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Issue 61August 28, 2012
Brad ClevelandCEOProto Labs
Electrical Engineering Community
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Brad ClevelandCEOProto Labs
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Brad Cleveland PROTO LABS
Interview with Brad Cleveland - CEO
The effects of timing and gain mismatches on the sampled signal in M-channel TI-ADCs and a unique digital solution found nowhere else on the market.
Despite the growth among the top fabless companies, the power of fabs is increasing in today’s semiconductor ecosystem.
RTZ - Return to Zero Comic
Featured Products
Time-Interleaved ADCs for Digital Communication ReceiversBY ELETTRA VENOSA, DR. MIKKO WALTARI, DR. FRED HARRIS & MIKE KAPPES WITH IQ-ANALOG
BY MEENU SARIN WITH VLSI
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BradClevelandProto Labs
Proto Labs is the world’s fastest provider of CNC machined and injection molded parts. Their goal is to provide new prod-uct designers with the easiest, fastest and least-expensive way to obtain low volumes of parts based on their 3D CAD design. We spoke with the CEO of Proto Labs, Brad Cleveland, about the key to their success, the Protomold process and the future of the company.
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BradClevelandProto Labs
Tell us a little about your background. How did you get started with physics and where did this interest take you?
I received an undergraduate degree in math and physics, but when I was in college I got really into building interfaces for computers and mechanical devices, which was a whole new world within itself. One of my professors left to work at Honeywell and that connection resulted in my first job. My responsibilities there were really similar to what I was doing in college: writing software and developing electronic interfaces between computer systems. I was also ripping apart circuit boards and rewiring things, so I had a pretty aggressive introduction to hands-on electrical engineering in my early days.
After Honeywell, I was fortunate to join a cutting-edge systems house called MTS Systems Corporation, also in Minneapolis. There I was working primarily on robotics systems and writing software for large-scale machinery. After a couple of years at MTS, I transitioned into a project engineer role and began organizing mechanical, software and electrical engineers to help develop and build custom manufacturing systems. For the next eight years, I traveled the world selling really interesting projects, like laser inspection systems and NASA flight simulators. While collaborating on a titanium manufacturing system that was ultimately sold to the Navy, I met a Johns Hopkins physicist who eventually became my business partner in a subsidiary that we operated for four years.
Shortly after that I happened to be flipping through the local newspaper and saw a “want ad” from a company called Protomold, and the rest, as
they say, is history. I started as the CEO in November of 2001 of what would soon become Proto Labs and have held the position since. I was the tenth employee at the time, and we currently have a staff of 560.
Tell us a little bit about the company overall. What different types of prototyping do you do?Proto Labs is the world’s fastest provider of CNC machined and injection-molded parts. We’ve created proprietary software that runs on high-performance compute clusters to dramatically accelerate standard manufacturing processes. The high speed, low cost, and unmatched scale with which we can deliver prototype and short-run production parts is redefining manufacturing.
The reason our services are so fast
is that we have developed proprietary
software that automates standard
manufacturing processes.
We currently have two services available. If a product developer anywhere in the world wants to create a prototype, they can have parts made with our CNC machining service, a process that begins when they upload a 3D CAD model to our website. We routinely take orders for one part, which is
pretty unique in CNC machining because typically you have to undergo hours of programming and fixture design before making parts. We’ve automated the majority of that process, enabling us to make hundreds and hundreds of different parts every day.
Our second (and original) service is called Protomold, which is a quick-turn custom plastic injection molding service. CNC machining deals with plastics and metal, and Protomold follows a similar process with plastic. You can upload a 3D CAD model and we’ll send back a quote within minutes. If you move ahead with the order, we
immediately begin manufacturing the mold and ship parts to you as fast as the next business day. We do have some limitations with the size and geometry of the part, but if it’s a part that we can make, there’s nobody else faster or more cost-effective for prototype or short-run parts.
Can you elaborate a little more on the software that you use and the technology behind it?The reason our services are so fast is that we have developed proprietary software that automates standard manufacturing processes. It allows us to the save the time spent on programming and building fixtures that might take days in a standard environment. When a product developer uploads a model and asks for a quote, the software completely programs the machine in real time to manufacture that part. The software runs on a parallel processing environment that we also developed to handle all of the analysis automatically. That’s why we are able to go from quote to cutting materials faster than anybody
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else. We’ve invested around 100 years’ worth of man-hours into this software, and we have been doing it over a 12-year period during which we have been producing parts for customers and constantly updating the software to improve the process.
Do you operate 24 hours a day since you get prototypes out that fast?
We do operate at all times. We have manufacturing facilities in the United States and in England, which supports all of the European Union, and we also have a facility in Japan.
In the U.S., we have about 300,000 square feet of manufacturing space in four different plants and almost
all of them operate 24/7. In Europe, we have around 130,000 square feet of manufacturing space to cover both services, and that facility runs 24 hours a day, 5 days a week to meet demand. In Japan, the plant has 30,000 square feet and operates around 18 hours a day, 5 days a week. We have these different locations so that we can provide our services to clients worldwide and still maintain our reliable and quick prototyping services, which is the basis of our core business model.
What is the range of prices for your services?
For our CNC Machining service, the least expensive single part price will be about $100. That’s
actually breakthrough cheap because typically you’d have to pay someone to develop fixtures and program the equipment, but again, our automation makes it more cost effective. The price really depends
We’ve invested around 100 years’ worth of man-hours into this
software, and we have been doing it
over a 12-year period during which we have been producing parts
for customers and constantly updating
the software to improve the process.
on the size and complexity of the part. The average price to create a mold and have 25 parts delivered is about $4,000. However, once you get that mold made, we can continue to make parts for you at a few dollars apiece, or less depending on the size and materials.
Where are you based?We are in the Minneapolis/St. Paul area. Our headquarters are in a Western suburb called Maple Plain. Our European manufacturing facilities are located in Telford,
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England and we have sales and customer service facilities in Germany, France and Italy in addition to the manufacturing plant in Japan.
What’s the culture like at Proto Labs?We strive for a culture that is as entrepreneurial as possible, meaning that we’re all in this together and our objective is to profitably grow this company forever. We aim to maintain an environment where people are appreciated and have the opportunity to contribute to a
winning team. We actually have a VP of Culture on staff, tasked specifically with creating a nurturing and productive workplace in which people enjoy doing their jobs.
What’s in store for Proto Labs for the next few years?We’ve had a strategy in place for a number of years, made up of several objectives. One of the objectives is to keep searching for new customers, driven by expansion of our marketing activities. We’ve established ourselves in the U.S., Europe and Japan and it’s unlikely that we’ll stop
there. The second growth factor is to constantly broaden the parts that we can handle, meaning the complexity of parts and additional materials that we support. We have a lot of things going on in that respect as well. The third growth factor is that we have the ability to add new manufacturing capabilities beyond the CNC machining and Protomold. You can expect to see all of these developments to continue over the next five years. ■
Proto Labs headquarters in Maple Plain, MN
Visit Proto Lab’s website: Proto Labs
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Energy Star-Compliant AC-DC Power SystemVicor™ Corporation introduced its new Westcor™ MicroPAC™ power factor corrected AC-DC power system providing up to 1300 W of continuous power at up to 92% efficiency and 25 Win3 power density in a compact 4 × 1.72 × 7.45 inch package. Offering semi-regulated output voltages of 12, 24, 36 and 48VDC via four factory-configurable isolated outputs, the new Westcor MicroPACs support a wide range of customer power requirements and are ideally suited for distributed power architectures in industrial and automation, MIL-COTS, telecom and renewable energy applications. For more information, click here.
Synchronus Step-Down DC/DC ControllerLinear Technology Corporation announces the LTC3883/-1, a synchronous step-down DC/DC controller with an I²C-based PMBus interface for digital power system management. This device combines best-in-class current-mode switching regulator performance with precision mixed signal data acquisition for unsurpassed ease of power system design and management. It is supported by the LTpowerPlay™ software development system via an easy-to-use graphical user interface (GUI). For more information, please click here.
Ultrabook Digital Control ICInternational Rectifier announced the introduction of the IR3588 CHiL® digital control IC and IR3552 and IR3548 single- and dual-phase PowIRstage™ devices, delivering the industry’s smallest solutions that meet Intel’s VR12.6 specifications for 15W and 25W Ultrabook™ laptop computers that significantly extend battery life. IR’s IR3588 and optimized single-phase and dual-phase IR3552 and IR3548 PowIRstage devices reduce footprint by more than 50 percent compared to leading monolithic solutions and offer a 40 percent smaller footprint compared to alternative reference designs. Fore more information, click here.
High Efficiency PoE++ PD ControllersLinear Technology Corporation introduces the LT4275, LTPoE++™, PoE+ and PoE-compliant powered device (PD) interface controllers for applications requiring up to 90W of delivered power. PoE+ limits the maximum PD power delivery to 25.5W, which is insufficient to power today’s new class of power-hungry applications, such as picocells, base stations, signage and heated outdoor cameras. Linear Technology’s LTPoE++ standard addresses this market by expanding the power budget to four different power levels (38.7W, 52.7W, 70W and 90W), enabling complete high power LTPoE++ systems. For more information, please click here.
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Dean Kamen landed in the limelight with the Segway, but he has been innovating since high school, with more than 150 patents under his belt. Recent projects include portable energy and water purification for the developing world.
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Dr. Elettra VenosaEE PHD - IQ-Analog, SDSU
Co-Authors:Dr. Mikko Waltari, IQ-Analog
Dr. fred harris, SDSUMike Kappes, IQ-Analog
Time-InterleavedADCs for DigitalCommunicationReceivers
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Dr. Elettra VenosaEE PHD - IQ-Analog, SDSU
Co-Authors:Dr. Mikko Waltari, IQ-Analog
Dr. fred harris, SDSUMike Kappes, IQ-Analog
Time-InterleavedADCs for DigitalCommunicationReceivers
Time-interleaving (TI) is the most effective way to overcome the constraints imposed by hardware technology which limit the maximum sampling frequency in analog-to-digital converters (ADCs) by reducing implementation costs and lowering power consumption. Low power consumption, lower implementation cost, high sampling frequency and fine resolution are highly desired characteristics with multipurpose DSP-based communication receivers. Unfortunately when ADCs are used in a time-interleaved fashion, timing and gain mismatches between the channels are introduced. These mismatches have a strong adverse effect on the performance of these systems.
In this white paper we describe the effects of timing and gain mismatches on the sampled signal in the general case of M-channel time-interleaved analog-to-digital converters (TI-ADCs) and propose a solution for the two-channel TI-ADC case. The proposed solution is quite general and also unique from the other solutions currently present on the market in that it works in communication scenarios when sub-sampling of intermediate frequency (IF) carriers is applied. This low-rate sampling approach is becoming popular in communication receivers because it promises lower workload and power consumption. Our solution is implemented completely in the digital domain, operates in the background while the TI-ADC is sampling, and allows for the full correction of mismatches without sacrificing resolution.
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ADC BASICS
Analog-to-digital converters translate analog quantities, which are characteristic to most phenomena in the “real world,” to the digital domain, used in information processing, computing, data transmission, and control systems. The relationship between inputs and outputs of an ideal ADC is shown in Figure 1. The analog signal, x(t), is at first, processed through a sampler that takes its values at fixed periodic, uniformly distributed, discrete time instants with resolution dictated by the sampling frequency fs=1/Ts. Then the discrete time samples are quantized and coded in bit words. The quantizer performs the transformation of the continuous values to fixed discrete values by applying the transfer function shown in Figure 2. Slightly different curves (non symmetric around zero or having non-uniformly distributed steps) can describe the quantization process when it is required by the design. The quantized values are later coded in digital N-bit words.
are slightly perturbed and the ADCs do not realize a perfectly uniform amplitude quantization.
The nature of the hardware devices involved in the sampling process (sampler and clock generator) also causes loss of precision of the output sampled data. This imprecision, which has two components (random and deterministic), is well modeled by timing jitter and timing offset errors. These two phenomena are quite different hence they have to be described by using different models and compensated using different methods. In particular, while timing jitter presents a random nature and can be correlated or uncorrelated (colored timing jitter and white timing jitter), timing offset is a deterministic delay. The correlated timing jitter, as well as the timing offset, have more significant effects when the frequency of the input signal is high. Usually, even if they are very small when compared to the overall sampling period, they will have destructive effects which compromise high precision applications. At high sampling frequencies the constraints on precision become, in fact, even more stringent.
Our goal is to increase the sampling frequency of the conversion process without impacting the ADC performance and implementation cost. A good solution for this is a time-interleaved architecture. A time-interleaved ADC represents an effective way to increase the overall sampling frequency of the system by using multiple lower sample rate ADCs.
Unfortunately, when two or more analog-to-digital converters are time-interleaved, the conversion process suffers from the timing and gain mismatches between the channels. All known solutions for correcting these mismatches are ineffective when the input signal has a band-pass nature which incidentally is the most common scenario for digital communication receivers.
Figure 1: Analog-to-Digital Converter. The Analog-to-Digital Conversion Process is Usually Modeled as a Sequence of Two Steps: Uniform Sampling and Uniform Quantization
In reality, the digitization of an analog signal, is far from being the ideal process just described. The quantizer in fact introduces errors which are due to the approximation in representing analog, continuous values with a finite set of 2N discrete values. All the analog signal values included in a certain, fixed interval are associated with the same discrete output value (look at the curve in Figure 2). This approximation imposes uncertainty on the quantizer output values which is usually modeled as a, zero mean, uncorrelated noise which is named quantization noise. This noise can be reduced (for example by increasing the number of bits) but it can never be completely avoided. Note that in practice, because of inaccuracies and mismatches in the ADC implementation, the quantizer thresholds Figure 2: Transfer Function of Uniform Quantizer
ADC
ADC
QUANTIZER
x(t)
x(t)
AnalogInput
DigitalOutput
t
bits
fs
Ts=1/fs
x[nTs]
nTs
-V V AnalogValues
bits
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The current identification and correction architectures for TI-ADCs also do not address when the desired signal spectral copy is not in the first Nyquist zone but instead resides on higher order Nyquist zones. Band-pass sampling on higher order Nyquist zones is commonly used in communication scenarios in which the involved signals have a sparse nature in the frequency domain.
In the following section, we explain briefly the effects of gain and timing mismatches on the TI-ADC input signal and later we present our solution for identifying and correcting the artifacts resulting from those mismatches in a two-channel TI-ADC case.
TIME-INTERLEAVED ARCHITECTURE
Several architectures of ADC’s exist (subranging, folding, pipeline, successive approximation register, etc) which are suitable for high sample rate, high precision applications. In each case there is a clear tradeoff of power and speed which restricts the range of applications the architecture can service. It is possible to eliminate this compromise through the use of time interleaving multiple ADC cores.
bandwidth required for the anti-alias filter [1]. However, for each arm it is not required to verify Nyquist sampling criteria hence, each TI-ADC channel, samples the analog signal at 1/M of the overall sampling frequency, fs. The starting point (initial time) of each sampler is delayed by mTs/M. This time shift turns into a phase shift in the frequency domain. In the ideal case the phase shifts on each channel are such that the undesired aliased signal replicas destructively sum together when the samples from each channel are interleaved by the multiplexer while only the desired replicas constructively sum together.
When two or more analog-to-digital converters are time-interleaved, the conversion process suffers from timing and gain mismatches between the channels which corrupt the multiplexing process.
THE CHANNEL MISMATCHES
There are two main sources of trouble in TI-ADCs: the timing offsets, r0, and the gain offsets, g0. The timing offset is the difference between the ideal time instant, in which the ADC is supposed to sample the input signal, and the real time instant in which the ADC samples the input signal. The gain offset is a multiplicative gain which is applied to the amplitude of the input signal. These parameters result from inevitable fabrication process imperfections as well as more systematic circuit layout and parasitic differences. They are normally very small and, when the ADC is used in a standalone fashion, they do not affect its performance. However they become considerable issues in time-interleaved architectures. These problems are caused by differences between the individual ADCs used in the time-interleaved system and are commonly referred to as channel mismatch errors. The channel mismatch errors give rise to distortion.
When used in a two-channel time-interleaved architecture, two ADCs operate in parallel with a Ts time offset of their 2Ts time interval sampling clock. When multiplexed properly, the overall sampling frequency of the system is doubled. In an ideal two-channel TI-ADC, the aliasing terms formed by the individual ADCs, operating at half rate, are cancelled by the interleaving process. This cancellation occurs because the aliased spectral component of the time offset ADC has the opposite phase of the same spectral component of the non-time offset ADC. In the absence of time offset and gain mismatch the sum of their spectra would cancel the undesired alias components.
Because of gain and timing phase mismatches the
Figure 3: Model of a M-Channel Time Interleaved Analog-to-Digital Converter
Figure 3 shows the block diagram of a M-channel TI-ADC architecture. In the interleaved fashion, two or more ADCs are placed in parallel and their samples are time-interleaved by a multiplexer. The overall sampling frequency of the system must verify Nyquist sampling theorem which states
fs ≥ BW + Δf (1)
where BW is the signal bandwidth and Δf is the extra
ADC0
ADC1
ADC2
ADCM-1
x(t) x(n)
(Mn+0)Ts+r0Ts
(Mn+1)Ts+r1Ts
(Mn+2)Ts+r2Ts
(Mn+M-1)Ts+rM-1Ts
MUX
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undesired spectral components from the interleaved time series replicas do not sum to zero. The sample instants of the two ADCs are, in fact, affected by a constant delay, Δtm with m = 0, 1, which results in an undesired frequency dependent phase offset of their aliased spectra which prevents them from being cancelled perfectly at the output of the time multiplexer. The gain mismatch contributes a frequency independent imperfect cancellation of the spectral components at the output of the TI-ADC system.
The effects of gain and time mismatches in a two channel TI-ADC are illustrated in Figure 4 while Figure 5 and Figure 6 show, using Matlab simulations, the effect of timing and gain mismatches on the output spectra of a two-channel TI-ADC. The ideal TI-ADC case, shown in Figure 5, shows perfect cancellation of the aliased replica occurs because of the absence of mismatches. The real case, shown in Figure 6, shows the effects of timing and gain mismatches which cause the imperfect cancellation of the aliased signal replicas from the second Nyquist zone which are clearly visible on the desired spectrum. In both the plots we used a combination of sine waves as a sample spectrum in order to show clearly, on the desired spectrum, the aliased replicas derived from the mismatches.
MISMATCHES IDENTIFICATION & CORRECTION
Our goal is to correct the effects of timing and gain offset in the sampled data domain. In order to do this, we must first estimate them. Estimation methods are divided into two categories:
• Foreground techniques, also known as non-blind, that inject a known test or probe signal to estimate the mismatches by measuring the TI-ADC output responses to the probe.
• Background techniques, also known as blind, for which no information is required about the input signal (except perhaps some knowledge about the presence or absence of signal activity in certain frequency bands) in order to estimate the mismatches.
The first approach has the disadvantage that normal TI-ADC operations are suspended during the probe but in the second approach the calibration process does not interrupt normal TI-ADC operations.
There are many papers present in the literature that use either blind or non-blind estimation and correction methods in a two-channel TI-ADC [2], [4]. In [2], the authors estimate time mismatches by means of an
Figure 4: Pictorial View of the Effects of Time and Gain Mismatches in a Two-Channel TI-ADC
-Ωs -Ωs
2Ωs
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adaptive approach based on the least-mean-square (LMS) algorithm. The input signal spectrum is assumed to be low-pass and slightly oversampled. This last hypothesis creates a mismatch band containing only undesired alias components. The total demonstrated improvement of aliased to non aliased spectral level ratio achieved by this technique is approximately 26dB. The structure presented in [2] has been generalized to the M-channel TI-ADC case in a more recent paper [3]. In [4] the authors present an adaptive filtering structure that uses three fixed FIR filters and two adaptive gain and delay parameters to perform the calibration. The assumptions on the input signal are the same as in [2] that it is a slightly oversampled low-pass signal. This structure achieves <26dB of improvement. All the
estimation and correction structures in the above cited papers are derived assuming the input signal has a low-pass nature.
The solution we propose is completely independent of the signal spectrum and of the selected overall TI-ADC sampling frequency, hence it works also in the case of band-pass signals for which sparse sampling (sub-sampling) is applied.
Figure 7 shows the block diagram of a two-channel TI-ADC followed by an estimation and compensation structure for both, gain and timing mismatches which operates in the digital domain.
The identification and compensation component is detailed in Figure 8. The architecture is based on the structures derived in [2] and [3]. It is based on the assumptions that the timing offsets are small relative to the overall sampling period, Ts, and their average value is zero. We will present several important modifications to this structure that allow us to correct channel mismatches when low-rate sampling is applied to sparse signals.
Figure 5: Spectrum of the Output Signal of an Ideal Two-Channel TI-ADC
Figure 6: Spectrum of the Output Signal of a Real Two-Channel TI-ADC
Figure 7: Proposed Solution Scheme for the Two-Channel TI-ADC
Figure 8: Commonly Used Identification and Correction Structure for a Two-Channel TI-ADX
Note that the basic observation that underlies the existing structure, depicted in Figure 8, is that by oversampling the input signal x(t) with a TI-ADC in which no mismatches occur, we should be able to observe some spectral regions where no signal energy is present. However, because of gain and time offsets between the two channels, a certain amount of undesired energy appears in these bands (called mismatching bandwidths). By filtering and minimizing the amplitude of the signal spectrum in the mismatching bandwidths it is possible to adaptively identify and correct both the mismatches and for this purpose the LMS algorithm is a natural option. The assumption of the low-pass nature
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of the input signal, along with the knowledge of the sampling frequency, allows us to predict the position of the mismatching bandwidths and to design high-pass filters to isolate, monitor, and correctly process these spectral regions.
to a gap between the maximum frequency component of the signal, fmax, and fs/2 that is bigger than the gap between the zero frequency and the minimum signal component, fmin, in the first Nyquist zone. This hypothesis is commonly discarded because it implies a waste of bandwidth.
When a two channel TI-ADC is used, the same sampling frequency fs0,1=fs/2 is used on each arm with a time shift of the initial sampling time in one of the arms equal to 1/fs. These sampling frequencies violate Nyquist sampling theorem and, as a consequence of that, the negative side of the replica that resides in the second Nyquist zone appears in the first Nyquist zone. This replica should be automatically suppressed at the output of the multiplexer if no mismatches are present in the structure. We specified before that when fIF/fs=1/4, Δf/2 represents the gap between fmax, the maximum frequency of the input signal, and fs0,1. It also represents the gap between the zero frequency and the minimum frequency of the negative replica coming from the second Nyquist zone. In this case, the two replicas, the positive one belonging to the first Nyquist zone and the negative one belonging to the second Nyquist zone, will perfectly overlap on each other and it is difficult to visualize the mismatches caused by the time and gain offset. In the case in which Δf <2fIF-BW the negative side of the signal replicas belonging to the second Nyquist zone will partially overlap on the positive signal
Figure 9: Graphical Example of Signal Spectrum After Sampling
We recall here that in a common digital receiver, with only one analog-to-digital converter, the sampling frequency is selected in order to satisfy the equality in Eq. (1) where Δf is called oversampling factor. Note that it represents the gap between the two signal spectra replicas after sampling (see Figure 9). It is our desire to make this factor as small as possible, compatible with the requirements for the subsequent filtering tasks that the digital receiver has to handle. In a practical receiver usually
0 < Δf ≤ 2fIF - BW (2)
It is most common to have quarter-rate sampling: fIF/fs=1/4. Note that the case Δf >2fIF-BW corresponds
Figure 10: Subplot 1: Spectrum at the Output of TI-ADC Affected by Gain and Time Mismatches; Subplot 2: Spectrum at the Output of the Identification and Correction Structure
fsfIF
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TI-ADC Output Spectrum
Compensated TI-ADC Output Spectrum
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B]
MissingTone
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part belonging to the first Nyquist zone; it will be, in fact, closer to zero. It is clear that, for both the cases specified above, we will not have undesired energy between fmax, and fs0,1. This is exactly the spectral region in which the mismatching bandwidths have been defined and for which the current TI-ADC identification and correction structures have been designed. And this is also the reason for which the current architectures do not work for IF-sampling communication scenarios. Moreover, the location of the mismatching bandwidths becomes even more unpredictable when low-rate sampling is applied. external side (high frequencies) of the signal spectrum;
by using the proposed estimation and compensation structure we are able to reduce its energy below 90dB. This value is indicated by the dotted red line in the figure.
Figure 11 shows the convergence behavior of the estimation process. The LMS error is minimized when the timing and gain errors converge to their correct values. The chosen step for the LMS algorithm in this example is μ=0.04. Because the LMS algorithm has been applied to minimize the energy of a deterministic sine tone, the converged value of the error has zero mean with zero variance. In the second subplot of Figure 11, the convergence behavior of the weights associated with the timing error is shown. Similarly, the third subplot of Figure 11 shows the convergence process of the weights associated with the gain error estimation; the process converges after 200 samples to 0.025 which is the theoretical expected value corresponding to the average value of the ADCs gains.
In order to demonstrate the degree of mismatch suppression which we cannot see directly in the spectral plots, we compare in Figure 12 the demodulated QPSK constellation (after correction) with the transmitted one. The demodulation process is achieved by passing the signal through a Hilbert transform, which gives us access to the analytic signal and its complex envelope. The signal is then down converted by a complex heterodyne in a digital down converter. Finally, the matched filter, with the proper time alignment, but not phase correction, is applied to the complex base-band signal to maximize its signal to noise ratio. The constellation resulting from this process is shown in the third subplot of Figure 12 along with the transmitted QPSK constellation in the first subplot and the corrupted QPSK constellation at the output of TI-ADC in the second subplot. It is clearly shown that the TI-ADC mismatches result in an increased variance cloud around the matched filter output constellation points. The variance
Figure 11: Subplot 1: Convergence Behavior and Estimated LMS Error; Subplot 2: Estimated Gain Error; Subplot 3: Estimated Timing Error
We have developed a general solution that is independent of the modulation format, signal bandwidth and overall selected sampling frequency. By using our solution, we are able to push the level of the artifacts below 80dB which is a unique result in this field (see references at the end of this section).
In the first subplot of Figure 10 the spectrum of a QPSK signal processed by a two-channel TI-ADC with gain and time offsets is shown. The timing offsets for this example are r0=0 and r1=0.04 which corresponds to a 4% error on the overall sampling time. Note that this time offset is quite large if compared to a realistic scenario but, also for this extreme case, the identification and correction structure still provides good attenuation levels. The selected gain offsets for this example are g0=0 and g1=0.05 which corresponds to a 5% error on the second arm of the TI-ADC. Note that the QPSK signal replica that should belong to the second Nyquist zone appears in the first one. This replica is completely superimposed on the information signal and, for this reason, it is not possible to demonstrate its presence on this signal spectrum. In the second subplot of Figure 8 the signal spectrum at the output of the compensator is shown. In this figure, the tone we inserted for testing the functionality of the structure, is not present on the
Figure 12: Subplot 1: Transmitted QPSK Constellation, Subplot 2: Effect of Gain and Timing Mismatches on the Transmitted QPSK Constellation; Subplot 3: Effect of the Correction Structure on the Output QPSK Constellation of the TI-ADC
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clouds are completely removed by using the proposed structure.
In Figure 13 we generated 17 equally spaced sine waves spanning frequencies from 0.1 to 0.4 on the normalized frequency axis. The gain and time errors are the same as those used in the previous simulations. The combined effects of time and gain offsets can be visualized in the first subplot of Figure 13 where the folded spectrum, coming from the second Nyquist zone and unsuppressed at the output of the multiplexer, appear between the spectral line of the constructed information signal. The second subplot of Figure 13 shows the spectrum obtained after compensation. Here we can clearly recognize that the spectral artifacts are significantly reduced. We also note a residual
Figure 13: Subplot 1: Sine Wave Spectrum at the Output of TI-ADC Affected by Gain and Time Mismatches with Superimposed Derivative and High-Pass Filters; Subplot 2: Sine Wave Spectrum at the Output of the Identification and Correction Structure
Figure 14: Subplot 1: Convergence Behavior and Estimated LMS Error for the Sine Wave Spectrum; Subplot 2: Estimated Gain Error; Subplot 3: Estimated Timing Error
spectrum containing the artifact remnants that were not suppressed to the same degree as the probe signal. These artifacts are below -90dB as demonstrated by the dotted red line in the same picture. Note that before compensation, the maximum amplitude, on log scale, of the spurious peaks affecting the signal is -30.2dB; after compensation their maximum amplitude is -90dB. This result clearly demonstrates that our structure is capable of obtaining improvement of approximately 60dB.
For completeness, Figure 14 shows the LMS convergence behavior, along with the time and gain offsets estimation for the sine waves spectrum case. The μ value used for the LMS algorithm embedded in the identification structure is the same as in the simulation of Figure 10.
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REFERENCES
[1] fred harris, Multirate Signal Processing, Prentice Hall, 2004.
[2] S. Saleem and C. Vogel, “LMS-based identification and compensation of timing mismatches in a two-channel time interleaved analog-to-digital converter”, in Proc. IEEE Norchip Conf., pp. 14, November 2007.
[3] C. Vogel, S. Saleem, and S. Mendel, “Adaptive blind compensation of gain and timing mismatches in M-channel time interleaved ADCs,” in Proc. 14th IEEE ICECS, pp. 4952, September 2008.
[4] S. Huang, B. C. Levy, “Adaptive blind calibration of timing offset and gain mismatch for two-channel time-interleaved ADCs,” IEEE Trans. on Circuits and Systems-I: Regular Papers, vol. 53, no. 6, pp. 1278-1288, June 2006.
[5] P. Satarzadeh, B. C. Levy, and P.J. Hurst, “Adaptive Semi-blind Calibration of Bandwidth Mismatch for Two-Channel Time- Interleaved ADCs,” IEEE Trans. on Circuits and Systems-I: Regular Papers, vol. 56, no. 9, September 2009.
[6] J. Goodman, B. Miller, M. Herman, G. Raz and J. Jackson, “Polyphase Nonlinear Equalization of Time-Interleaved Analog-to-Digital Converters,” IEEE Journal of Selected Topics in Signal Processing, vol. 3, no. 3, June 2009.
[7] F. Palmieri, E. Venosa, A. Petropulu, G. Romano and P. Salvo Rossi, “Sparse Sampling for Software Defined Radio Receivers”, Proc. of SPAWC 2010 - 11th IEEE International Workshop on Signal Processing Advances in Wireless Communications, June 20-23 2010, Marrakech, Morocco.
[8] E. Venosa, fred harris and F. Palmieri, “Software Radio: Sampling Rate Selection, Design and Synchronization,” Springer Science + Business Media, LLC 233 Spring Street, New York, NY 10013, USA, 2011.
[9] F. Palmieri, E. Venosa, G. Romano, P. Salvo Rossi and A. Petropulu, “On Low-Rate Uniform Sampling of Digital Communication Signals,” submitted to EURASIP Journal on Wireless Communications and Networking.
[10] Mikko Waltari and Kari Halonen, Circuit Techniques for Low-Voltage and High-Speed A/D Converters, Kluwer Academic Publishers, 2002.
About the Author
Elettra Venosa received the “Laurea” (BS/MS) de-gree (summa cum laude) in electrical engineering in January 2007 from Seconda Università degli Studi di Na-poli, Italy. From January 2007 to November 2007 she was a researcher at the Italian National Inter-University Con-sortium for Telecommunications. In November 2010, she received the Ph.D. in Telecommunication/DSP from Seconda Università degli Studi di Napoli, Italy. From June 2008 to September 2008 she worked as a project manager for Kiranet s.r.l.- ICT Research Centre – to de-velop an advanced radio identification system for avi-onics, in collaboration with the Italian Center for Aero-space Research (CIRA). From April 2009 to September 2009 she worked at Communications and Signal Pro-cessing Laboratory (CSPL) in the department of Elec-trical and Computer Engineering at Drexel University, Philadelphia, PA, USA where she focused on sparse sampling techniques for software defined radio receiv-ers. Currently, she is working, as a system engineer in IQ-Analog Corp., a semiconductor company located in San Diego, CA, USA. Currently, she is also working, as a postdoctoral researcher, on multirate signal process-ing techniques for software defined radio design in the department of Electrical and Computer Engineering at San Diego State University, San Diego, CA, USA. She is author of the book “Software Radio Sampling Rate Se-lection, Design and Synchronization.” ■
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Single or Multiple Cell Li-ion Battery Powered 4-Channel and 6-Channel LED DriversISL97692, ISL97693, ISL97694AThe ISL97692, ISL97693, ISL97694A are Intersil’s highly integrated 4- and 6-channel LED drivers for display backlighting . These parts maximize battery life by featuring only 1mA quiescent current, and by operating down to 2.4V input voltage, with no need for higher voltage supplies.The ISL97692 has 4 channels and provides 8-bit PWM dimming with adjustable dimming frequency up to 30kHz. The ISL97693 has 6 channels with Direct PWM dimming control. The ISL97694A has 6 channels and provides 8-, 10-, or 12-bit PWM dimming with adjustable dimming frequency up to 30kHz, 7.5kHz, or 1.875kHz, respectively, controlled with I2C or PWM input. ISL97692 and ISL97694A feature phase shifting that may be enabled optionally, with a phase delay between channels optimized for the number of active channels. In ISL97694A, phase shifting can multiply the effective dimming frequency by 6 allowing above-audio PWM dimming with 10-bit dimming resolution.
The ISL97692/3/4A employ adaptive boost architecture, which keeps the headroom voltage as low as possible to maximize battery life while allowing ultra low dimming duty cycle as low as 0.005% at 100Hz dimming frequency in Direct PWM mode.
The ISL97692/3/4A incorporate extensive protection functions including string open and short circuit detections, OVP, and OTP.
The ISL97692/3 are offered in the 16 Ld 3mmx3mm TQFN package and ISL97694A is offered in the 20 Ld 3mmx4mm TQFN package. All parts operate in ambient temperature range of -40°C to +85°C.
Features• 2.4V Minimum Input Voltage, No Need for Higher Voltage
Supplies
• 4 Channels, up to 40mA Each (ISL97692) or 6 Channels, up to 30mA Each (ISL97693/4A)
• 90% Efficient at 6P5S, 3.7V and 20mA (ISL97693/4A)• Low 0.8mA Quiescent Current
• PWM Dimming Control with Internally Generated Clock
- 8-bit Resolution with Adjustable Dimming Frequency up to 30kHz (ISL97692/4A)
- 12-bit Resolution with Adjustable Dimming Frequency up to 1.875kHz (ISL97694A)
- Optional Automatic Channel Phase Shift (ISL97692/4A)- Linear Dimming from 0.025%~100% up to 5kHz or
0.4%~100% up to 30kHz (ISL97692/4A)• Direct PWM Dimming with 0.005% Minimum Duty Cycle at
100Hz• ±2.5% Output Current Matching
• Adjustable Switching Frequency from 400kHz to 1.5MHz
Applications• Tablet, Notebook PC and Smart Phone Displays LED
Backlighting
Related Literature (Coming Soon)• AN1733 “ISL97694A Evaluation Board User Guide”
• AN1734 “ISL97693 Evaluation Board User Guide”
• AN1735 “ISL97692 Evaluation Board User Guide”
FIGURE 1. ISL97694A TYPICAL APPLICATION DIAGRAM FIGURE 2. ULTRA LOW PWM DIMMING LINEARITY
FSW
FPWM
AGND
OVP
VIN
SDA/PWMI
ISET
COMP
SCL
D1
CH1
CH2
CH3
CH4
PGND
LX
VIN: 2.4V~5.5V VOUT: 24.5V, 6 x 20mA
CH5
CH6
L1
10µH
12k15nF
10
1µF
4.7µF4.7µF
470k
23.7k
143k
291k
53k
100pF
2.2nFISL97694A
4.7µF
EN
0.0001
0.001
0.01
0.1
1
10
0.001 0.01 0.1 1 10INPUT DIMMING DUTY CYCLE (%)
ILED
(mA
)
fPWM: 200Hz
fPWM: 100Hz
July 19, 2012FN7839.2
Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright Intersil Americas Inc. 2012All Rights Reserved. All other trademarks mentioned are the property of their respective owners.
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Meenu SarinDirector - VLSI Consultancy
POWERFAB
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Meenu SarinDirector - VLSI Consultancy
POWERFAB
Looks like the scarling down road for the fabless – foundry model is getting bumpier. First, the high cost of setting up new fabs made the earlier IDMs get into the “fab lite” model where they depend upon the pure-play foundries for the basic process capacity and do the specialized process add-ons in-house to get the competitive advantage. The fab-less companies coupled with pure-play foundries and gained prominence. The industry seemed to have found a way out (at least temporarily) of the high cost challenges of scaling down coupled with the issues of designing multi-million gates chips with increasing features and decreasing time to market window.
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But now the speed breakers on this road are getting frequent and higher. Take the last couple of examples. FD-SOI is one of the new transistor architectures thrown up by ST/ST-Ericsson for scaling down 28nm and below. The process is reported to give a 35% power performance gain and that was also by a simpler process transition from the typical CMOS. However, ST lacks the capacity and hence is exploring options with GlobalFoundries. The latter is reportedly insisting that it will use ST’s process to make parts for all other parties too, in exchange for this extra capacity – leading to ST/ST-E potentially losing on a big competitive edge of sole access to a proprietary process through its FDSOI process.
The second recent example is of Qualcomm. The world’s largest fabless company uses TSMC‘s 28nm process to manufacture its Snapdragon S4. The world’s largest pure play foundry has also had yield/capacity issues on this node.
TSMC’s 28nm foundry capacity woes have put a dampener in the presently exclusive run of Qualcomm – the sole provider of integrated multimode 3G/4G LTE baseband chips. It ripples further down the chain causing distress to LTE smart-phone vendors. Shortage
is not expected to cease before Q4’12. Qualcomm is now planning a 23% increase in operating expenses this year and looking for alternative (apart from TSMC) suppliers. It has very recently signed up UMC and Samsung as second suppliers for 28nm.
Incidentally, TSMC’s sales hit an all-time high (9.1% annual revenue growth) in April’12 – with much of the strong growth attributed to 28nm demand!
So where does this leave the fabless-foundry model? And how does this affect the IDMs?
One thing for sure is that the model will need to be tweaked in order to stand up to the sub 28nm/20nm challenges. Some pointers:
• Cost advantage of scaling down is diminishing for the foundries. The cost-per-transistor has been about 29% per node leading to cheaper scaled down chips. 28nm and sub has seen that leveling off for the foundries. Intel still has a relatively big lead in the process race. If the fabless companies do not see a steady decline in the cost-per-transistor in their foundries’ scaling, it certainly puts a spoke in their wheel continuing down on the scaling path with this model.
2011 Top 25 Fabless IC Suppliers ($M)2011Rank
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
* Represents the 50% share no accounted for by ST.
Source: Company reports, IC Insights’ Strategic Reviews Database
2010Rank
1
2
3
6
4
5
7
8
9
10
13
11
15
12
16
17
27
19
18
21
33
22
29
23
24
Top 25 Total
Non-Top 25 Fabless
Total Fabless
2009Rank
1
3
2
5
6
4
7
10
8
11
12
13
16
9
15
17
67
19
14
-
30
21
20
24
23
Company
Qualcomm
Broadcom
AMD
Nvidia
Marvell
MediaTek
Xilinx
Altera
LSI Corp.
Avago
MStar
Novatek
CSR
ST-Ericsson*
Realtek
HiSilicon
Spreadtrum
PMC-Sierra
Himax
Lantiq
Dialog
Silicon Labs
MegaChips
Semtech
SMSC
–––
–––
–––
Headquarters
United States
United States
United States
United States
United States
Taiwan
United States
United States
United States
Singapore
Taiwan
Taiwan
Europe
Europe
Taiwan
China
China
United States
Taiwan
Europe
Europe
United States
Japan
United States
United States
–––
–––
–––
2009($M)
6,409
4,271
5,403
3,151
2,690
3,500
1,699
1,196
1,422
858
838
819
601
1,263
615
572
105
496
693
0
218
441
445
254
283
38,242
11,091
49,333
2010($M)
7,204
6,589
6,494
3,575
3,592
3,590
2,311
1,954
1,616
1,187
1,065
1,149
801
1,146
706
652
346
635
643
550
297
494
337
403
397
47,733
14,781
62,514
%Change
12%
54%
20%
13%
34%
3%
36%
63%
14%
38%
27%
40%
33%
-9%
15%
14%
230%
28%
-7%
N/A
36%
12%
-24%
59%
40%
25%
33%
27%
2011($M)
9,910
7,160
6,568
3,939
3,445
2,969
2,269
2,064
2,042
1,341
1,220
1,198
845
825
742
710
674
654
633
540
527
492
456
438
415
52,076
12,811
64,887
%Change
38%
9%
1%
10%
-4%
-17%
-2%
6%
26%
13%
15%
4%
5%
-28%
5%
9%
95%
3%
-2%
-2%
77%
0%
35%
9%
5%
9%
-13%
4%
EEWeb PULSE TECH ARTICLE
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• The prohibitive high cost of setting up a new fab and the related R&D and yield challenges just does not make sense for a fabless company—even Qualcomm—to start one. Owning a pre-planned and negotiated capacity or even production means with an existing foundry is viable, but a fab from scratch does not appear to be reasonable.
• With the increasing yield issues at smaller geometries pitched along with capacity shortage and uncertain market demand, a stronger vertical integration of supply chain may become the order of the day to sustain the fabless model – one which accounted for $64.9 billion in 2011. While expecting to resolve 28nm capacity shortage by Q4, TSMC has raised this year’s capex 42% to USD 8.5 billion to ride the market opportunities.
• Rewinding to one of my earlier blog posts (Jan 2008) in “Travelling on the Silicon Road,” I had cited a remark by Infineon’s CEO, Ziebart in an interview to EE Times’ Rick Merritt, “The major thing giving semiconductor makers a competitive advantage has evaporated. Today everyone has access to the same process technology at roughly the same time. This access used to be what differentiated the best from the worst semiconductor companies, but now it has evaporated. What’s replacing process technology as a differentiator is systems know-how, and it must be specific to a market area”. My comment to that, as also mentioned in the same post, was: Yes, the differentiator has moved from process technology; but it is due to access to the process technology. This access has become cost prohibitive for any single semiconductor company (perhaps leaving aside a couple with really deep pockets) and hence the scramble to find an alternate place in the value chain to survive. That access to the process technology is now morphing, if not under threat.
• GlobalFoundties’ SVP Mojy Chian mentioned that “New challenges at 20nm and beyond will require deep, IDM-like collaboration to accelerate the time-to-market”. Now, does this mean that foundries will transition towards virtual IDMs? Rewind to another earlier blog post (Dec 2007): “Over the last couple of years, we have seen IDMs going towards fablite and fabless models, and the emerging dominance of the original pure play foundries. I say “original” as lately, these foundries have been paving their way into newer territories like climbing up the design support value chain by increasing their IP portfolio, collaborating with EDA vendors for providing yield related data/information to the designers and reference design flows, and others – just short of coming up with their own ASSPs. So will
we see the re-emergence of real IDMs albeit in the form of a morphed foundry? IDMs, foundries, fabless… they are all morphing from their original identities and are reshaping the industry with their redefined (work in progress) grey and diffused boundaries.
However, one thing stands tall amidst all this and that is “The “Fab power’ is increasingly getting honed into the semiconductor eco-system lately.” Fab matters.
About the AuthorMs. Meenu Sarin is a microelectronics professional with a career spanning over 22 years and traversing across all aspects of the Semi-custom Business including Library Design & management, Program Management, Technical Marketing & Business Development, Consulting, Market and Technology trends research and analysis - and across geographies like Europe, India, Singapore, Greater China and Australia. After working with STMicroelectronics for around 14 years, she registered her company, VLSI Consultancy, in Singapore from where she consults offering techno-commercial services to the semiconductor industry. This includes Training (corporate and public), Market & Technology intelligence (research & analysis) and Business Development Support (Technical Marketing, Social Media Marketing). She is also a founding member and an Executive Board Member of the Singapore Semiconductor Industry Association. From 1997-2002, Meenu was a Technical Marketing Manager in STMicroelectronics (STM)/Singapore with focus on Telecom segment. In this role, she was responsible for Business Development and Program Management for STM’s semicustom ASIC projects in Asia Pacific. Meenu also worked as a Program Manager in charge of managing various semi-custom projects with customers in the Asia-Pacific Region. Before her move to STM Singapore, Meenu worked at STM India from 1991 to 1997. As a Design Manager for Library Design Group, she was responsible for growing and managing a 30 member strong team involved in design and development of semi-custom digital libraries in various technologies across different platforms as per the market requirements and to support designers in STM’s worldwide locations. Prior to this, Meenu had been a Design Engineer for digital library design and development at STM Italy for several years after she received her engineering degree (Computer Engineering) from Delhi Institute of Technology, India in 1988. ■
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