFF) OTA-C filters
7	Design of a Low Power, High Performance Track-and-Hold Circuit in a 0.18µm CMOS Technology / Design av en lågeffekts högprestanda track-and-hold krets i en 0.18µm CMOS teknologi. Säll, Erik January 2002 (has links) This master thesis describes the design of a track-and-hold (T&H) circuit with 10bit resolution, 80MS/s and 30MHz bandwidth. It is designed in a 0.18µm CMOS process with a supply voltage of 1.8 Volt. The circuit is supposed to work together with a 10bit pipelined analog to digital converter. A switched capacitor topology is used for the T&H circuit and the amplifier is a folded cascode OTA with regulated cascode. The switches used are of transmission gate type. The thesis presents the design decisions, design phase and the theory needed to understand the design decisions and the considerations in the design phase. The results are based on circuit level SPICE simulations in Cadence with foundry provided BSIM3 transistor models. They show that the circuit has 10bit resolution and 7.6mW power consumption, for the worst-case frequency of 30MHz. The requirements on the dynamic performance are all fulfilled, most of them with large margins. Electronics track-and-hold CMOS 0.18 low power high performance 10-bit folded cascode switch theory correlated double sampling CDS fully differential gain boosting regulated cascode transmission gate transmission gate switch clock generator clock driver bias bias circuit amplifier design switch design common mode feedback CMFB 80MSPS 80MS/s Elektronik Electronics Elektronik
8	Design of a Low Power, High Performance Track-and-Hold Circuit in a 0.18µm CMOS Technology / Design av en lågeffekts högprestanda track-and-hold krets i en 0.18µm CMOS teknologi. Säll, Erik January 2002 (has links) <p>This master thesis describes the design of a track-and-hold (T&H) circuit with 10bit resolution, 80MS/s and 30MHz bandwidth. It is designed in a 0.18µm CMOS process with a supply voltage of 1.8 Volt. The circuit is supposed to work together with a 10bit pipelined analog to digital converter. </p><p>A switched capacitor topology is used for the T&H circuit and the amplifier is a folded cascode OTA with regulated cascode. The switches used are of transmission gate type. </p><p>The thesis presents the design decisions, design phase and the theory needed to understand the design decisions and the considerations in the design phase. </p><p>The results are based on circuit level SPICE simulations in Cadence with foundry provided BSIM3 transistor models. They show that the circuit has 10bit resolution and 7.6mW power consumption, for the worst-case frequency of 30MHz. The requirements on the dynamic performance are all fulfilled, most of them with large margins.</p> Electronics track-and-hold CMOS 0.18 low power high performance 10-bit folded cascode switch theory correlated double sampling CDS fully differential gain boosting regulated cascode transmission gate transmission gate switch clock generator clock driver bias bias circuit amplifier design switch design common mode feedback CMFB 80MSPS 80MS/s Elektronik Electronics Elektronik

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