Pulse or digital communications – Cable systems and components
Reexamination Certificate
1999-08-27
2003-06-17
Chin, Stephen (Department: 2634)
Pulse or digital communications
Cable systems and components
C375S219000, C330S252000
Reexamination Certificate
active
06580760
ABSTRACT:
FIELD OF THE INVENTION
The present invention generally relates to broadband networks. More specifically, the invention is related to an inverting line driver architecture having reduced distortion and improved power efficiency.
BACKGROUND OF THE INVENTION
With the advancement of technology and the need for instantaneous information, the ability to transfer digital information from one location to another, such as from a central office (CO) to a customer premises (CP), has become more and more important. Allowing for increasing data transmission rates has become a requirement, as opposed to an option.
As part of the system responsible for proper transmission and reception of data in a broadband network, an analog front end (AFE) interfaces between an analog transmission medium, such as an analog telephone line, and digital signal processing circuits. The AFE, among other functions, converts a digital signal into a continuous time analog signal. Particular to the case of a digital subscribe line (DSL) AFE with an integrated line driver, the AFE also puts this converted signal on a two-wire pair. The AFE circuit performs this function by using the combination of a digital-to-analog converter and an analog-to-digital converter. The digital-to-analog converter receives digital signals from a digital signal processor (DSP), and converts them to analog signals, upon which the analog signals are transmitted to a line driver. The analog-to-digital converter receives analog signals, converts them to digital signals, and furnishes them to the DSP. The AFE may also incorporate other elaborate analog signal processing.
Once the analog signal is transmitted to the line driver, the line driver drives the analog signal through the two-wire pair in accordance with a required power particular to the application considered and the type of line driven. Most established DSL applications have a required standard power spectral density template that they are required to meet. As an example, for the most common DSL service currently deployed (2B1Q HDSL), the required transmit power is approximately 13.5 dBm. This yields a maximum peak power of 18.6 dBm, for a peak current of 48.2 mA (assuming 6 Vpp differential output voltage, 3 dB loss in back matching resistors, and a peak-to-average ratio (PAR) of 1.8 for 2B1Q).
At the other extreme, the required transmit power for a Discrete Multi Tone-Asymmetric Digital Subscriber Line-Central Office (DMT-ADSL-CO), assuming 3 dB loss in the back matching resistors and a PAR of 5.3 for DMT, is approximately 20.5 dBm. This yields a maximum peak power of 37.98 dBm, for a peak current of 2095 mA (assuming a 6 Vpp differential output voltage). It should be noted that there is a multitude of other applications at various power levels between these two extremes. Also, due to line impairment caused by a variety of different factors, particularly bridge taps, the actual line impedance might be significantly less then expected, and the load current can thus be significantly higher then expected.
For DSL systems, the line driver is typically the most significant source of distortion in the data transmit path, due to the high speed and large load current requirement, combined with the variety of line configurations encountered. For most high-speed ADSL applications the trend is currently to avoid transmitting and receiving in the same frequency bands. From the customer premise side, typically there is transmission at the low frequency end of the band and reception at the upper frequency end of the band. Thus, distortion products, which fall at multiples of the transmit-signal, fall in the receive spectrum. Typically, distortion in the transmit-path couples into the receive path through a hybrid, which makes the receiver implementation significantly more challenging. The receiver needs to recover the portion of the transmit-signal, which falls in the receive-band, as well as the receive-signal by itself. Therefore, limitation of distortion in the transmit-path is important to both the transmission and reception of information.
It should also be noted, that distortion introduced in the receive-band by any element in the transmit path, up to the line driver, can be filtered out with a passive external LC filter before it is fed to the line driver. However, if the line driver introduces the distortion, it is not practical to filter the distortion out due to the low impedance level. Thus, the distortion introduced by the line driver is the final limiting factor for the distortion of the transmit-path, which typically is the most critical factor in terms of achievable reach of the system.
Typical line driver implementation is based on high input impedance amplifiers. This makes it easy to interface to the line driver. However, it implies that there is significant signal swing across the input terminals of the line driver. This changes the common mode input to the line driver, which inherently changes the gain, in turn, yielding distortion and hampering transmitted and received data.
Since the conventional line driver architecture is non-inverting, it is impossible to introduce voltage attenuation in this stage of signal transmission. Thus, if voltage attenuation is desired, it must be performed at a previous stage in the signal chain. This will, however, reduce the signal to noise ratio of the overall signal path, since the noise will not be reduced when the signal is reduced. Most of the noise is introduced before the line driver, and the less voltage gain needed at this stage, the better the overall signal to noise ratio achieved. Further, for some ADSL applications, standards allow for power cutback for short loop operation. For DMT ADSL, the appropriate standards are ITU G.992.1 for G-Lite, and ITU G.992.2 and ANSI T1.413 for G-Heavy. Thus, the system would need to be able to attenuate the signal significantly below the standard magnitude. If this can be done at the final stage of the line driver, it can be achieved with no additional digital signal processing, and no cost in terms of signal to noise ratio. Further, if the attenuation had to be performed in the digital domain, by reducing the analog input signal going into the AFE, the signal to noise (SNR) ratio would drop proportional to the reduction of the signal level.
It should also be noted, that an amplifier, such as the high input amplifiers of the line driver, will have a higher closed loop bandwidth if it has a low gain. Thus, for optimum overall performance, maximum closed loop bandwidth, and as little closed loop gain as possible, is desired.
Also, current line drivers are typically barely capable of delivering the required power into an ideal load. As an example, if the line driver were designed for DMT ADSL customer premises applications operating at 7 Vpp output swing, the required peak current would be 300 mA in order to generate the required 13.5 dBm into a 100-Ohm line. In order to achieve a power efficient design, the design would be done assuming a maximum output current of about 350 mA. However, in the case of bridge taps, when the effective load is cut in half and the maximum required current therefore could be about 600 mA, significant distortion results. In order to address this problem, an increase in the drive capability of the line driver could be implemented. This would, however, reduce the speed of the device, given the same quiescent power, and increase the distortion during normal load conditions. Thus, the same amplifier cannot be optimized readily to handle both scenarios.
Therefore, the system designer typically has to weigh trade-offs between maximum line power, distortion, and quiescent current in order to find the line driver most suitable for a given application. If power consumption were most significant, the designer may pick a line driver that is barely capable of delivering the required power, but can do this efficiently with little distortion. However, if the device is connected to a line with a bridge tap, such that it is asked to deliver twice the nominal line current, significan
Chin Stephen
GlobespanVirata Inc.
Lugo David B.
Thomas Kayden Horstemeyer & Risley
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