Dynamic voltage scaling for packet-based data communication systems

A dynamic voltage scaling system for a packet-based data communication transceiver includes a constant voltage supply, a variable voltage supply, and a voltage control unit. The constant voltage supply is configured to supply a constant voltage to at least one parameter-independent function of the transceiver, and the variable voltage supply is configured to supply a variable voltage in accordance with a control signal to at least one parameter-dependent function of the transceiver. Parameter-independent transceiver functions perform operations independent of a predetermined parameter and parameter-dependent transceiver functions perform operations dependent on the predetermined parameter The voltage control unit is configured to generate the control signal based on information provided by at least one parameter-independent transceiver function about the predetermined parameter.

FIELD OF THE INVENTION

The present invention generally pertains to transceiver design for packet-based data communication systems. More particularly, the present invention pertains to techniques for reducing transceiver energy consumption in transmitting and/or receiving data packets.

BACKGROUND

Communication systems exist that can support variable data rate by dynamically selecting the best modulation and coding scheme to compensate for channel condition variation and/or upper layer requirement changes. Such systems can implement Adaptive Modulation and Coding (AMC). Exemplary systems include 3G cellular system (3GPP), IEEE 802.11, and WiMedia's multiband orthogonal frequency division multiplexing (MBOFDM) ultra wideband (UWB) system.

Low power consumption is often desirable, and sometimes mandatory, for communication devices. However, communication devices, such as transceivers, are typically designed to support the maximum throughput that the communication system can achieve This requirement for high speed (i.e., high data rate) communication can result in design choices that make optimization of power consumption difficult to achieve. Accordingly, what is needed arc techniques that enable reduction of transceiver power consumption in packet-based data communication systems.

BRIEF SUMMARY

In accordance with an embodiment of the present invention, a dynamic voltage scaling system for a packet-based data communication transceiver includes a constant voltage supply, a variable voltage supply, and a voltage control unit. The constant voltage supply is configured to supply a constant voltage to at least one parameter-independent function of the transceiver, and the variable voltage supply is configured to supply a variable voltage in accordance with a control signal to at least one parameter-dependent function of the transceiver. Parameter-independent transceiver functions perform operations independent of a predetermined parameter and parameter-dependent transceiver functions perform operations dependent on the predetermined parameter. The voltage control unit is configured to generate the control signal based on information about the predetermined parameter provided by at least one parameter-independent, transceiver function.

In accordance with another embodiment of the present invention, a dynamic voltage scaling system for a packet-based data communication transceiver includes means for supplying a constant voltage to at least one parameter-independent function of the transceiver. Parameter-independent transceiver functions perform operations independent of a predetermined parameter. The system further includes means for generating a control signal based on information provided by at least one parameter-independent transceiver function about the predetermined parameter, and means for supplying a variable voltage to at least, one parameter-dependent function of the transceiver in accordance with the control signal. Parameter-dependent transceiver functions perform operations dependent on the predetermined parameter.

In accordance with a further embodiment of the present invention, a method for dynamically scaling voltage for a packet-based data communication transceiver includes supplying a constant voltage to at least one parameter-independent function of the transceiver. Parameter-independent transceiver functions perform operations independent of a predetermined parameter. The method further includes generating a control signal based on information provided by at least one parameter-independent transceiver function about the predetermined parameter, and supplying a variable voltage to at least one parameter-dependent function of the transceiver in accordance with the control signal. Parameter-dependent transceiver functions perform operations dependent on the predetermined parameter.

DETAILED DESCRIPTION

Overview

Transceivers can be powered by one or more power supplies that provide constant voltage(s). Such transceivers can be designed to meet peak performance requirements with respect to data rate, coding gain, etc. Thus, even when peak performance is not required, the transceiver can still consume a significant amount of power because the supply voltage(s) remain constant regardless of the instantaneous performance requirements.

Conventional CMOS digital circuitry requires low noise, constant power supply voltage to achieve high noise margin. Thus, transceivers in packet-based data communication systems can be implemented with CMOS circuits that use constant supply voltage. The power consumption of any CMOS circuit can be defined as the sum of dynamic power consumption and static power consumption (See, Rabaey,Digital Integrated Circuits, Prentice Hall (1996)). The dynamic power consumption for digital circuits can be attributed to the power consumption from switching capacitive loads, whereas the static power consumption can be attributed to current that flows when the circuit is not actively switching due to the finite resistance of the path between the power supply and the ground. For CMOS circuits, the static current is also referred to as “leakage current.” The dynamic power consumption for a CMOS gate can be expressed, as Pdyn=C*Vdd2*fclk, where C is the load capacitance, Vddis the supply voltage and fclk is the clock frequency. The static power consumption can be expressed as Pleak−Ileak*Vdd, where Ileakis the leakage current and Vddis the supply voltage. Thus, the total power consumption for the CMOS gate can be expressed as Ptotal−Pleak+Pdyn, and is strongly dependent on Vdd.

Techniques exist for scaling down the supply voltage (Vdd) statically to reduce circuit power consumption. Because the speed of a circuit decreases with lower supply voltage, static voltage sealing techniques can reduce the peak throughput of the circuit.

Techniques also exist for scaling down the supply voltage (Vdd) dynamically to reduce circuit power consumption. Dynamic voltage scaling (DVS) is one active power management technique for reducing the overall power consumption of a CMOS circuit, where the supply voltage and clock frequency can be adjusted dynamically in response to a circuit throughput requirement. For example, Gonzalez, et al., “Supply and Threshold Voltage Scaling for Low Power CMOS,” IEEE J of Solid-State Circuits, Vol. 32 (August 1997) investigate the effect of lowering the supply voltage and provide a first-order model of energy and delay in CMOS circuits, which shows that, lowering the supply and threshold voltage can be advantageous, especially when the transistors of the CMOS circuit are velocity saturated and the nodes have a high activity factor. Burd et al., “A Dynamic Voltage Scaled Microprocessor System,” IEEE Journal of Solid State Circuits, Vol. 35 (November 2000) use a microprocessor to compute workload and adaptively scale supply voltage for the entire system. Such systems require an operating system that can intelligently vary the processor speed.

Similar to DVS, a dynamic threshold voltage (VTII) scaling (DVTS) scheme is described in Kim et al., “Dynamic VTII Scaling for Active Leakage Power Reduction,” IEEE Design, Automation and Test in Europe Conference, pp. 163-167 (March 2002) to reduce the active leakage power of a circuit. The DVTS technique uses body bias control to control the threshold voltage, and can provide significant power savings.

Both DVS and DVTS schemes are considered for wireless micro-sensor systems in Chandrakasan et al., “Power Aware Wireless Microsensor Systems,” ESSCIRC, Florence, Italy (September 2002). Due to the need for long battery life for such systems, scaling of both the supply and the threshold voltage is proposed. Similarly, joint optimization of both DVS and adaptive body biasing (ABB) is considered in Martin et al., “Combined Dynamic Voltage Scaling and Adaptive Body Biasing for Lower Power Microprocessors under Dynamic Workloads,” IEEE/ACM, pp. 721-725 (November 2002) to reduce power even when the leakage power is the limiting factor. Martin et al, provide trade-offs between supply voltage and body bias for a given clock frequency and duration of operation, and suggest that the combined voltage and body biasing scaling becomes more effective for deep sub-micron process.

FIG. 1illustrates a high-level block diagram of a prior art communications system100having a transceiver120and a constant voltage supply110, which provides a constant supply voltage Vdd. The transceiver120can be represented as including hypothetical blocks130and140. Hypothetical block130can be considered to include the functional blocks of the transceiver120that are independent of a given system parameter, while hypothetical block140can be considered to include the functional blocks of the transceiver120that are dependent on the given system parameter. As shown inFIG. 1, the same supply voltage Vddcan be applied to all of the functional blocks of the transceiver120, regardless of whether they are dependent on the given system parameter.

The system parameter can include, but need not be limited to, data rate, bit error rate (BER), packet, error rate (PER) and transceiver state (e.g., idle, acquiring, synchronizing, and decoding, etc.). As used herein, the term “system parameter-independent” can describe a functional block of a transceiver for which the structure/functionality of the block does not change when the parameter is changed, while “system parameter-dependent” can describe a functional block of the transceiver for which the structure/functionality of the block changes when the parameter is changed, for example, consider a multi band-OFDM UWB system that can operate at various data rates (see, ECMA-368, “High rate ultra wideband PHY and MAC: standard,” First Edition (December 2005), available at http://www.ecmainternational.org/publications/files/ECMA-T/ECMA-368.pdf). If data rate is the system parameter of interest, then a synchronizer in the multiband-OFDM UWB transceiver can be considered system parameter-independent because it operates on the preamble section of a packet, which is independent of the packet data rate. On the other hand, a Viterbi decoder in the multiband-OFDM UWB transceiver can be considered system parameter-dependent because it outputs a varying number of bits per second in accordance with the data rate.

FIG. 2Aillustrates an exemplary data communications packet200having a header portion210and a payload portion220and illustrates idle periods230when no packet is transmitted or received. InFIG. 2A, the packet200is transmitted (or received) from time instance t1until time instance t3. The packet200can consist of multiple portions, and the system parameters for different portions of the packet200can be different. For example,FIG. 2Billustrates changes in data rate corresponding to the header210and payload220portions of the communications packet200. As shown inFIG. 2B, during the header portion210(from t1to t2), the data rate is Rh. During the payload portion220(from t2to t3), the data rate is changed to Rp. During the idle periods230(before t1and after t3the data rate is zero.FIG. 2Cillustrates a constant voltage supply level applied during each portion of the packet200, in accordance with the prior art system ofFIG. 1. As shown inFIG. 2C, the supply voltage Vddhaving a constant voltage level V1can be applied during transmission (or reception) of all portions of the packet200. In this example, if data rate is the system parameter of interest, the constant voltage level V1is applied regardless of changes in the data rate.

Dynamic Voltage Scaling for Packet-Based Data Communication Transceiver

A power saving technique based on DVS is described herein to reduce circuit energy consumption by a packet-based data communication transceiver. In an embodiment, voltage can be adjusted adaptively based on a system parameter(s) of interest. In an exemplary implementation, a voltage control unit is proposed that can be configured to obtain information related to the system parameter(s), and control a variable voltage supply to provide variable voltage levels to transceiver functions, the operation of which depends on the system parameter(s). In this way, the proposed scheme can provide a constant voltage level to transceiver functional blocks for which the structure/functionality is independent of the system parameter(s), and variable voltage levels to transceiver functional blocks for which the structure/functionality is dependent on the system parameter(s).

FIG. 3illustrates a high-level block diagram of a communication system300having a transceiver330, a constant voltage supply310, which provides a constant supply voltage Vdd1, and a variable voltage supply320, which provides a variable supply voltage Vdd2, in accordance with an embodiment of the present invention. The transceiver330can be represented as including hypothetical blocks340and360, and a voltage control unit350. Hypothetical block340can be considered to include the functional blocks of the transceiver330for which the structure/functionality is independent of a given system parameter, while hypothetical block360can be considered to include the functional blocks of the transceiver330for which the structure/functionality is dependent on the given system parameter. In accordance with an aspect of the present disclosure, the voltage control unit350can be implemented in conjunction with a computer-based system, including hardware, software, firmware, or combinations thereof.

As shown inFIG. 3, the constant supply voltage Vdd1is supplied to the system parameter-independent block340and to the voltage control unit350by the constant voltage supply310. The system parameter-independent block340can provide information about the system parameter to the voltage control unit350via an information signal351. For example, the system parameter-independent block340can provide information about the data rate, BER, and PER, among other information, obtained from a data communication packet header. The voltage control unit350can use the information provided in the information signal351about the system parameter to generate a control signal Vctrl. The control signal Vctrlcan then be used to control the variable supply voltage Vdd2output by the variable voltage supply320and supplied to the system parameter-dependent block360. For example, one or more control signals Vctrlcan be used to adapt the variable supply voltage Vdd2to one or more variable voltage levels in accordance with the system parameter. In this way, system300can be adapted to achieve significant power savings for a given performance criterion. Alternatively, system300can be adapted to optimize performance for a given power constraint.

FIG. 4Aillustrates the exemplary data packet200, having the header portion210and the payload portion220, and illustrates the idle periods230when no packet is transmitted or received. The header portion210is transmitted (or received) from time instance t1to time instance t2, the payload portion220from time instance t2to time instance t3.FIG. 4Billustrates variations in data rate for the different portions of the packet200. For example, during the idle periods230the data rate is zero, during the header portion210(from t1to t2) the data rate is Rh, and during the payload portion220(from t2to t3) the data rate is increased to Rp.

FIG. 4Cillustrates a constant voltage supply level andFIG. 4Dillustrates variable voltage supply levels applied during portions of the packet200, in accordance with the exemplary system300ofFIG. 3. As shown inFIG. 4C, the constant supply voltage Vdd1has a constant voltage level V2, which can be applied to parameter-independent functional blocks of the transceiver during transmission (or reception) of all portions of the packet200. As shown inFIG. 4D, the variable supply voltage Vdd2has variable voltage levels V3, V4, and V5, which can be adaptively applied to parameter-dependent functional blocks of the transceiver during transmission (or reception) of the different portions of the packet200, in accordance with the system parameter(s) of interest.

For example, at the beginning of the packet200(at t1), the variable supply voltage Vdd2can be adapted to a default voltage level V4. Then, during transmission (or reception) of the header portion210of the packet200(from t1to t2), values of the system parameter(s) for subsequent portions of the packet200(e.g., payload portion220) can be determined. These new values of the system parameter(s) can be included in the information signal351and used by the voltage control unit350, shown inFIG. 3, to generate the control signal Vctrlfor adapting the variable supply voltage Vdd2. During the idle periods230(before t1and after t3), the variable supply voltage Vdd2can be adapted to the lowest voltage level V3. From t1to t2, the variable supply voltage Vdd2can be increased to V4, which is the voltage level corresponding to the system parameter of the header portion210. From t2to t3, the variable supply voltage Vdd2, can be increased to V3, which is the voltage level corresponding to the new system parameters (e.g., data rate). At t3, the variable supply voltage Vdd2can be reset to the lowest voltage level V5. Persons skilled in the art will understand that the variable supply voltage Vdd2can be configured to provide more than three or less than three variable voltage levels (V3, V4and V5) and that the variable supply voltage Vdd2can be configured to provide variable voltage levels that are continuous over a range, rather than discrete voltage levels. Further, the voltage control unit350can be configured to generate one or more control signal(s) Vctrlfor adapting the levels of the variable supply voltage Vdd2.

In this way, by adapting the variable supply voltage Vdd2in accordance with the changing data rates Rhand Rp, the packet-based data communication transceiver300can use dynamic voltage sealing to optimize power efficiency of the transceiver. Persons skilled in the art will understand that the system parameter of interest need not be limited to data rate and that the variable supply voltage Vdd2can be adapted in accordance with other system parameter(s) of interest, such as BER, PER, and transceiver state, among others.

In one embodiment, information for the system parameter(s) of interest is available before dynamic voltage scaling is applied. In this way, the variable voltage level applied to parameter-dependent functional blocks of the transceiver can be adapted in a timely manner. For example, information about the data rate of the header portion210of the packet200can be predetermined, while information about the data, rate of the payload portion220can be provided in the header portion210to facilitate timely adaptation of the variable voltage level(s) before transmitting (or receiving) the corresponding portions of the packet. In an alternate embodiment, however, dynamic voltage scaling can be applied even if the values of the system parameter(s) are obtained after they have already changed.

FIG. 5illustrates exemplary steps for a process500for dynamically scaling voltage for a packet-based data communication transceiver. Not all of the steps ofFIG. 5have to occur in the order shown, as will be apparent to persons skilled in the art based on the teachings herein. Other operational and structural embodiments will be apparent to persons skilled in the art based on the following discussion. These steps are described in detail below.

In step505, a constant voltage is supplied to parameter-independent functions of the transceiver. As described herein, parameter-independent functions of the transceiver can include such functions as synchronization, among others, the structure/functionality of which does not depend on a given system parameter(s) of interest (e.g., data rate, BER, PER, transceiver state, etc.). For example, the constant voltage supply310can apply the constant voltage Vdd1to one or more of the system parameter-independent functions340of transceiver330, as shown in the embodiment ofFIG. 3.

In step510, a control signal is generated based on information provided by one or more of the parameter-independent transceiver functions about the predetermined parameter(s). As described herein, information about the data rate, or other system parameters of interest, of a payload portion of a transmitted (or received) data communication packet can be obtained from a header portion of the packet. In this way, system parameter-independent transceiver functions that operate on the header portion of the packet can determine the new data rate information, or other system parameter information of interest. This information can then be used to generate a control signal for controlling a variable voltage supply that supplies voltage to parameter-dependent transceiver functions. For example, the voltage control unit350can generate the control signal Vctrlbased on the information signal351, which includes the information about the system parameter(s) of interest determined by the system parameter-independent transceiver functions340, as shown in the embodiment ofFIG. 3.

In step515, a variable voltage is supplied to parameter-dependent, functions of the transceiver in accordance with the control signal. As described herein, parameter-dependent functions of the transceiver can include such functions as decoding, among others, the structure/functionality of which depends on a given system parameter(s) of interest (e.g., data rate, BER, PER, transceiver state, etc.). For example, the variable voltage supply320can adapt the variable voltage Vdd2in accordance with the control signal Vctrland supply the variable voltage Vdd2to one or more of the system parameter-dependent, transceiver functions360, as shown in the embodiment ofFIG. 3.

Conclusion

The present invention has been described with reference to exemplary embodiments. However, it will be apparent, to those skilled in the art that it is possible to embody the invention in specific forms other than those described above without departing from the spirit of the invention.

Accordingly, the various embodiments described herein are illustrative, and they should not be considered restrictive in any way. The scope of the invention is given by the appended claims, rather than the preceding description, and all variations and equivalents thereof that fall within the range of the claims are intended to be embraced therein.