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A 3GS/s 6-Bit Bipolar Flash ADC in 0.25 µm
Bruno Da Silva, Stґphane Bosse, Sґverin Barth e e
Station de radioastronomie de Nancay - route de Souesmes 18330 Nancay ё ё
bruno.da silva@obs-nancay.fr

Abstract
We report on a flash Analog to Digital Converter (ADC) at 3 Giga samples per second (GS/s) which was developed using QUBIC4X: a 0.25 µm SiGeC process from NXP semiconductor. The ADC has a bandwidth of 1.5 GHz and a resolution of 6-bits. The design employs a differential structure. The ADC uses a parallel architecture consisting of the following components: track and hold, comparators, and a fat tree encoder. A system test validated the test bench, and an additive scrambler was used to eliminate long sequences consisting entirely of 0 or 1 . The core of the digital circuit is in EmitterCoupled Logic (ECL). The input is adapted to 100 differential, and the outputs use standard Low Voltage Differential Signaling (LVDS). The operating voltage is 0.5 Volts. The complete system has a power consumption of 2.6 Watts and the Effective Number of Bits (ENOB) is higher than 5 at Nyquist frequency (1500 MHz).

INTRODUCTION
Heterodyne receivers have generally been used in radio astronomy to bring high frequencies down to frequencies which can be directly treated by digital processing systems. Such a system has its associated complexity (see e.g. Fig: 1a) and an important goal is to do away with the heterodyne mixing, and instead to process directly the received frequency (RF) of the radio receiver. In order to dramatically reduce the system complexity, the goal is to acquire the whole frequency band between 300 MHz and 1.5 GHz (UHF-L band) using only one receiver (Fig: 1b). [1, 2].

CIRCUIT IMPLEMENTATION
Track and Hold
The T/H study is based on [5, 6]. The goal is to reduce the feedthrough and the droop rate, to adapt the input and to have a low impedance on output. Three parts make up this T/H (Fig: 3): An input buffer, T/H (switch with a charge capacitance) and an output buffer.
T/H SINGLE T/H Single Input T/H Single Output 1.35 0.15 0.2 T/H DIFFERENTIAL Input T/H Output T/H

0.1 1.3 0.05

volts

volts

Figure 5: Digital part and digital gate

0

1.25 -0.05

-0.1 1.2

Integrated Test System
A test system is integrated on chip to evaluate the transmission to the data acquisition card (fig: 7). Random binary code is also integrated in the circuit for test purposes. The output data can be scrambled allowing the possibility to use Clock Data Recovery (CDR) at the output without sending the clock itself.

-0.15

-0.2 2.41 2.415 2.42 2.425 2.43 2.435 2.44 2.445 2.45 2.455 second (x10E-8) 2.41 2.415 2.42 2.425 2.43 2.435 2.44 2.445 2.45 second (x10E-8)

Figure 3: Track and Hold design and Transient simulations with input signal at 2 GHz and clock signal at 4 GHz single-ended and differential

Comparator
Figure 1: a. heterodyne receiver on L-band (ADC << 1GS/s) b. Radio receiver simplified L-band (ADC > 3GS/s)

ADC REQUIREMENTS
High sampling rate (< 3 GS/s) Minimum bandwidth of 1.4 GHz 6-bit ADC

The pre-amplifier has a large bandwidth and provides sufficient gain to obtain a large voltage. Using a Monte Carlo statistical analysis, a yield higher than 90% is obtained at 3 GS/s for a quantum of 1 mV.

Figure 6: Output ADC design

ADC layout
The layout is designed with the overall goal of minimizing cost. The layout is divided into sectors that are isolated by a guard ring. Each ladder resistance is composed of ten resistances for improved matching. The comparator ladder is symmetrically divided in 2 blocks. The clock is distributed symmetrically with a clock regeneration for each 8 comparators. LVDS are integrated in Output Logical pads. The ADC layout with pads has a total area of 4.25mm2 (fig: 7).

ADC ARCHITECTURE
Our flash ADC is composed of the following stages (Fig: 2): a track and hold (T/H), comparators, a bubble correction, a fat tree encoder, and a scrambler. A test board was constructed in order to validate the behaviour of the chip. Each block is fabricated in differential bipolar technology. The digital part is based on Emitter-Coupled Logic (ECL) and Current Mode Logic (CML) [3, 4].

Figure 4: Comparator design: pre-amplifier and ECL D-latches

Digital
The digital part of the ADC is composed by a Bubble Correction (BC) and a Wallace Tree Encoder (WTE). Fig: 5 shows the gate architecture. Synchronization is improved by adding a D-Latch between the BC, the WTE, and the output digital part. This is similar to the method employed in the structure of the comparator. and Table: 1 presents specifications. Physical characterisation is in progress. Three test benches are being prepared for measurement. On the first test bench (Fig: 9a), the ADC outputs are acquired with a fast oscilloscope (see the eye diagram Fig: 8). For the second test bench, the data are sent via optical fibre directly to the data acquisition card (Vertex 6 FPGA board) using SFP+ connectors to evaluate static and dynamic parameters.

Figure 2: Block diagram of the ADC.

Figure 7: Layout

Simulation, Measurements and Results
Static and dynamic parameters have been characterized in simulation. Dynamic parameters were computed with a 700 points time resolution. The resistance and capacitance parasitic extraction simulation predicts an effective number of bits (ENOB) of 5.2 bits at 100 MHz to 5 bits at 1500 MHz (Fig: 9b). The static performance analysis of the flash ADC gives a DNL (Differential Non-Linearity) and INL (Integral Non-Linearity) smaller than 0.6 LSB. Table 1: Specifications Table 2: Consumption Budget
Process 0.25 µm Input range 0.5 V Sampling rate 3 GS/s Bandwidth 1500 MHz S u p p ly 2.5 & 2 V Power diss. 2.6 W D i e a re a 4 . 2 5 mm2 Blocks S u p p ly T/H 2.5 V C o m p a ra to rs 2 V D i g i ta l 2V System test 2V LVDS 2V Total -- Current 6 4 mA 4 6 8 mA 4 7 0 mA 1 1 5 mA 1 8 9 mA -- Power 1 6 0 mW 9 3 6 mW 9 4 0 mW 2 3 0 mW 3 7 8 mW 2 6 4 4 mW

The third test bench uses external 1-to-8 demultiplexers designed at the Nancay Radio Astronomy Facility. The demulё tiplexer data rate is 375 MHz. Each ADC bit is connected to a demultiplexer to reduce speed data to easier acquisition. Matlab scripts are used for the ADC performance analysis.
35 34.5 34 33.5 33 dB 32.5 32 31.5 31 30.5 0 200 400 600 800 MHz 1000 1200 1400 1600 SNR SFDR

Figure 8: Digital results: 1-bit Eye diagram at 3 GS/s.

Figure 9: Test card and simulation results: a) Test card showing input and output ports. b) Dynamic simulation results.

Table: 2 presents the power consumption budget for the ADC

Conclusions
The Flash ADC op erates at 3 GS/s with an ENOB > 5 bits for input frequencies up to 1.5 GHz. The ADC was pro duced with the 0.25 µm QUBIC4X technology of NXP. It consumes 2.6 W. Efforts will b e made to reduce the general p ower consumption in a next generation chip.

References
[1] M. Ruiter, E. van der Wal EMBRACE, a 10000 Element Next Generation Aperture Array Telescope, European Microwave Conference 2009, pp326-329, 29 September 2009 - 1 October 2009 [2] S.J. Wijnholds, G.W. Kant, E. van der Wal EMBRACE: Phased Array Results with the First Thousand Elements 2010, Limelette, Belgium, S.A. Torchinsky et al. (eds), ASTRON, ISBN 978-90-805434-5-4 [3] Stephane Thuries, Conception et integration d'un synthetiseur digital microonde en technologie silicium SiGe:C 0.25µm, PhD Thesis, december 2006

[4] Samad Sheikhaei, Shahriar Mirabbasi, Andre Ivanov An encoder for 5GS/s 4-Bit flash ADC 0.18µm CMOS CCECE/CCGEI, Saskatoon, May 2005 [5] Yevgen Borokhovych, Hans Gustat, Bernt Tillack, Bernd Heinemann, A Low-Power, 10GS/s Track and Hold AMplifier in SiGe BiCMOS Technology, Esscirc v61 [6] Andrea Boni, Matteo Parenti, A 1GS/s 2.7V Track an Hold Amplifier with 10-b resolution at Nyquist in SiGe BiCMOS, ESSCIRC 2002

Acknowledgements

This work was carried out with the financial assistance of the Rґgion Centre, the CNRS, and the Observatoire de Paris. e