Abstract:
A technique for reducing power consumption in voltage and current steered differential busses that transmit and receive encoded signals is described. A circuit is used to save power in the static state. The circuit blocks static current flow, but allows the frequency components associated with the signaling band.

Description:
FIELD OF THE INVENTION  
         [0001]    The present invention pertains to the field of integrated circuit design. More particularly, the present invention relates to a power saving termination technique for voltage and current steered differential busses.  
         BACKGROUND OF THE INVENTION  
         [0002]    A computer system typically has components such as a processor, a main memory, a cache, and a chipset. Components of a computer system communicate with one another through interconnections or busses. There are multiple ways to implement a bus. The type of data to be transferred and timing requirements between computer components are common factors used to decide which bus implementation to use.  
           [0003]    The use of differential busses has become more prevalent as the need for extremely high transfer rates between components in a computer system continue to grow. Differential busses typically involve the transfer of a pair of signals, known as a differential pair, such that when data on one transmission line is asserted high, the other transmission line has an active low signal. A receiver receives the signals and looks only at the difference between the two signals. Differential busses help to cancel out noise that is picked up on transmission lines because adjacent wires usually pick up approximately equal noise voltages. The more noise a bus is subjected to, the less timing margin the data is given to propagate across a transmission line. As a result, decreasing the noise on a bus helps a system to achieve improved transfer rates between components.  
           [0004]    Several of the latest differential busses such as Infiniband, Third Generation Input/Output (3GIO), Serial Advanced Technology Attachment (SATA), and Universal Serial Bus (USB) use encoding techniques to eliminate direct current (DC) and low frequency components of a signal. Other busses achieve similar results using a modulation technique. By generating an approximately equal number of digital high and digital low signals to be transmitted across a bus, encoding and modulation helps to reduce signal distortion on the bus.  
           [0005]    Moreover, encoded and modulated signals save power. For example, if an active high signal has to be driven for a great distance over a long period of time, the transmission line has to be charged for the entire time and distance. In the same example, by forcing intermittent low signals over the transmission line, encoded and modulated signals do not require the transmission line to be continuously charged.  
           [0006]    Differential systems, however, are still susceptible to static state conditions such as when the system is placed in a standby mode. During static state, current flows if the voltages on the differential pair are different. As a result, power is dissipated. Thus, in order to conserve power in differential systems, it would be desirable to design a bus circuit that provides a bypass for static current flow while allowing transmitted encoded signals to reach their receiver circuitry.  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0007]    The present invention is illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements and in which:  
         [0008]    [0008]FIG. 1 shows an embodiment of the invention of a power saving Pi termination network driven by a voltage source;  
         [0009]    [0009]FIG. 2 shows a frequency versus magnitude plot of an encoded signal;  
         [0010]    [0010]FIG. 3 shows another embodiment of the invention of a power saving Pi termination network driven by a voltage source;  
         [0011]    [0011]FIG. 4 shows an embodiment of the invention of a power saving T termination network driven by a voltage source;  
         [0012]    [0012]FIG. 5 shows yet another embodiment of the invention of a power saving Pi termination network driven by a voltage source;  
         [0013]    [0013]FIG. 6 shows an embodiment of the invention of a power saving Pi termination network driven by a current source; and  
         [0014]    [0014]FIG. 7 shows an embodiment of the invention of a power saving T termination network driven by a current source.  
     
    
     DETAILED DESCRIPTION  
       [0015]    In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the invention. However, it will be understood by those skilled in the art that the present invention may be practiced without these specific details. In other instances, well-known methods, procedures, components and circuits have not been described in detail so as not to obscure the present invention.  
         [0016]    Conductors or transmission lines that are not terminated result in reflected voltage and current waves. The magnitude of the reflection is determined by the impedance of the lines and by the amplitude of the data. To prevent reflections, transmission lines may be terminated. For one embodiment of the invention, FIG. 1 depicts an example of a Pi termination technique of a voltage steered differential system that saves power during static states. Transmission line  120  and transmission line  125  are a differential pair. The voltage source  110  generates encoded or modified signals that are to be transmitted across transmission lines  120  and  125 . The generated signals on transmission lines  120  and  125  may be differential. In such a case, resistors  140  and  145  may be sized to approximately match the impedance of transmission lines  120  and  125  when transmission lines  120  and  125  are in even mode. Even mode is defined by the situation where the data on transmission lines  120  and  125  are identical and switch at approximately the same time. In contrast, resistor  130  may be sized to approximately match the impedance of transmission lines  120  and  125  when transmission lines  120  and  125  are in odd mode. Odd mode is defined by the situation where the data on transmission lines  120  and  125  are in opposite states. Thus, in odd mode, the data on transmission line  120  is active high when the data on transmission  125  is active low.  
         [0017]    Capacitor  150  is coupled between transmission line  120  and resistors  130  and  140 . Similarly, capacitor  160  is coupled between transmission line  125  and resistors  130  and  145 . Capacitors  150  and  160  may be sized according to the impedance and length of transmission lines  120  and  125 , the frequency of the data transmitted by voltage source  110 , and the allowable noise of the circuit.  
         [0018]    Impedance is defined by the formula  
           Z =( L/C ) 1/2 ,  (1)  
         [0019]    whereby Z is the impedance, L is the inductance, and C is the capacitance of the transmission line. From the impedance formula above, the inductance may be represented as  
           L=Z   2   *C.   (2)  
         [0020]    The delay per unit length, t, of the transmission line is defined by the formula  
           t= 1/( f*d )=( L*C ) 1/2 ,  (3)  
         [0021]    whereby f is the frequency of the data on the transmission line and d is the length of the transmission line. Substituting equation (2) into equation (3), it follows that  
           t =( Z   2   *C*C ) 1/2   =z*C.   (4)  
         [0022]    It can be derived from equations (3) and (4) that  
           C=t/Z= 1/( Z*f*d ).  (5)  
         [0023]    As previously stated, capacitors  150  and  160  may be sized according to the impedance of the transmission lines and the frequency of the data being transmitted on the transmission line. Noise on the transmission line can be factored into the capacitor value of equation (5) by defining the frequency and distance specifications conservatively. The capacitors  150  and  160  act similar to resistors having, infinite impedance when the currents and voltages in the circuit  100  do not vary with time. Because the DC signals are filtered by the capacitors  150  and  160 , no current flows through the circuit and no power is dissipated. The high frequency encoded or modulated signals, however, are not constrained by the capacitors  150  and  160 .  
         [0024]    [0024]FIG. 2 depicts a frequency versus magnitude plot of an encoded signal  230 . X-axis  210  is the frequency of the signal and y-axis  220  is the magnitude of the signal at a given frequency. Because the encoded signal  230  lacks low frequency content, capacitors  150  and  160  are able to filter out low frequency components transmitted on transmission lines  120  and  125  that are not a part of the encoded signal  230 .  
         [0025]    [0025]FIG. 3 depicts another example of a modified Pi termination technique of a voltage steered differential system that saves power during static states. For this embodiment of the invention, voltage sources  310  and  315  of circuit  300  generate data to be transmitted across transmission lines  320  and  325 . Capacitor  350  is coupled between voltage source  310  and transmission line  320 , while capacitor  360  is coupled between voltage source  315  and transmission line  325 . Transmission line  320  is also coupled to resistors  330  and  340 . Transmission line  325  is coupled to resistors  330  and  345 . Resistors  330 ,  340 , and  345  serve to terminate the transmission lines  320  and  325 . Termination helps to reduce reflection noise on transmission lines. To help stop static current flow, the capacitors  350  and  360  are sized according to the impedance and length of transmission lines  320  and  325 , the frequency of the data transmitted by voltage sources  310  and  315 , and the allowable noise of the network.  
         [0026]    For another embodiment of the invention, FIG. 4 depicts an example of a modified T termination technique of a voltage steered differential system that saves power during static states. Circuit  400  has a T termination structure. Voltage sources  410  and  415  generate differential signals to be transferred across transmission lines  420  and  425 . The transmission line  420  is coupled to resistor  440  and the transmission line  425  is coupled to resistor  445 . Capacitor  450  is coupled to resistor  440  and capacitor  450 . Capacitor  460  is coupled to resistor  445  and capacitor  450 . Resistor  430  is coupled to both capacitors  450  and  460 . The capacitors  450  and  460  block static current flow in the circuit  400 , preventing power dissipation when DC signals are transmitted across transmission lines  420  and  425 .  
         [0027]    [0027]FIG. 5 depicts another example of a modified T termination technique of a voltage steered differential system that saves power during static states. In this example, voltage sources  510  and  515  generate signals to be transmitted across transmission line  520  and transmission line  525 . Resistors  530  and  540  are coupled to transmission line  520 . Resistor  530  is also coupled to a node of capacitor  550 . The other node of capacitor  550  is coupled to transmission line  525  and resistor  545 . Capacitor  550  acts to block the static current flow across transmission lines  520  and  525 .  
         [0028]    For yet another embodiment of the invention, FIG. 6 depicts an example of a power saving Pi termination of a current steered differential system. Like voltage steered busses, current steered differential systems that use the Pi and T termination networks dissipates power when the bus is static, or in a standby state. When the system is in a static state, current flows through the termination network, which results in power loss. Current source  610  generates data to be distributed on transmission lines  620  and  625 . Resistors  630 ,  640 , and  645  are coupled to the transmission lines to terminate the transmission lines  620  and  625 . To prevent static current flow, circuit  600  incorporates an inductor  650  to block static current flow. Inductors appear as a zero resistance connection (short circuit) in a DC circuit. Thus, inductor  650  provides a bypass for the static current flow, but is small enough in value to act as a high impedance path for the frequency components associated with the data.  
         [0029]    The value of the inductor may be chosen according to the impedance of the transmission lines, the frequency of the data being transferred and the length of the transmission lines. From the impedance formula of equation (1), capacitance is defined as  
           C=L/Z   2 .  (6)  
         [0030]    Substituting equation (6) into equation (3),  
           t= 1/ f*d=L/Z.   (7)  
         [0031]    From equation (7),  
           L=Z/f*d.   (8)  
         [0032]    For yet another embodiment of the invention, FIG. 7 depicts an example of a power saving T termination for a pair of current steered differential signals. Current source  710  generates signals to be distributed on transmission lines  720  and  725 . The transmission lines  720  and  725  are terminated using a T termination network comprising resistors  740 ,  745 , and  730 . Inductor  750  is coupled to transmission lines  720  and  725  to provide a bypass for static current flow.  
         [0033]    In the foregoing specification the invention has been described with reference to specific exemplary embodiments thereof. It will, however, be evident that various modification and changes may be made thereto without departure from the broader spirit and scope of the invention as set forth in the appended claims. The specification and drawings are, accordingly, to be regarded in an illustrative rather than restrictive sense.