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FROM EDN EUROPE: Low-power differential interface technologies for portable products
Although a number of recent publications have outlined the benefits of using differential signalling technology over single-ended technology for serial interfaces, less information exists on the hidden forces driving such migrations at the signal-transmission level.
By Pravas Pradhan and Jeff Ju, Fairchild Semiconductor -- EDN Europe, 14 Apr 2005
Designs in the consumer and communications sectors are witnessing a
transition from parallel to high-speed serial I/O solutions. Interface
technologies that can balance the conflicting requirements for very high data
rates, at lower power consumption, and with improved EMI performance are
experiencing rapid growth. This article analyses the architectures of the most
commonly used differential signalling technologies to illustrate the trade-off
between power consumption, throughput and electromagnetic interference (EMI)
emission. It also introduces a new I/O approach, current transfer logic
(CTL).
Key specifications
As the resolution of high-end cell phone LCD displays exceeds SVGA
(800×600), the RGB data throughput between the application processor and
the LCD module can become very high. For XGA mode with a 60 Hz refresh rate, it
can exceed 750 Mbps. The high magnitude swing (0 to Vcc) of existing TTL
technology between the baseband controller and the LCD module restricts the
signal data throughput between logic transitions, especially with the
regulatory EMI requirements limiting the edge rate. If it is not possible to
meet these conflicting demands, the project team may be forced into a redesign
of the baseband chipset itself.
In addition, since next-generation camera phones offer a pixel
resolution of more than three million, the RGB data throughput read back to the
baseband processor for snapshots pushes the limits of existing TTL technology.
The same challenge applies to consumer designs such as high-speed DVD-RW design
(at over 16× speeds), where a high volume of data is transferred between
the Read/Write controller and the laser diode driver (LDD).
For most battery-powered devices, power consumption remains a factor
that must always be considered. Any interface technology adopted in baseband
design needs to have ultra-low power consumption, in addition to meeting the
throughput requirements. The dynamic power consumption of any such device is a
function of load capacitance, signal swing, power supply and data rate.
Reducing the signal swing allows existing technologies, such as LVDS, TMDS and
CML, to reach very high throughput, although the power consumption for these
interfaces may still be out of tolerance for portable design requirements. The
capacitance load on driven signal lines is also a major factor that limits the
data throughput for these technologies.
Noise margin
In most portable and consumer electronic designs, connections are
typically over low-bandwidth flex cable or even ultra-low-bandwidth ribbon
cable. The low-bandwidth media can eventually degrade the signal edge, cause
signal attenuation, and generate reflections in long cables. For example, in
DVD-RW and DVD changer applications, the distance between the DVD-RW processor
and Laser Diode Driver (LDD) can be more than 400 mm. To minimise the bit error
rate while maintaining the capability to drive a usable cable length, it is
critical to have sufficient noise margin, defined as the difference between the
driver output voltage and the corresponding receiver input threshold voltage.
Longer cable driving capability becomes a very desirable attribute when using
low-bandwidth media such as flexible cables. This allows the designer more
flexibility in the routing of the signal data path.
Traditional TTL technology has typically used large signal amplitudes
with faster edge rates, resulting in reflections and EMI problems. Slowing down
the edge rate of the TTL signal reduces the reflections and EMI, but limits the
throughput—particularly on low-bandwidth cable. Furthermore, for applications
such as cell phone designs, the RF noise and other EMI noise surrounding the
flex cable between the baseband processor and LCD module or camera image
processor is significant.
Accordingly, differential technologies such as Transition Minimised
Differential Signalling (TMDS) and Low Voltage Differential Signalling (LVDS)
come into play with improved throughput, noise immunity or EMI performance. But
these technologies still consume a considerable amount of power, which is not
desirable in battery-operated devices.
Differential solutions
Currently, two interface technologies dominate in portable and consumer
designs. The TMDS signalling scheme is mainly adopted by the HDMI and DVI
standard as the link for both HDTV digital video/audio and the PC monitor RGB
data link with speeds as high as 1.65 Gbps. LVDS is also widely used in
flat-panel display designs to transmit RGB data between the LCD controller and
LCD Modules (LCM). These two technologies are very similar except for the
difference between the sink or source current scheme.
The TMDS-based driver typically has an open-drain or open-collector
output with far-end termination to Vcc (3.3V) for transmission line impedance
match. The output buffer usually is an amplifier-type architecture with a
constant tail current of typically 10 mA. The typical swing of the single-ended
signal is about 500 mV, and the differential swing is 1000 mVp-p. The common-mode signal of the driver output is
Vcc - 0.25V.
The TMDS driver (href="contents/images/515309f1.pdf">Figure 1) sinks the
current at its plus or minus line from the far-end termination voltage,
depending on the logic input. This creates a voltage drop over the termination
resistor, which is sensed as logic "1" or "0" by the receiver. Depending on
which line is sinking the current, the other line will be pulled high to Vcc by
a 50-Ω termination resistor. Thus, the latter not only acts as a
matching resistor (RT=Z0) for signal integrity purposes, but also performs
the job of creating a voltage drop for logic "0". Z0 is the characteristic impedance of the cable or
traces. The resistor value is critical for both signal integrity and noise
margin in terms of signal magnitude. Typical standards require a 10%-tolerance
in the resistor value. In order to perform high throughput transfer and
maintain a satisfactory noise margin for the receiver, the TMDS link could have
a rise/fall time as fast as 75 psec. This fast edge rate can cause very fast
current switching, with worsening EMI as throughput rises. For these reasons,
designers mainly use TMDS for high-speed data transfer in applications such as
digital YCbCr video signals. However, they attain this high throughput at the
cost of high power consumption in the output driver. Increasing the EMI is
another big sacrifice that makes it possible to achieve such high throughput
(1.65 Gbps). 8b/10b encoding is needed to obtain minimised transition and
DC-balanced character.
One could call this type of scheme a "pseudo-current
interface", since it is necessary to convert the output current of the driver to
voltage at the receiver side so it can be received correctly. Of course, once
voltage comes into play, parasitic capacitance will effectively hamper the
throughput for such I/Os as TMDS and LVDS, governed by the relationship i=C.dV/dt.
For constant-current output from drivers, the higher the parasitic
capacitance in the data path, the lower the edge rate. This results in limited
throughput. Consequently, the capacitance effect along the data path not only
contributes to higher power consumption but also heavily limits the data
throughput. Parasitic capacitance here includes ESD capacitance, gate input
capacitance, cable capacitance and stub/connector capacitance.
Unlike TMDS, LVDS requires the flow of a balanced current (3.5 mA) in
the loop between the plus and the minus line as shown in Figure
2. The direction of the current is dependent on
the input logic of the drivers. This 3.5 mA current creates a voltage drop over
the termination resistor (100 Ω) at the receiver side, which is sensed
by the internal receiver amplifier and interpreted as logic "1" or "0",
depending on the direction of the current flow.
Meanwhile, the opposite flow of the currents in the loop generates
magnetic fields which cancel out each other if the media, such as traces, are
laid out close enough. Since the LVDS signal's edge rates (typically 1 V/nsec)
are much slower than TMDS, this reduces the di/dt, leading to smaller electromagnetic emissions.
Of course, traditional LVDS technology offers lower throughput than TMDS due to
reduced edge rate, which nonetheless is rewarded with less EMI. Efforts are in
place to further reduce the LVDS swing to achieve lesser EMI and power
consumption for portable and consumer electronics. However, this comes at the
cost of lower throughput, reduced noise margin, and less cable driving
capability.
As the video display market migrates to high definition with more
resolution than UXGA, data throughput between display controllers and LCD
modules in both portable and consumer electronics, such as cell phones and LCD
TVs, is approaching the bottleneck that exists in the current single-ended TTL
technology. Despite efforts to extend their capabilities, today's differential
solutions will have a difficult time meeting all the key specifications of such
a design.
Although it is very difficult to define a perfect interface technology
to meet all of the key specifications simultaneously, by better understanding
the signalling schemes we can reduce the interdependence between the important
specification parameters. This offers a route to lower power and lower EMI
signalling technology for portable and consumer designs. A general block
diagram, such as that shown in href="contents/images/515309f3.pdf">Figure 3, can
represent the most critical areas that are limited by the performance of
today's technologies.
All of these technologies use similar current mode drivers on the driver
side. A current source is used to source the current out of the driver. This
current flows through the cable and then through the terminating resistance,
thus creating a voltage drop which is sensed by a voltage amplifier. To create
logic "1" or "0", the direction of the current flowing through the terminating
resistor is changed using some properly-sized switches at the driver. Thus,
terminating resistance not only helps in terminating the cable which acts as a
transmission line, but it also creates the differential voltage that the
receiver must sense. Usually, the receiver is a trans-conductance amplifier
followed by an I-V conversion stage. The sensitivity of the receiver depends on
the size of the input devices and the signal swing at the receiver, which, in
turn, depends on the current sourced by the driver. The noise margin on the
receiver side constrains the minimal allowable signal swing. For longer cables,
the signal attenuates as it moves along the length of the cable due to the
resistive drop from the cable itself. This effect is particularly severe at
high frequencies, as resistance increases due to the skin effect which
consequently attenuates the signal at the receiver and degrades the noise
margin. For a lesser signal swing, the noise margin will depend on the rate of
change of the input signal and the minimum input swing required to switch the
receiver or the sensitivity of the receiver.
One way to increase the sensitivity of a typical CMOS voltage receiver
is to increase the size of the input devices. However, this will increase the
input capacitance and degrade the slew-rate, which will ultimately set the
limits on power and speed requirements to transmit the signal reliably.
Signal swing determines the noise margin and the power while the edge
rate determines the speed. Signal swing at the receiver is in turn determined
by i×R, where i is the
current sourced by the driver and R is the
terminating resistance. EMI is dependent on both the edge rate and the signal
swing. A slow edge rate with less signal swing will give less EMI. Edge rate
(slew rate), dv/dt, at the receiver is
primarily determined by i/C. Capacitance C
is the sum of capacitance of the cable, input device, bond pad, pin, and other
parasitics and strays. Reducing i will
require a bigger input device to achieve the same noise margin which will
increase the input capacitance, and thus reduce and dv/dt limit the speed. To solve these problems, it is
imperative to address fundamental constraints in the signalling technology.
Most of these constraints originated from the requirements on the receiver
side.
Current transfer logic
What would happen if the current output from the driver were not
converted to voltage and the receiver were capable of taking the current
directly? This would eliminate the trans-impedance amplifier in the receiver,
which would not only reduce the propagation delay, but would also greatly
diminish the effect of parasitic capacitance on the channel bandwidth. This
model will require a fundamental shift in the signalling technology by
replacing the voltage mode receive circuit with a current mode receive
circuit.
A current-sensing circuit can be designed to work with low input
currents without compromising the noise margin. If some mechanism can reliably
sense the current sourced by the driver and make the sensing process less
dependent on the capacitance, it should be able to guarantee high speed at much
less swing, which leads to less power consumption. This mechanism signifies a
"true-current transfer" scheme differentiating from traditional "pseudo-current
schemes" such as TMDS and LVDS technologies.
This current-transfer scheme forms the basis of Current Transfer Logic
(CTL). The key point is to replace the high-input impedance of the voltage
amplifier with a low-input impedance current-sensing circuit followed by an I-V
conversion stage to drive the digital logic. An immediate advantage of using a
differential current-sensing circuit will be very low voltage swing, leading to
reduced current spikes and low EMI. Work in memories has demonstrated that
current-mode signals are much less affected by the load capacitance and can
provide significant performance improvement over the voltage mode signals
(Reference 1).
href="contents/images/515309f4.pdf">Figure 4 shows a typical interface
system employing CTL. Conceptually, the current signal transferred between the
driver and the receiver is sensed with a current-sensing circuit. Depending on
the requirements, the current-sensing circuit can also be designed to terminate
the transmission media. Since the receiver is designed to sense the current, we
can afford to transmit very low current, which is typically not possible using
a voltage mode receiver. LVDS technology derives its power and EMI advantage by
matching the currents in the forward and return paths. In CTL, the current in
the forward direction is I, while the
current which loops back to the driver is 0.5×I. The
current change in both the lines to achieve logic "1" or logic "0" is
0.5×I in opposite directions, thus cancelling the magnetic
field generated. Due to the low input impedance of the receiver, the remaining
50% of current I is absorbed in the
receiver. Depending on the direction of the current flow, one pin (plus or
minus) of the receiver will absorb more current than the other. This will
create a differential current between the positive and negative pins. Current
gain is not needed at the input stage, and unity gain can be employed to
transfer the differential current from heavily-loaded input nodes to a
lightly-loaded node internal to the chip. Subsequently, differential current is
multiplied, if required, before the current-to-voltage transformation using a
simple trans-conductance stage. Low-to-high impedance transformation takes
place inside the chip, where the capacitive load is not big enough to affect
the voltage signal.
Low input impedance is ideal for current processing and much less
dependent on capacitive loading, while the digital circuit that follows the
analogue input amplifier needs to be driven by a voltage at its high input
impedance. Using the CTL technique avoids current-to-voltage conversion at the
high capacitive input node and allows current-to-voltage conversion to take
place at a point where capacitance is insignificant. This helps to achieve high
throughput and enables transferring the signal at very low power, specifically
when compared to LVDS and TMDS technologies. Similar to LVDS, for cables with
low dispersive loss, it is either possible for the receiver to set the total
common-mode value, or for the driver to force it. The return current helps in
biasing the receiver around its common-mode value. It is possible to design the
0.5×I return current and the current the receiver absorbs
to track the current that the driver sources, thus providing a good common-mode
range to accommodate the potential ground mismatch between drivers and
receivers. Due to the fact that receiver can take the current input directly,
the input threshold voltage of receiver is not as critical as it is in TMDS and
LVDS interfaces. With a smaller swing, the slew rate can have an even bigger
range for the same throughput. With a slower edge rate and less power
consumption, one can transfer the same bandwidth of data with much less EMI and
channel latency if the receiver has current-sensing capability.
Experimental trials
To prove the concept with basic circuit techniques, researchers designed
a pair of LVCMOS-to-CTL and CTL-to-LVCMOS translators. For this experiment,
they developed a CTL driver to source 1 mA of current and sink 0.6 mA of
current. The transmission line was terminated with a 100-Ω resistance
across the receiver input. They designed the receiver to take in the remaining
0.4 mA of current and generate a swing of 65 mV across its input, and they
placed much emphasis on comparing CTL with the reduced-swing LVDS technology
(250 instead of 350 mV).
To make the comparison as accurate as possible, they designed the
prototype CTL translator chipset to fit exactly in the same footprint as an
existing reduced-swing LVDS translator chipset. They changed only the analogue
front-end of the driver and receiver while keeping the remainder of the digital
and analogue circuits identical. Thus, with identical boards and the socket and
test set up in place, the difference in key specifications comes only from the
difference in the interface signalling technique.
Power and throughput
CTL derives its power and speed advantage from the low loop current of
the current-sensing receiver. With less than one-fourth the swing of the
corresponding LVDS approach, the DC power dissipation in the driver stage
reduces dramatically. Due to the smaller drive current and a
common-mode-generating receiver, CTL doesn't require a powerful pre-driver and
a common-mode feedback circuit, which leads to dynamic power saving. Since
current-to-voltage conversion is done at a reduced-capacitance node, power
requirements on the receiver side are not restrictive. Reduced swing also leads
to higher speeds. Furthermore, it is possible to design the current-sensing
receiver to be sensitive enough to respond to differential current of only a
few microamperes—resulting in very high speeds, while reducing power
consumption. In a translator design, the LVCMOS side of the signal path is the
main element that limits speed.
Since CTL is fundamentally different from LVDS at the receiver input, it
makes more sense to compare bit error rate instead of comparing the voltage
signal at the differential I/O. However, for completeness,
Figure
5 shows an eye-diagram of a CTL signal
at 250 and 100 MHz at the differential I/O, as well as at the CMOS output. The
data was collected with a PRBS data pattern running through 6 inches of flex
cable (typical of cell phone applications) with a CTL driver and receiver
paired.
With throughput of 200 Mbps (100 MHz), the additive jitter of the CTL
driver and receiver is only 23 psec peak to peak. The common-mode variation of
the driver output is only 29.21 mV. This also leads to the conclusion that for
the same speed and eye-opening, CTL takes only 50% of the power compared to
reduced-swing LVDS, 70% of power versus traditional LVDS and at least 90% less
power compared with TMDS technology. The impact of this reduction in power
becomes significant in high-throughput applications like SerDes
(serialiser/deserialiser) deployed between the LCD display and the base-band
processor. In a specific SerDes architecture, using CTL as the serial I/O can
provide up to 30% power savings over reduced-swing LVDS I/O.
CTL offers excellent eye-opening capability to achieve high throughput
at low power due to its current-sensing inputs. A voltage receiver, as in LVDS,
will require complex equalisation techniques to detect the data reliably from a
closed eye. Further equalisation needs to be adaptive for different cable
lengths. With CTL, easily-implemented circuit techniques at the input sensing
nodes provide the same eye opening. Data collected using PRBS input at
different data rates yield the waveforms shown in Figure
6.
Noise margin and drive
As explained earlier, noise margin carries a direct trade-off with drive
capability. CTL is inherently capable of driving very long cables with little
attenuation due to the current-sensing circuit present at the far end. As long
as there is no significant dispersion loss in the cable, the current reaching
the receiver at the far end will remain constant, according to Kirchoff's
Current Law. Since current received at the end of the link is not attenuated
during transmission as is voltage in the case of LVDS, designers can use CTL
over longer cable length—it still provides reliable signal detection.
Figure
7 shows eye diagrams over various
distances and cable types with 500 Mbps PRBS data.
EMI and susceptibility
As CTL is differential in nature and employs low signal swing-edge rate,
it should—according to the reasoning outlined above—provide good EMI
performance. The emissions from CTL were compared with LVDS, reduced-swing LVDS
(LpLVDS) and TTL, on a 250-MHz input signal over a 10cm-long flex cable,
typical for a cell phone application. Observed from the magnetic emission
collected by a near-field probe, CTL technology on average delivers EMI that is
over 10 dB lower than LVDS technology and 20 dB less than TTL signalling
scheme. This is achieved with a power consumption of only 1 mA (typical) for
each channel, which is much less than the 3.5 mA per channel for LVDS
technology and 10 mA for TMDS interfaces.
Author Information
Pravas Pradhan and Jeff Ju are Staff Application/Design Engineers at
Fairchild Semiconductor.
REFERENCES
- "Current Mode Techniques for High Speed VLSI
Circuits with Applications to Current Sense Amplifier for CMOS SRAMS,"
Seevinck et al, IEEE Journal of Solid State Circuits, vol. 26, Nr 4,
April 1991, p. 525-535.
- "A 1-Gb/s Bidirectional I/O Buffer Using the Current-Mode Scheme,"
Sim et al, IEEE Journal of Solid State Circuits, vol. 34, Nr 4, April 1999, p.
529-535.
href="contents/images/515309.pdf">![]()
src="http://www.edn.com/articles/images/EDNE/20050414/pdfbutton.gif">
transition from parallel to high-speed serial I/O solutions. Interface
technologies that can balance the conflicting requirements for very high data
rates, at lower power consumption, and with improved EMI performance are
experiencing rapid growth. This article analyses the architectures of the most
commonly used differential signalling technologies to illustrate the trade-off
between power consumption, throughput and electromagnetic interference (EMI)
emission. It also introduces a new I/O approach, current transfer logic
(CTL).
(800×600), the RGB data throughput between the application processor and
the LCD module can become very high. For XGA mode with a 60 Hz refresh rate, it
can exceed 750 Mbps. The high magnitude swing (0 to Vcc) of existing TTL
technology between the baseband controller and the LCD module restricts the
signal data throughput between logic transitions, especially with the
regulatory EMI requirements limiting the edge rate. If it is not possible to
meet these conflicting demands, the project team may be forced into a redesign
of the baseband chipset itself.
resolution of more than three million, the RGB data throughput read back to the
baseband processor for snapshots pushes the limits of existing TTL technology.
The same challenge applies to consumer designs such as high-speed DVD-RW design
(at over 16× speeds), where a high volume of data is transferred between
the Read/Write controller and the laser diode driver (LDD).
that must always be considered. Any interface technology adopted in baseband
design needs to have ultra-low power consumption, in addition to meeting the
throughput requirements. The dynamic power consumption of any such device is a
function of load capacitance, signal swing, power supply and data rate.
Reducing the signal swing allows existing technologies, such as LVDS, TMDS and
CML, to reach very high throughput, although the power consumption for these
interfaces may still be out of tolerance for portable design requirements. The
capacitance load on driven signal lines is also a major factor that limits the
data throughput for these technologies.
typically over low-bandwidth flex cable or even ultra-low-bandwidth ribbon
cable. The low-bandwidth media can eventually degrade the signal edge, cause
signal attenuation, and generate reflections in long cables. For example, in
DVD-RW and DVD changer applications, the distance between the DVD-RW processor
and Laser Diode Driver (LDD) can be more than 400 mm. To minimise the bit error
rate while maintaining the capability to drive a usable cable length, it is
critical to have sufficient noise margin, defined as the difference between the
driver output voltage and the corresponding receiver input threshold voltage.
Longer cable driving capability becomes a very desirable attribute when using
low-bandwidth media such as flexible cables. This allows the designer more
flexibility in the routing of the signal data path.
with faster edge rates, resulting in reflections and EMI problems. Slowing down
the edge rate of the TTL signal reduces the reflections and EMI, but limits the
throughput—particularly on low-bandwidth cable. Furthermore, for applications
such as cell phone designs, the RF noise and other EMI noise surrounding the
flex cable between the baseband processor and LCD module or camera image
processor is significant.
Differential Signalling (TMDS) and Low Voltage Differential Signalling (LVDS)
come into play with improved throughput, noise immunity or EMI performance. But
these technologies still consume a considerable amount of power, which is not
desirable in battery-operated devices.
designs. The TMDS signalling scheme is mainly adopted by the HDMI and DVI
standard as the link for both HDTV digital video/audio and the PC monitor RGB
data link with speeds as high as 1.65 Gbps. LVDS is also widely used in
flat-panel display designs to transmit RGB data between the LCD controller and
LCD Modules (LCM). These two technologies are very similar except for the
difference between the sink or source current scheme.
output with far-end termination to Vcc (3.3V) for transmission line impedance
match. The output buffer usually is an amplifier-type architecture with a
constant tail current of typically 10 mA. The typical swing of the single-ended
signal is about 500 mV, and the differential swing is 1000 mVp-p. The common-mode signal of the driver output is
Vcc - 0.25V.
current at its plus or minus line from the far-end termination voltage,
depending on the logic input. This creates a voltage drop over the termination
resistor, which is sensed as logic "1" or "0" by the receiver. Depending on
which line is sinking the current, the other line will be pulled high to Vcc by
a 50-Ω termination resistor. Thus, the latter not only acts as a
matching resistor (RT=Z0) for signal integrity purposes, but also performs
the job of creating a voltage drop for logic "0". Z0 is the characteristic impedance of the cable or
traces. The resistor value is critical for both signal integrity and noise
margin in terms of signal magnitude. Typical standards require a 10%-tolerance
in the resistor value. In order to perform high throughput transfer and
maintain a satisfactory noise margin for the receiver, the TMDS link could have
a rise/fall time as fast as 75 psec. This fast edge rate can cause very fast
current switching, with worsening EMI as throughput rises. For these reasons,
designers mainly use TMDS for high-speed data transfer in applications such as
digital YCbCr video signals. However, they attain this high throughput at the
cost of high power consumption in the output driver. Increasing the EMI is
another big sacrifice that makes it possible to achieve such high throughput
(1.65 Gbps). 8b/10b encoding is needed to obtain minimised transition and
DC-balanced character.
interface", since it is necessary to convert the output current of the driver to
voltage at the receiver side so it can be received correctly. Of course, once
voltage comes into play, parasitic capacitance will effectively hamper the
throughput for such I/Os as TMDS and LVDS, governed by the relationship i=C.dV/dt.
capacitance in the data path, the lower the edge rate. This results in limited
throughput. Consequently, the capacitance effect along the data path not only
contributes to higher power consumption but also heavily limits the data
throughput. Parasitic capacitance here includes ESD capacitance, gate input
capacitance, cable capacitance and stub/connector capacitance.
the loop between the plus and the minus line as shown in Figure
2. The direction of the current is dependent on
the input logic of the drivers. This 3.5 mA current creates a voltage drop over
the termination resistor (100 Ω) at the receiver side, which is sensed
by the internal receiver amplifier and interpreted as logic "1" or "0",
depending on the direction of the current flow.
magnetic fields which cancel out each other if the media, such as traces, are
laid out close enough. Since the LVDS signal's edge rates (typically 1 V/nsec)
are much slower than TMDS, this reduces the di/dt, leading to smaller electromagnetic emissions.
Of course, traditional LVDS technology offers lower throughput than TMDS due to
reduced edge rate, which nonetheless is rewarded with less EMI. Efforts are in
place to further reduce the LVDS swing to achieve lesser EMI and power
consumption for portable and consumer electronics. However, this comes at the
cost of lower throughput, reduced noise margin, and less cable driving
capability.
resolution than UXGA, data throughput between display controllers and LCD
modules in both portable and consumer electronics, such as cell phones and LCD
TVs, is approaching the bottleneck that exists in the current single-ended TTL
technology. Despite efforts to extend their capabilities, today's differential
solutions will have a difficult time meeting all the key specifications of such
a design.
to meet all of the key specifications simultaneously, by better understanding
the signalling schemes we can reduce the interdependence between the important
specification parameters. This offers a route to lower power and lower EMI
signalling technology for portable and consumer designs. A general block
diagram, such as that shown in href="contents/images/515309f3.pdf">Figure 3, can
represent the most critical areas that are limited by the performance of
today's technologies.
side. A current source is used to source the current out of the driver. This
current flows through the cable and then through the terminating resistance,
thus creating a voltage drop which is sensed by a voltage amplifier. To create
logic "1" or "0", the direction of the current flowing through the terminating
resistor is changed using some properly-sized switches at the driver. Thus,
terminating resistance not only helps in terminating the cable which acts as a
transmission line, but it also creates the differential voltage that the
receiver must sense. Usually, the receiver is a trans-conductance amplifier
followed by an I-V conversion stage. The sensitivity of the receiver depends on
the size of the input devices and the signal swing at the receiver, which, in
turn, depends on the current sourced by the driver. The noise margin on the
receiver side constrains the minimal allowable signal swing. For longer cables,
the signal attenuates as it moves along the length of the cable due to the
resistive drop from the cable itself. This effect is particularly severe at
high frequencies, as resistance increases due to the skin effect which
consequently attenuates the signal at the receiver and degrades the noise
margin. For a lesser signal swing, the noise margin will depend on the rate of
change of the input signal and the minimum input swing required to switch the
receiver or the sensitivity of the receiver.
is to increase the size of the input devices. However, this will increase the
input capacitance and degrade the slew-rate, which will ultimately set the
limits on power and speed requirements to transmit the signal reliably.
rate determines the speed. Signal swing at the receiver is in turn determined
by i×R, where i is the
current sourced by the driver and R is the
terminating resistance. EMI is dependent on both the edge rate and the signal
swing. A slow edge rate with less signal swing will give less EMI. Edge rate
(slew rate), dv/dt, at the receiver is
primarily determined by i/C. Capacitance C
is the sum of capacitance of the cable, input device, bond pad, pin, and other
parasitics and strays. Reducing i will
require a bigger input device to achieve the same noise margin which will
increase the input capacitance, and thus reduce and dv/dt limit the speed. To solve these problems, it is
imperative to address fundamental constraints in the signalling technology.
Most of these constraints originated from the requirements on the receiver
side.
converted to voltage and the receiver were capable of taking the current
directly? This would eliminate the trans-impedance amplifier in the receiver,
which would not only reduce the propagation delay, but would also greatly
diminish the effect of parasitic capacitance on the channel bandwidth. This
model will require a fundamental shift in the signalling technology by
replacing the voltage mode receive circuit with a current mode receive
circuit.
currents without compromising the noise margin. If some mechanism can reliably
sense the current sourced by the driver and make the sensing process less
dependent on the capacitance, it should be able to guarantee high speed at much
less swing, which leads to less power consumption. This mechanism signifies a
"true-current transfer" scheme differentiating from traditional "pseudo-current
schemes" such as TMDS and LVDS technologies.
(CTL). The key point is to replace the high-input impedance of the voltage
amplifier with a low-input impedance current-sensing circuit followed by an I-V
conversion stage to drive the digital logic. An immediate advantage of using a
differential current-sensing circuit will be very low voltage swing, leading to
reduced current spikes and low EMI. Work in memories has demonstrated that
current-mode signals are much less affected by the load capacitance and can
provide significant performance improvement over the voltage mode signals
(Reference 1).
href="contents/images/515309f4.pdf">Figure 4 shows a typical interface
system employing CTL. Conceptually, the current signal transferred between the
driver and the receiver is sensed with a current-sensing circuit. Depending on
the requirements, the current-sensing circuit can also be designed to terminate
the transmission media. Since the receiver is designed to sense the current, we
can afford to transmit very low current, which is typically not possible using
a voltage mode receiver. LVDS technology derives its power and EMI advantage by
matching the currents in the forward and return paths. In CTL, the current in
the forward direction is I, while the
current which loops back to the driver is 0.5×I. The
current change in both the lines to achieve logic "1" or logic "0" is
0.5×I in opposite directions, thus cancelling the magnetic
field generated. Due to the low input impedance of the receiver, the remaining
50% of current I is absorbed in the
receiver. Depending on the direction of the current flow, one pin (plus or
minus) of the receiver will absorb more current than the other. This will
create a differential current between the positive and negative pins. Current
gain is not needed at the input stage, and unity gain can be employed to
transfer the differential current from heavily-loaded input nodes to a
lightly-loaded node internal to the chip. Subsequently, differential current is
multiplied, if required, before the current-to-voltage transformation using a
simple trans-conductance stage. Low-to-high impedance transformation takes
place inside the chip, where the capacitive load is not big enough to affect
the voltage signal.
dependent on capacitive loading, while the digital circuit that follows the
analogue input amplifier needs to be driven by a voltage at its high input
impedance. Using the CTL technique avoids current-to-voltage conversion at the
high capacitive input node and allows current-to-voltage conversion to take
place at a point where capacitance is insignificant. This helps to achieve high
throughput and enables transferring the signal at very low power, specifically
when compared to LVDS and TMDS technologies. Similar to LVDS, for cables with
low dispersive loss, it is either possible for the receiver to set the total
common-mode value, or for the driver to force it. The return current helps in
biasing the receiver around its common-mode value. It is possible to design the
0.5×I return current and the current the receiver absorbs
to track the current that the driver sources, thus providing a good common-mode
range to accommodate the potential ground mismatch between drivers and
receivers. Due to the fact that receiver can take the current input directly,
the input threshold voltage of receiver is not as critical as it is in TMDS and
LVDS interfaces. With a smaller swing, the slew rate can have an even bigger
range for the same throughput. With a slower edge rate and less power
consumption, one can transfer the same bandwidth of data with much less EMI and
channel latency if the receiver has current-sensing capability.
a pair of LVCMOS-to-CTL and CTL-to-LVCMOS translators. For this experiment,
they developed a CTL driver to source 1 mA of current and sink 0.6 mA of
current. The transmission line was terminated with a 100-Ω resistance
across the receiver input. They designed the receiver to take in the remaining
0.4 mA of current and generate a swing of 65 mV across its input, and they
placed much emphasis on comparing CTL with the reduced-swing LVDS technology
(250 instead of 350 mV).
prototype CTL translator chipset to fit exactly in the same footprint as an
existing reduced-swing LVDS translator chipset. They changed only the analogue
front-end of the driver and receiver while keeping the remainder of the digital
and analogue circuits identical. Thus, with identical boards and the socket and
test set up in place, the difference in key specifications comes only from the
difference in the interface signalling technique.
the current-sensing receiver. With less than one-fourth the swing of the
corresponding LVDS approach, the DC power dissipation in the driver stage
reduces dramatically. Due to the smaller drive current and a
common-mode-generating receiver, CTL doesn't require a powerful pre-driver and
a common-mode feedback circuit, which leads to dynamic power saving. Since
current-to-voltage conversion is done at a reduced-capacitance node, power
requirements on the receiver side are not restrictive. Reduced swing also leads
to higher speeds. Furthermore, it is possible to design the current-sensing
receiver to be sensitive enough to respond to differential current of only a
few microamperes—resulting in very high speeds, while reducing power
consumption. In a translator design, the LVCMOS side of the signal path is the
main element that limits speed.
makes more sense to compare bit error rate instead of comparing the voltage
signal at the differential I/O. However, for completeness,
Figure
5 shows an eye-diagram of a CTL signal
at 250 and 100 MHz at the differential I/O, as well as at the CMOS output. The
data was collected with a PRBS data pattern running through 6 inches of flex
cable (typical of cell phone applications) with a CTL driver and receiver
paired.
driver and receiver is only 23 psec peak to peak. The common-mode variation of
the driver output is only 29.21 mV. This also leads to the conclusion that for
the same speed and eye-opening, CTL takes only 50% of the power compared to
reduced-swing LVDS, 70% of power versus traditional LVDS and at least 90% less
power compared with TMDS technology. The impact of this reduction in power
becomes significant in high-throughput applications like SerDes
(serialiser/deserialiser) deployed between the LCD display and the base-band
processor. In a specific SerDes architecture, using CTL as the serial I/O can
provide up to 30% power savings over reduced-swing LVDS I/O.
at low power due to its current-sensing inputs. A voltage receiver, as in LVDS,
will require complex equalisation techniques to detect the data reliably from a
closed eye. Further equalisation needs to be adaptive for different cable
lengths. With CTL, easily-implemented circuit techniques at the input sensing
nodes provide the same eye opening. Data collected using PRBS input at
different data rates yield the waveforms shown in Figure
6.
capability. CTL is inherently capable of driving very long cables with little
attenuation due to the current-sensing circuit present at the far end. As long
as there is no significant dispersion loss in the cable, the current reaching
the receiver at the far end will remain constant, according to Kirchoff's
Current Law. Since current received at the end of the link is not attenuated
during transmission as is voltage in the case of LVDS, designers can use CTL
over longer cable length—it still provides reliable signal detection.
Figure
7 shows eye diagrams over various
distances and cable types with 500 Mbps PRBS data.
it should—according to the reasoning outlined above—provide good EMI
performance. The emissions from CTL were compared with LVDS, reduced-swing LVDS
(LpLVDS) and TTL, on a 250-MHz input signal over a 10cm-long flex cable,
typical for a cell phone application. Observed from the magnetic emission
collected by a near-field probe, CTL technology on average delivers EMI that is
over 10 dB lower than LVDS technology and 20 dB less than TTL signalling
scheme. This is achieved with a power consumption of only 1 mA (typical) for
each channel, which is much less than the 3.5 mA per channel for LVDS
technology and 10 mA for TMDS interfaces.
Fairchild Semiconductor.
- "Current Mode Techniques for High Speed VLSI
Circuits with Applications to Current Sense Amplifier for CMOS SRAMS,"
Seevinck et al, IEEE Journal of Solid State Circuits, vol. 26, Nr 4,
April 1991, p. 525-535.
- "A 1-Gb/s Bidirectional I/O Buffer Using the Current-Mode Scheme,"
Sim et al, IEEE Journal of Solid State Circuits, vol. 34, Nr 4, April 1999, p.
529-535.
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