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Power Management
Texas Instruments Incorporated
Power-management solutions for telecom
systems improve performance, cost, and size
By Brian C. Narveson,
Analog Applications Manager, Power Marketing Development – High Performance Analog Group,
and Adrian Harris,
Application Specialist, Plug-In Power – High Performance Analog Group
Deregulation and competition in wire line and wireless
infrastructure telecommunications systems have acceler-
ated the need for lower-cost equipment solutions with ever-
increasing bandwidth. The challenge of power-management
requirements for telecom equipment continues to grow.
Increasingly, designers are asked to provide more voltage
rails for a variety of digital signal processors (DSPs), field
programmable gate arrays (FPGAs), application-specific
integrated circuits (ASICs), and microprocessors. In short,
they are required to generate more voltages, at higher cur-
rents, more efficiently, with less noise, in a smaller space.
And, if that isn’t challenge enough, the solution has to cost
less, too!
Deploying access equipment closer to the subscriber
requires smaller enclosures (pad and pole mounting) that
must survive in a tougher environment. Infrastructure
equipment is being designed for smaller footprints, as
central office space comes at a premium. Factors driving
power management are size, thermal management, cost,
and electrical performance (regulation, transient response,
and noise generation). This article provides a basic under-
standing of the evolution of board-mounted power systems,
and how the latest generation can achieve higher perform-
ance and lower cost—in a smaller footprint.
Size/efficiency/cost
The need to address size, efficiency, and cost simultane-
ously has ignited renewed interest in power architectures.
The first generation of board-mounted power used a power
architecture known as a distributed power architecture
(DPA) (see Figure 1). This architecture used an isolated
(brick) power module for every voltage rail. It worked well
when there were limited rails, but cost and PCB space
increased significantly with each added voltage rail.
Sequencing of the voltage rails also was difficult and
required adding external circuitry, which in turn increased
cost and board space.
To deal with the size and cost constraints of DPA, second-
generation systems moved to a fixed-voltage intermediate
bus architecture (IBA) (Figure 2). An IBA uses a single,
isolated-brick power module and many nonisolated, point-
of-load (POL) DC/DC converters. The POLs can be either
power modules, such as the Texas Instruments (TI) PTH
series, or discrete buck converters. The isolated converter
works over the same input-voltage range as the first gen-
eration, either 36 to 75 V or 18 to 36 V. It creates an IBA
supply that is regulated to 3.3 V, 5 V, or 12 V. The voltage
choice is up to the system designer. This design results in
less board space, lower cost, and easier sequencing of the
Figure 1. Typical DPA architecture
Isolated
DC/DC
48 V
+3.3Vat5A
Isolated
DC/DC
48 V
+2.5 V at 6.5 A
Isolated
DC/DC
48 V
+1.8Vat11A
Isolated
DC/DC
48 V
+1.2Vat20A
Figure 2. Fixed-voltage IBA
Point
of
Load
PTH
12 V
Isolated
DC/DC
+3.3Vat5A
48 V
Point
of
Load
PTH
+2.5 V at 6.5 A
Point
of
Load
PTH
+1.8Vat11A
Point
of
Load
PTH
+1.2Vat20A
Auto-Track
TM
10
Analog Applications Journal
High-Performance Analog Products
www.ti.com/aaj
3Q 2007
Texas Instruments Incorporated
Power Management
voltages due to features such as TI’s Auto-Track™. The
only drawback of this architecture is reduced efficiency
due to the double conversion required for each voltage.
Today, most telecom systems use a fixed-voltage IBA.
However, a higher-efficiency and smaller-footprint solution
is needed as access-equipment designs evolve to sealed
enclosures with no forced air cooling. As every designer
knows, the best way to get rid of heat in a system is not to
create it. The main focus for improving efficiency is the
front-end isolated converter, since all of the power goes
through it. The proven way to increase isolated-converter
efficiency is to run the converter at a fixed duty cycle and
not regulate the output. This method led to the unregu-
lated intermediate bus architecture (Figure 3).
This architecture uses an unregulated bus converter
that creates an output voltage as a ratio of the input volt-
age. In the example, an ALD17 5:1 converter creates an
output voltage that is
1
Figure 3. Unregulated IBA
Isolated
ALD17
5:1
1/16
150 W
Point
of
Load
T2
~9.6 V
36 to
55 V
+3.3Vat5A
Point
of
Load
T2
+2.5 V at 6.5 A
Point
of
Load
T2
+1.8Vat11A
/
Point
of
Load
T2
5
of the input. This technique allows
a 150-W system/board to be designed with a
1
/
+1.2Vat20A
16
brick,
achieving 96% efficiency for the first conversion stage.
Unregulated voltage became possible when wide-input
(4.5- to 14-V) PWMs and power modules such as TI’s T2
products were introduced. This architecture is limited by
the bus converters’ maximum input range of 36 to 55 V to
keep the input voltage to POLs less than 12 V. The 12-V
maximum is necessary because, for POLs to generate
output voltages of 1 V or less, the input voltage cannot
exceed 10 to 12 times the output. However, an increasing
number of telecom original equipment manufacturers
(OEMs) are considering a move to this limited input range
for the significant cost savings, size reduction, and effi-
ciency improvements obtained with this architecture.
Some telecom OEMs insist on maintaining the traditional,
wider input-voltage specification of 36 to 75 V with input
transients of up to 100 V. For these requirements, the
power industry has responded with the quasiregulated
IBA (Figure 4). The main difference between this and the
unregulated IBA is that if the input voltage exceeds 55 to
60 V, the quasiregulated IBA regulates the output voltage
to around 10 V. The drawback of this approach is that the
isolated power module must increase in size to accommo-
date the regulation circuitry, and its efficiency is reduced
when the input voltage exceeds 55 V. An example of this
kind of product is the TI PTQB series.
Auto-Track
TM
SmartSync
Figure 4. Quasiregulated IBA
Isolated
PTQB
6:1
1/4
>200 W
Point
of
Load
T2
~8 V
36 to
75 V
+3.3Vat5A
Point
of
Load
T2
+2.5 V at 6.5 A
Point
of
Load
T2
+1.8Vat11A
Point
of
Load
T2
+1.2Vat20A
Auto-Track
TM
SmartSync
11
Analog Applications Journal
3Q 2007
www.ti.com/aaj
High-Performance Analog Products
Power Management
Texas Instruments Incorporated
Architecture comparison
To provide a meaningful comparison, each example in
Figures 2, 3, and 4 has identical output-voltage and current
requirements. The examples are based on a theoretical
base station utilizing multiple high-performance DSPs with
associated analog and digital circuits. The output voltages
are 3.3 V at 5 A, 2.5 V at 6.5 A, 1.8 V at 11 A, and 1.2 V at
20 A. For a comparison of the architectures described
earlier, see Figure 5. The graphs indicate that the ultimate
dream is indeed possible. A quasiregulated or unregulated
power system can provide higher efficiency in less space
at lower cost. The most notable improvement of the quasi/
unregulated IBA over the second-generation, fixed-voltage
IBA is efficiency. As shown in Figure 5, power-conversion
efficiency increased by almost 7%. This translates to a
thermal load reduction of 14 W for a 200-W system.
Power modules were used in these examples because
they provide the greatest power density and are the solu-
tion of choice at many telecom OEMs. Discrete POLs can
be used in all systems to reduce cost, but the board space
will increase by a factor of two.
Electrical performance
The remaining challenge for the designer is to meet the
increasing electrical demands of the high-performance
DSPs and ASICs at the heart of each system. Primary
performance issues are voltage regulation, current transient
response, and noise.
Regulation and current transient response are closely
linked. To get higher performance with lower power in a
smaller size, digital semiconductors are fabricated with
smaller-geometry transistors that require ever-decreasing
voltages. Sub-1-V core-voltage requirements are now
becoming the standard. Along with this low voltage have
come increasingly tighter tolerances. It is now common
practice to specify a total voltage tolerance of 3% that
includes line (variations in input voltage), load (small
deviations in load current), time, temperature, and current
transients. This leaves the power designer with only 30 mV
of headroom to accommodate everything the digital system
requires. About half of the tolerance budget (15 mV) is
usually absorbed by the DC parameters of line, load, time,
and temperature. The remaining 15 mV is then available to
deal with sudden changes in current (1 to 3 clock cycles)
due to computational or data-transmission loads.
This tolerance budget challenges the power-system
designer to minimize voltage deviation in the presence of
these current transients. If the core voltage (V
CC
) exceeds
the specified tolerance limits, the digital IC may initiate a
reset or have logic errors. To prevent this, designers need
to pay close attention to the transient performance of the
Figure 5. Comparison of architectures
140
120
128
100
80
60
80.3
75.30
69.3
40
20
0
DPA
Fixed-
Voltage
Quasi-
regulated
Unregu-
lated
Architecture
(a) Cost comparison
10000
8000
8288
6000
4000
4286
3578
2000
2542
0
DPA
Fixed-
Voltage
Quasi-
regulated
Unregu-
lated
Architecture
(a) Board size comparison
88.0
87.40
87.28
86.0
84.0
82.0
80.74
80.0
78.0
DPA
Fixed-
Voltage
Unregu-
lated
Architecture
(a) System efficiency comparison
12
Analog Applications Journal
High-Performance Analog Products
www.ti.com/aaj
3Q 2007
Texas Instruments Incorporated
Power Management
POL modules being used. Digital loads such as the latest
gigahertz DSPs require extremely fast transient responses
with very low voltage deviation. To achieve these targets,
many additional output capacitors are usually added to
the DC/DC converter to provide hold-up time until its
feedback loop can respond. The power module, including
this added capacitance to meet transient-voltage toler-
ances, represents the complete power solution.
Capacitors have been evolving over the years, with volu-
metric efficiencies getting better all the time. Even with
higher volumetric efficiency, the overall power solution
can be over twice the size of the power module alone. This
requires a large allocation on the PCB that is usually not
available in today’s physically smaller systems. What’s
more, the cost of power-supply materials can be more
than double the cost of the power module when the cost
of capacitors is added in.
With innovations in DC/DC power-module technology,
system designers now are able to achieve faster transient
response and less voltage deviation while using less output
capacitance. An example is the T2 series next-generation
PTH modules (Figure 6) from TI. These devices incorpo-
rate a new patented technology called TurboTrans™ that
allows custom tuning of the module to meet a specific
transient-load requirement. Tuning is accomplished with a
single external resistor.
TurboTrans can achieve up to an eightfold reduction in
output capacitance, which lowers the cost of capacitors and
saves PCB space. Another benefit of this technology is that
using a capacitor with ultralow equivalent series resistance
(ESR) provides enhanced module-circuit stability. These
newer Oscon, polymer-tantalum, and ceramic output capac-
itors have the additional benefit of being able to withstand
high-temperature, lead-free soldering processes.
The final performance hurdle for isolated and POL
converters is noise. When switching POLs run at different
frequencies and share a common input bus, frequencies
resulting from the sum and difference of those frequencies
can create beat frequencies that make EMI filtering difficult.
Figure 6. T2 series power modules
with TurboTrans™
As an example, if a system has two POLs with one operating
at 300 kHz and a second at 301 kHz, the beat frequency is
1 kHz. This can require larger, more complex system filters.
T2 power modules from TI have a SmartSync feature that
lets the designer synchronize the switching frequency of
multiple T2 modules to a specific frequency, which elimi-
nates beat frequencies and makes EMI filtering easier.
SmartSync can be used to set the frequency so that switch-
ing noise is minimized in a particular frequency band (i.e.,
xDSL transmission frequencies). TurboTrans and SmartSync
are standard features on T2 power modules that add no
additional cost to the systems described earlier.
A telecom system built with state-of-the-art power
modules allows the system designer to reduce system size,
decrease dissipated power, meet the power demands of
high-performance digital circuits, and reduce the cost of
power compared to regulated-voltage IBA systems.
Related Web site
power.ti.com
13
Analog Applications Journal
3Q 2007
www.ti.com/aaj
High-Performance Analog Products
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