WO1996041421A1 - High speed, low power cmos d/a converter for wave synthesis in network - Google Patents

High speed, low power cmos d/a converter for wave synthesis in network Download PDF

Info

Publication number
WO1996041421A1
WO1996041421A1 PCT/US1996/002823 US9602823W WO9641421A1 WO 1996041421 A1 WO1996041421 A1 WO 1996041421A1 US 9602823 W US9602823 W US 9602823W WO 9641421 A1 WO9641421 A1 WO 9641421A1
Authority
WO
WIPO (PCT)
Prior art keywords
current
terminal
control signal
coupled
node
Prior art date
Application number
PCT/US1996/002823
Other languages
French (fr)
Inventor
John Michael Wincn
Original Assignee
Advanced Micro Devices, Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Advanced Micro Devices, Inc. filed Critical Advanced Micro Devices, Inc.
Priority to DE69601268T priority Critical patent/DE69601268T2/en
Priority to EP96908603A priority patent/EP0834220B1/en
Priority to JP9500430A priority patent/JPH11506286A/en
Publication of WO1996041421A1 publication Critical patent/WO1996041421A1/en

Links

Classifications

    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03MCODING; DECODING; CODE CONVERSION IN GENERAL
    • H03M1/00Analogue/digital conversion; Digital/analogue conversion
    • H03M1/06Continuously compensating for, or preventing, undesired influence of physical parameters
    • H03M1/0617Continuously compensating for, or preventing, undesired influence of physical parameters characterised by the use of methods or means not specific to a particular type of detrimental influence
    • H03M1/0675Continuously compensating for, or preventing, undesired influence of physical parameters characterised by the use of methods or means not specific to a particular type of detrimental influence using redundancy
    • H03M1/0678Continuously compensating for, or preventing, undesired influence of physical parameters characterised by the use of methods or means not specific to a particular type of detrimental influence using redundancy using additional components or elements, e.g. dummy components
    • H03M1/068Continuously compensating for, or preventing, undesired influence of physical parameters characterised by the use of methods or means not specific to a particular type of detrimental influence using redundancy using additional components or elements, e.g. dummy components the original and additional components or elements being complementary to each other, e.g. CMOS
    • H03M1/0682Continuously compensating for, or preventing, undesired influence of physical parameters characterised by the use of methods or means not specific to a particular type of detrimental influence using redundancy using additional components or elements, e.g. dummy components the original and additional components or elements being complementary to each other, e.g. CMOS using a differential network structure, i.e. symmetrical with respect to ground
    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03MCODING; DECODING; CODE CONVERSION IN GENERAL
    • H03M1/00Analogue/digital conversion; Digital/analogue conversion
    • H03M1/66Digital/analogue converters
    • H03M1/74Simultaneous conversion
    • H03M1/742Simultaneous conversion using current sources as quantisation value generators
    • H03M1/747Simultaneous conversion using current sources as quantisation value generators with equal currents which are switched by unary decoded digital signals

Definitions

  • the present invention relates generally to semiconductor integrated circuits and more specifically to integration of aveshaping functions into an integrated circuit that drives a differential signal onto a local area network.
  • US Patent No. 5,357,145 titled Integrated Waveshaping Circuit Using Weighted Current Summing and Issued Oct. 18, 1994 describes relevant background for understanding the present invention, as well as describing one conventional solution to on-chip wave synthesis.
  • Various network protocols such as IEEE Standards 802.3
  • US Patent 5,357,145 hereby expressly incorporated by reference for all purposes, illustrates a solution to wave shaping incorporating a weighted sum solution that provides an output waveform designed to represent a shape of an output signal after it has passed through a filter.
  • the solution disclosed in the US Patent No. 5,357,145 provides a plurality of current cells that are controlled in a fashion so that output contributions of the various cells provide the desired wave shape. Generically, this conversion process defines a digital to analog (D/A) converter or DAC implementation.
  • D/A digital to analog
  • the present invention provides apparatus and method for simply, efficiently and economically improving performance over conventional D/A converters.
  • the preferred embodiment provides an improved performance partially because of a decrease in capacitive loading of current output drivers used in least significant bit cells making up the improved D/A converter and has a lower power consumption than previous versions of DACs.
  • the improved D/A converter may be faster and produce less distortion while consuming less power than conventional D/A converters.
  • a low power least significant bit (LSB) cell for an integrated digital to analog converter that drives an incremental current at each of a first and a second output node, includes a first pair of a first and second matching MOS transistor, each having a first terminal node, a second terminal node and a gate terminal node, the gate terminal nodes receiving a bias current for controlling an operating current between the first terminal node and second terminal node and wherein the first terminal node of the first MOS transistor is coupled to the first output node and the first terminal node of the second MOS transistor is coupled to the second output node.
  • LSB low power least significant bit
  • the low power LSB cell includes a first current source having a first current terminal coupled to the second terminal node of the first MOS transistor and a second current terminal coupled to a voltage reference level, the first current source is responsive to a first control signal for switching a first operating current through the first MOS transistor on when the first control signal has a first value and switching the first operating current through the first MOS transistor off when the first control signal has a second value; and a second current source having a first current terminal coupled to the second terminal node of the second MOS transistor and a second current terminal coupled to the voltage reference level, the second current source responsive to a second control signal for switching a second operating current through the second MOS transistor ON when the second control signal has a first value and switching the second operating current through the second MOS transistor OFF when the second control signal has a second value.
  • the low power LSB cell includes a second pair of a third and fourth matching MOS transistor, each having a first terminal node, a second terminal node and a gate terminal node, the gate terminal nodes receiving a bias current for controlling an operating current between the first terminal node and second terminal node and wherein the first terminal node of the third MOS transistor is coupled to the first output node and the first terminal node of the fourth MOS transistor is coupled to the second output node.
  • the low power LSB cell includes a third current source having a first current terminal coupled to the second terminal node of the third MOS transistor and a second current terminal coupled to a second voltage reference level, the third current source is responsive to a third control signal for switching a third operating current through the third MOS transistor ON when the third control signal has a first value and switching the third operating current through the third MOS transistor OFF when the third control signal has a second value; and a fourth current source having a first current terminal coupled to the second terminal node of the fourth MOS transistor and a second current terminal coupled to the second voltage reference level, the fourth current source responsive to a fourth control signal for switching a fourth operating current through the fourth MOS transistor ON when the fourth control signal has a first value and switching the fourth operating current through the fourth MOS transistor OFF when the fourth control signal has a second value.
  • Fig. 1 is a schematic block diagram of a preferred embodiment of a twisted pair transmitter 50 including a high speed, low power, digital to analog converter (DAC) 100 for wave synthesis;
  • Fig. 2 is a block schematic diagram of DAC 100;
  • Fig. 3 is a detail block diagram of cell 200i shown in Fig. 2;
  • Fig. 4 is a detailed schematic diagram of LSB cell 300 shown in Fig. 3;
  • Fig. 5 is a schematic diagram of mirror circuit 205 shown in Fig. 2; and
  • Fig. 6 is a schematic diagram of mirror circuit 210 shown in Fig. 2.
  • Fig. 1 is a schematic block diagram of a preferred embodiment of a twisted pair transmitter 50 including a high speed digital to analog converter (DAC) 100 for wave synthesis.
  • Twisted pair transmitter includes a core logic circuit 102 that provides a plurality of control signals, an enable signal, a clock signal, a reset signal, and two bias signals (P_BIAS and N_BIAS) to DAC 100. These signals define operation of DAC 100 and control a differential signal driven on a differential output (IOP and ION) of DAC 100.
  • a terminating resistor RT provides termination and couples IOP to ION as well known. Additionally, the differential signal at IOP and ION is provided to a transformer T.
  • core logic 102 determines the shape of the differential signal to be driven from the output of DAC 100. As will be explained in further detail later, core logic 102 selects a combination of control signals to drive the output differential signal to the desired level.
  • core logic 102 first asserts the enable signal to DAC 100 to enable its operation. With the enable signal deasserted, DAC 100 dissipates very low levels of power irrespective of the status of the control signals and the bias signal. After asserting the enable signal, core logic 102 asserts the bias signals to DAC 100, and selective ones of the control signals. Assertion of the clock signal synchronizes application of the control signals to current cells within DAC 100. In response to particular combinations of the control signals (while enable and bias are asserted) , DAC 100 drives the output differential signal at the desired levels. Details regarding operation of DAC 100 are explained more specifically with regard to Figs. 2-6 below.
  • Fig. 2 is a block schematic diagram of DAC 100.
  • DAC 100 includes a plurality of cells 200 i that each respond to selected ones of synchronized control signals (SCNTLx) to add a predetermined amount of current to collectively define the differential output signal.
  • the synchronized control signal SCNTLx are output from synchronizers 203x.
  • Synchronizers 203x are implemented, in the preferred embodiment, by D flip-flops that latch a corresponding CNTLx signal as SCNTL signal in response to the clock signal from core logic 102.
  • DAC 100 includes a first mirror circuit 205 and a second mirror circuit 210.
  • Mirror circuit 205 is responsive to the N_BIAS signal to establish an N_BIAS mirror current that is provided to each of the plurality of cells 200 ⁇ .
  • Mirror circuit 210 is responsive to the P_BIAS signal to establish a P_BIAS mirror current that is provided to each of the plurality of cells 200 ⁇
  • the enable signal is also provided to each of the cells 200 1 .
  • Inverters G x , G 2 and G 3 delay assertion of the enable signal. Inverter G receives the enable signal at its input.
  • Inputs of inverter G 2 and inverter G 3 are coupled to an output of inverter G lf with an output of inverter G 2 driving the delayed enable signal to one-half (in the preferred embodiment) of the plurality of cells 200i and with an output of inverter G 3 driving the delayed enable signal to the other one-half of the plurality of cells 200 ⁇
  • Each cell 200 i of the preferred embodiment has a slightly different configuration, details of which are explained with regard to Fig. 3.
  • Each cell 200 x is responsive to a synchronized control signal SCNTL_X. Each cell 200 thus receives the mirror currents, an enable signal and a synchronized control signal.
  • assertion of the bias signals and assertion of the enable signal by core logic 102 shown in Fig. 1 establishes the mirror currents for each cell 200 ⁇ Asserting the clock signal when all CNTLX signals are in the desired state latches the control signals as the synchronized control signals. Thereafter, depending upon particular ones of the differential control signals asserted by synchronizers 203x, particular ones of the plurality of cells 200 i add a predetermined amount of current to the differential output signal. For example in the preferred embodiment, cell 200 1 may add 10 milliamps (mA) , cell 200 2 may add 6 mA, etc. With enough cells provided to uniquely define the desired output range of DAC 100, the combination of cells 200i produce a simple mechanism to convert input digital signals (the combination of the control signals) into an analog output (the output differential signal at IOP and ION) .
  • the plurality of cells 200i are divided into two subgroups (220 and 225) . These subgroups of cells are provided in parallel to improve layout efficiency when integrated into a semiconductor device. Thus, for specific embodiments, the particular groupings of the plurality of cells 200i may be different. In the preferred embodiment, each subgroup includes two 10 mA cells, one 6 mA cell, three 4 mA cells, two 3 mA cells, two 2 mA cells, and two 1 mA cells. Corresponding cells in the respective subgroups are responsive to the same synchronized control signal. Again, particular embodiments may use different numbers or configurations of cells 200i.
  • Fig. 3 is a detail block diagram of cell 200i shown in Fig. 2.
  • a particular cell 200i includes one or more least significant bit (LSB) cells 300.
  • LSB cells 300 making up a particular cell 200i are coupled to each other in parallel to receive the synchronized control signal (CNTL_i) , the enable signal and the mirror currents.
  • Each LSB cell 300 of the preferred embodiment provides the same amount of drive current.
  • each LSB cell 300 provides one-half of the minimum step of DAC 100.
  • LSB 300 drives one-half milliamp, allowing for a 1 mA cell 200.
  • Inverters G 10 , G ⁇ and G 12 , and inverters G 15 , G 16 , and G 17 provide delay for the. synchronized control signal CNTL_X and the delayed enable signal, respectively.
  • Fig. 4 is a detailed schematic diagram of LSB cell 300 shown in Fig. 3.
  • LSB cell 300 includes two N-channel metal oxide field-effect transistors (MOSFETs) Ql and Q2, two P- channel MOSFETs Q3 and Q4, four switchable current sources 400 ⁇ two dual-input NOR gates G20 and G21, two dual-input NAND gates G22 and G23, and two inverters G24 and G25.
  • ' Transistor Ql and transistor Q2 each include a gate for receipt of the N_BIAS mirror current provided from first mirror circuit 205 shown in Fig. 2.
  • Transistor Ql and transistor Q2 are, in the preferred embodiment, identical to each other and are scaled relative to a transistor in mirror circuit 205 (as described further below) to produce a preselected current level in response to the bias signal provided from core logic 205 shown in Fig. 2.
  • Transistor Ql includes a drain coupled to an IOP output port and transistor Q2 includes a drain coupled to an ION output port.
  • a source of transistor Ql is coupled to a first terminal of one current source 400 ! and a source of transistor Q2 is coupled to a first terminal of the other current source 400 2 .
  • a second terminal of each of the current sources 400 is coupled to a first reference voltage (e.g., ground).
  • Each current source 400 has a control terminal for receipt of a control signal. Assertion of the control signal to current source 400 ! results in activation of current source 400 ! . Similarly, assertion of the control signal to current source 400 2 activates current source 400 2 .
  • first NOR gate G20 is coupled to the control terminal of current source 400 ! and an output of second NOR gate G21 is coupled to the control terminal of current source
  • a first input of first NOR gate G20 receives the synchronized control signal while the second input of the first NOR gate G20 receives an output of second inverter G25.
  • the enable signal is provided to the input of inverter G25.
  • a first input of second NOR gate G21 is coupled to an output of first inverter G24, with the input of first inverter G24 coupled to the synchronized control signal input line.
  • the second input of second NOR gate G21 is coupled to the output of second inverter G25.
  • Transistor Q3 and transistor Q4 each include a gate for receipt of the P_BIAS mirror current provided from second mirror circuit 210 shown in Fig. 2.
  • Transistor Q3 and transistor Q4 are, in the preferred embodiment, identical to each other and are scaled relative to a transistor in mirror circuit 210 (as described further below) to produce a preselected current level in response to the P_BIAS signal provided from second mirror circuit 210 shown in Fig. 2.
  • Transistor Q3 includes a source coupled to the IOP output port and transistor Q4 includes a source coupled to the ION output port.
  • a drain of transistor Q3 is coupled to a first terminal of a third current source 400 3 and a drain of transistor Q4 is coupled to a first terminal of the fourth current source 400 4 .
  • a second terminal of each of the current sources 400 3 and 400 4 is coupled to a second reference voltage (e.g., Vdd) .
  • Vdd a second reference voltage
  • Each current source 400 3 and 400 4 has a control terminal for receipt of a control signal. Assertion of the control signal to current source 400 3 results in activation of current source
  • An output of second NAND gate G23 is coupled to the control terminal of current source 400 4 and an output of first NAND gate G22 is coupled to the control terminal of current source 400 4 .
  • a first input of second NAND gate G23 receives the synchronized control signal while the second input of the second NAND gate G23 receives the enable signal.
  • a first input of first NAND gate G22 is coupled to the output of first inverter G24. The second input of first NAND gate G22 is coupled to the enable signal.
  • resistors R are coupled to the output of LSB 300.
  • a first resistor R is coupled between the second voltage reference and IOP, a second resistor R is coupled between the second voltage reference and ION, a third resistor R coupled between IOP and the first voltage reference and a fourth resistor R coupled between ION and the first voltage reference.
  • resistors R must be very large in relation to a terminating resistor R ⁇ (shown in Fig. 1) .
  • Resistors R may be integrated into the DAC 100 or provided externally.
  • assertion of the N_BIAS mirror current to transistor Ql and to transistor Q2 attempts to establish a scaled current from either IOP or ION to the first voltage reference level
  • assertion of the P_BIAS mirror current to transistor Q3 and to transistor Q4 attempts to establish a scaled current from either IOP or ION to the second voltage reference level. Whether one of these currents is established depends upon which, if any, of the control signals are asserted to which of the current sources 400.
  • first current source 4001 CNTL is deasserted and enable is asserted.
  • second current source 4002 CNTL is asserted and enable is asserted.
  • first and third current sources, and second and fourth current sources turn on and off as groups to drive the differential signal as well known.
  • One aspect of the low power mode is that the outputs of IOP and ION sit halfway between the first and second voltage references so that when beginning operation, large currents are not necessary to pull the outputs from one of the voltage reference levels.
  • Fig. 5 is a schematic diagram of first mirror circuit 205 shown in Fig. 2.
  • Mirror circuit 205 of the preferred embodiment includes a third N-channel MOSFET Q10 coupled in series to a fourth N-channel MOSFET Qll.
  • a drain and gate of MOSFET Q10 is coupled to the n__bias input for receiving the n_bias input signal while a source of MOSFET Q10 is coupled to a drain of MOSFET Qll.
  • a source of MOSFET Qll is coupled to the first voltage reference level. Configuring MOSFET Q10 and MOSFET Qll in this fashion forms one part of the first current mirror. It is one important aspect of the preferred embodiment to closely match transistor Ql and transistor Q2 of each LSB 300 to MOSFET Q3 in order to complete the current mirror. Additionally, it is an important aspect of the preferred embodiment to closely match transistors of the current sources 4001 and 4002 to transistor Qll.
  • Fig. 6 is a schematic diagram of second mirror circuit 210 shown in Fig. 2.
  • Mirror circuit 210 of the preferred embodiment includes a third p-channel MOSFET Q12 coupled in series to a fourth p-channel MOSFET Q13.
  • a source and gate of MOSFET Q13 is coupled to the p_bias input for receiving the p_bias input signal while a drain of MOSFET Q13 is coupled to a source of MOSFET Q12.
  • a gate of MOSFET Q13 is coupled to the source of MOSFET Q13, while a gate of MOSFET Q12 is coupled to the first voltage reference level.
  • a drain of MOSFET Q12 is coupled to the second voltage reference level. Configuring MOSFET Q12 and MOSFET Q13 in this fashion forms one part of the second current mirror.
  • the present invention provides a simple, efficient solution to a problem of providing a high-speed, low power DAC for use in wave synthesis when communicating over a twisted pair network. While the above is a complete description of the preferred embodiments of the invention, various alternatives, modifications, and equivalents may be used. Therefore, the above description should not be taken as limiting the scope of the invention which is defined by the appended claims.

Abstract

A high speed low power digital-to-analog (D/A) converter (DAC) includes a plurality of least significant bit (LSB) cells that collectively define a total output of the DAC. Each LSB cell includes a differential current driver that has reduced capacitive loading due to a cascode structure of the current driver wherein transistors are biased to desired levels and current sources are switched on and off to control the differential output signal.

Description

HIGH SPEED, LOW POWER CMOS D/A CONVERTER FOR WAVE
SYNTHESIS IN NETWORK
BACKGROUND OF THE INVENTION
The present invention relates generally to semiconductor integrated circuits and more specifically to integration of aveshaping functions into an integrated circuit that drives a differential signal onto a local area network. US Patent No. 5,357,145 titled Integrated Waveshaping Circuit Using Weighted Current Summing and Issued Oct. 18, 1994 describes relevant background for understanding the present invention, as well as describing one conventional solution to on-chip wave synthesis. Various network protocols such as IEEE Standards 802.3
(Ethernet) and lOBase-T (twisted pair) , both hereby expressly incorporated by reference for all purposes, define operational characteristics for various data signals. To implement a data transmitter for twisted pair wiring using an integrated circuit solution, many conventional systems rely on external filter elements to properly shape the output wave.
US Patent 5,357,145, hereby expressly incorporated by reference for all purposes, illustrates a solution to wave shaping incorporating a weighted sum solution that provides an output waveform designed to represent a shape of an output signal after it has passed through a filter. The solution disclosed in the US Patent No. 5,357,145 provides a plurality of current cells that are controlled in a fashion so that output contributions of the various cells provide the desired wave shape. Generically, this conversion process defines a digital to analog (D/A) converter or DAC implementation.
For effective operation, construction and control of the current cells is important to provide a robust, fast, and reliable D/A converter for use in waveform synthesis. The solution described in US Patent No. 5,357,145 provides a current cell that may have excessive parasitic capacitance that can limit an operational speed of the D/A converter. Some implementations of a DAC consume excessive power. In some of these embodiments, it may be desirable to have reduced power DAC.
SUMMARY OF THE INVENTION The present invention provides apparatus and method for simply, efficiently and economically improving performance over conventional D/A converters. The preferred embodiment provides an improved performance partially because of a decrease in capacitive loading of current output drivers used in least significant bit cells making up the improved D/A converter and has a lower power consumption than previous versions of DACs. Thus, the improved D/A converter may be faster and produce less distortion while consuming less power than conventional D/A converters. According to one aspect of the invention, a low power least significant bit (LSB) cell for an integrated digital to analog converter that drives an incremental current at each of a first and a second output node, includes a first pair of a first and second matching MOS transistor, each having a first terminal node, a second terminal node and a gate terminal node, the gate terminal nodes receiving a bias current for controlling an operating current between the first terminal node and second terminal node and wherein the first terminal node of the first MOS transistor is coupled to the first output node and the first terminal node of the second MOS transistor is coupled to the second output node. The low power LSB cell includes a first current source having a first current terminal coupled to the second terminal node of the first MOS transistor and a second current terminal coupled to a voltage reference level, the first current source is responsive to a first control signal for switching a first operating current through the first MOS transistor on when the first control signal has a first value and switching the first operating current through the first MOS transistor off when the first control signal has a second value; and a second current source having a first current terminal coupled to the second terminal node of the second MOS transistor and a second current terminal coupled to the voltage reference level, the second current source responsive to a second control signal for switching a second operating current through the second MOS transistor ON when the second control signal has a first value and switching the second operating current through the second MOS transistor OFF when the second control signal has a second value.
The low power LSB cell includes a second pair of a third and fourth matching MOS transistor, each having a first terminal node, a second terminal node and a gate terminal node, the gate terminal nodes receiving a bias current for controlling an operating current between the first terminal node and second terminal node and wherein the first terminal node of the third MOS transistor is coupled to the first output node and the first terminal node of the fourth MOS transistor is coupled to the second output node. The low power LSB cell includes a third current source having a first current terminal coupled to the second terminal node of the third MOS transistor and a second current terminal coupled to a second voltage reference level, the third current source is responsive to a third control signal for switching a third operating current through the third MOS transistor ON when the third control signal has a first value and switching the third operating current through the third MOS transistor OFF when the third control signal has a second value; and a fourth current source having a first current terminal coupled to the second terminal node of the fourth MOS transistor and a second current terminal coupled to the second voltage reference level, the fourth current source responsive to a fourth control signal for switching a fourth operating current through the fourth MOS transistor ON when the fourth control signal has a first value and switching the fourth operating current through the fourth MOS transistor OFF when the fourth control signal has a second value.
Reference to the remaining portions of the specification, including the drawing and claims, will realize other features and advantages of the present invention. Further features and advantages of the present invention, as well as the structure and operation of various embodiments of the present invention, are described in detail below with respect to accompanying drawing. In the drawing, like reference numbers indicate identical or functionally similar elements.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a schematic block diagram of a preferred embodiment of a twisted pair transmitter 50 including a high speed, low power, digital to analog converter (DAC) 100 for wave synthesis; Fig. 2 is a block schematic diagram of DAC 100;
Fig. 3 is a detail block diagram of cell 200i shown in Fig. 2;
Fig. 4 is a detailed schematic diagram of LSB cell 300 shown in Fig. 3; Fig. 5 is a schematic diagram of mirror circuit 205 shown in Fig. 2; and
Fig. 6 is a schematic diagram of mirror circuit 210 shown in Fig. 2.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Fig. 1 is a schematic block diagram of a preferred embodiment of a twisted pair transmitter 50 including a high speed digital to analog converter (DAC) 100 for wave synthesis. Twisted pair transmitter includes a core logic circuit 102 that provides a plurality of control signals, an enable signal, a clock signal, a reset signal, and two bias signals (P_BIAS and N_BIAS) to DAC 100. These signals define operation of DAC 100 and control a differential signal driven on a differential output (IOP and ION) of DAC 100. A terminating resistor RT provides termination and couples IOP to ION as well known. Additionally, the differential signal at IOP and ION is provided to a transformer T.
In operation, core logic 102 determines the shape of the differential signal to be driven from the output of DAC 100. As will be explained in further detail later, core logic 102 selects a combination of control signals to drive the output differential signal to the desired level. In order to operate DAC 100, core logic 102 first asserts the enable signal to DAC 100 to enable its operation. With the enable signal deasserted, DAC 100 dissipates very low levels of power irrespective of the status of the control signals and the bias signal. After asserting the enable signal, core logic 102 asserts the bias signals to DAC 100, and selective ones of the control signals. Assertion of the clock signal synchronizes application of the control signals to current cells within DAC 100. In response to particular combinations of the control signals (while enable and bias are asserted) , DAC 100 drives the output differential signal at the desired levels. Details regarding operation of DAC 100 are explained more specifically with regard to Figs. 2-6 below.
Fig. 2 is a block schematic diagram of DAC 100. DAC 100 includes a plurality of cells 200i that each respond to selected ones of synchronized control signals (SCNTLx) to add a predetermined amount of current to collectively define the differential output signal. The synchronized control signal SCNTLx are output from synchronizers 203x. Synchronizers 203x are implemented, in the preferred embodiment, by D flip-flops that latch a corresponding CNTLx signal as SCNTL signal in response to the clock signal from core logic 102. Additionally, DAC 100 includes a first mirror circuit 205 and a second mirror circuit 210. Mirror circuit 205 is responsive to the N_BIAS signal to establish an N_BIAS mirror current that is provided to each of the plurality of cells 200±. Mirror circuit 210 is responsive to the P_BIAS signal to establish a P_BIAS mirror current that is provided to each of the plurality of cells 200^ The enable signal is also provided to each of the cells 2001. Inverters Gx, G2 and G3 delay assertion of the enable signal. Inverter G receives the enable signal at its input. Inputs of inverter G2 and inverter G3 are coupled to an output of inverter Glf with an output of inverter G2 driving the delayed enable signal to one-half (in the preferred embodiment) of the plurality of cells 200i and with an output of inverter G3 driving the delayed enable signal to the other one-half of the plurality of cells 200^ Each cell 200i of the preferred embodiment has a slightly different configuration, details of which are explained with regard to Fig. 3. Each cell 200x is responsive to a synchronized control signal SCNTL_X. Each cell 200 thus receives the mirror currents, an enable signal and a synchronized control signal.
In operation, assertion of the bias signals and assertion of the enable signal by core logic 102 shown in Fig. 1 establishes the mirror currents for each cell 200^ Asserting the clock signal when all CNTLX signals are in the desired state latches the control signals as the synchronized control signals. Thereafter, depending upon particular ones of the differential control signals asserted by synchronizers 203x, particular ones of the plurality of cells 200i add a predetermined amount of current to the differential output signal. For example in the preferred embodiment, cell 2001 may add 10 milliamps (mA) , cell 2002 may add 6 mA, etc. With enough cells provided to uniquely define the desired output range of DAC 100, the combination of cells 200i produce a simple mechanism to convert input digital signals (the combination of the control signals) into an analog output (the output differential signal at IOP and ION) .
In the preferred embodiment, the plurality of cells 200i are divided into two subgroups (220 and 225) . These subgroups of cells are provided in parallel to improve layout efficiency when integrated into a semiconductor device. Thus, for specific embodiments, the particular groupings of the plurality of cells 200i may be different. In the preferred embodiment, each subgroup includes two 10 mA cells, one 6 mA cell, three 4 mA cells, two 3 mA cells, two 2 mA cells, and two 1 mA cells. Corresponding cells in the respective subgroups are responsive to the same synchronized control signal. Again, particular embodiments may use different numbers or configurations of cells 200i. Fig. 3 is a detail block diagram of cell 200i shown in Fig. 2. A particular cell 200i includes one or more least significant bit (LSB) cells 300. LSB cells 300 making up a particular cell 200i are coupled to each other in parallel to receive the synchronized control signal (CNTL_i) , the enable signal and the mirror currents. Each LSB cell 300 of the preferred embodiment provides the same amount of drive current. In the preferred configuration illustrated in Fig. 3, each LSB cell 300 provides one-half of the minimum step of DAC 100. In the preferred embodiment, LSB 300 drives one-half milliamp, allowing for a 1 mA cell 200. Inverters G10, Gια and G12, and inverters G15, G16, and G17 provide delay for the. synchronized control signal CNTL_X and the delayed enable signal, respectively.
Fig. 4 is a detailed schematic diagram of LSB cell 300 shown in Fig. 3. LSB cell 300 includes two N-channel metal oxide field-effect transistors (MOSFETs) Ql and Q2, two P- channel MOSFETs Q3 and Q4, four switchable current sources 400^ two dual-input NOR gates G20 and G21, two dual-input NAND gates G22 and G23, and two inverters G24 and G25.' Transistor Ql and transistor Q2 each include a gate for receipt of the N_BIAS mirror current provided from first mirror circuit 205 shown in Fig. 2. Transistor Ql and transistor Q2 are, in the preferred embodiment, identical to each other and are scaled relative to a transistor in mirror circuit 205 (as described further below) to produce a preselected current level in response to the bias signal provided from core logic 205 shown in Fig. 2. Transistor Ql includes a drain coupled to an IOP output port and transistor Q2 includes a drain coupled to an ION output port. A source of transistor Ql is coupled to a first terminal of one current source 400! and a source of transistor Q2 is coupled to a first terminal of the other current source 4002. A second terminal of each of the current sources 400 is coupled to a first reference voltage (e.g., ground). Each current source 400 has a control terminal for receipt of a control signal. Assertion of the control signal to current source 400! results in activation of current source 400!. Similarly, assertion of the control signal to current source 4002 activates current source 4002.
An output of first NOR gate G20 is coupled to the control terminal of current source 400! and an output of second NOR gate G21 is coupled to the control terminal of current source
4002. A first input of first NOR gate G20 receives the synchronized control signal while the second input of the first NOR gate G20 receives an output of second inverter G25. The enable signal is provided to the input of inverter G25. A first input of second NOR gate G21 is coupled to an output of first inverter G24, with the input of first inverter G24 coupled to the synchronized control signal input line. The second input of second NOR gate G21 is coupled to the output of second inverter G25.
Transistor Q3 and transistor Q4 each include a gate for receipt of the P_BIAS mirror current provided from second mirror circuit 210 shown in Fig. 2. Transistor Q3 and transistor Q4 are, in the preferred embodiment, identical to each other and are scaled relative to a transistor in mirror circuit 210 (as described further below) to produce a preselected current level in response to the P_BIAS signal provided from second mirror circuit 210 shown in Fig. 2. Transistor Q3 includes a source coupled to the IOP output port and transistor Q4 includes a source coupled to the ION output port. A drain of transistor Q3 is coupled to a first terminal of a third current source 4003 and a drain of transistor Q4 is coupled to a first terminal of the fourth current source 4004. A second terminal of each of the current sources 4003 and 4004 is coupled to a second reference voltage (e.g., Vdd) . Each current source 4003 and 4004 has a control terminal for receipt of a control signal. Assertion of the control signal to current source 4003 results in activation of current source
4003. Similarly, assertion of the control signal to current source 4004 activates current source 4004.
An output of second NAND gate G23 is coupled to the control terminal of current source 4004 and an output of first NAND gate G22 is coupled to the control terminal of current source 4004. A first input of second NAND gate G23 receives the synchronized control signal while the second input of the second NAND gate G23 receives the enable signal. A first input of first NAND gate G22 is coupled to the output of first inverter G24. The second input of first NAND gate G22 is coupled to the enable signal.
Four impedances (resistors R) are coupled to the output of LSB 300. A first resistor R is coupled between the second voltage reference and IOP, a second resistor R is coupled between the second voltage reference and ION, a third resistor R coupled between IOP and the first voltage reference and a fourth resistor R coupled between ION and the first voltage reference. In the preferred embodiment, resistors R must be very large in relation to a terminating resistor Rτ (shown in Fig. 1) . Resistors R may be integrated into the DAC 100 or provided externally.
In operation, assertion of the N_BIAS mirror current to transistor Ql and to transistor Q2 attempts to establish a scaled current from either IOP or ION to the first voltage reference level, and assertion of the P_BIAS mirror current to transistor Q3 and to transistor Q4 attempts to establish a scaled current from either IOP or ION to the second voltage reference level. Whether one of these currents is established depends upon which, if any, of the control signals are asserted to which of the current sources 400. To turn on first current source 4001, CNTL is deasserted and enable is asserted. To turn on second current source 4002, CNTL is asserted and enable is asserted. To turn on third current source 4003, CNTL is asserted and enable is asserted. To turn on fourth current source 4004, CNTL is deaserted and enable is asserted. Note that deassertion of enable turns off all the current sources 400. Thus, first and third current sources, and second and fourth current sources turn on and off as groups to drive the differential signal as well known. One aspect of the low power mode is that the outputs of IOP and ION sit halfway between the first and second voltage references so that when beginning operation, large currents are not necessary to pull the outputs from one of the voltage reference levels.
Fig. 5 is a schematic diagram of first mirror circuit 205 shown in Fig. 2. Mirror circuit 205 of the preferred embodiment includes a third N-channel MOSFET Q10 coupled in series to a fourth N-channel MOSFET Qll. A drain and gate of MOSFET Q10 is coupled to the n__bias input for receiving the n_bias input signal while a source of MOSFET Q10 is coupled to a drain of MOSFET Qll. A source of MOSFET Qll is coupled to the first voltage reference level. Configuring MOSFET Q10 and MOSFET Qll in this fashion forms one part of the first current mirror. It is one important aspect of the preferred embodiment to closely match transistor Ql and transistor Q2 of each LSB 300 to MOSFET Q3 in order to complete the current mirror. Additionally, it is an important aspect of the preferred embodiment to closely match transistors of the current sources 4001 and 4002 to transistor Qll.
Fig. 6 is a schematic diagram of second mirror circuit 210 shown in Fig. 2. Mirror circuit 210 of the preferred embodiment includes a third p-channel MOSFET Q12 coupled in series to a fourth p-channel MOSFET Q13. A source and gate of MOSFET Q13 is coupled to the p_bias input for receiving the p_bias input signal while a drain of MOSFET Q13 is coupled to a source of MOSFET Q12. A gate of MOSFET Q13 is coupled to the source of MOSFET Q13, while a gate of MOSFET Q12 is coupled to the first voltage reference level. A drain of MOSFET Q12 is coupled to the second voltage reference level. Configuring MOSFET Q12 and MOSFET Q13 in this fashion forms one part of the second current mirror. It is one important aspect of the preferred embodiment to closely match transistor Q3 and transistor Q4 of each LSB 300 to MOSFET Q13 in order to complete the current mirror. Additionally, it is an important aspect of the preferred embodiment to closely match transistors of the current sources 4003 and 4004 to transistor Q12. in conclusion, the present invention provides a simple, efficient solution to a problem of providing a high-speed, low power DAC for use in wave synthesis when communicating over a twisted pair network. While the above is a complete description of the preferred embodiments of the invention, various alternatives, modifications, and equivalents may be used. Therefore, the above description should not be taken as limiting the scope of the invention which is defined by the appended claims.

Claims

WHAT IS CLAIMED IS;
1. A least significant cell for an integrated digital to analog converter for driving an incremental current at each of a first and a second output node, comprising: a first pair of matching MOS transistors including a first and second MOS transistor, each transistor having a first terminal node, a second terminal node and a gate terminal node, said gate terminal nodes receiving a first bias current for controlling an operating current between said first terminal node and second terminal node and wherein said first terminal node of said first MOS transistor is coupled to the first output node and said first terminal node of said second MOS transistor is coupled to the second output node; a first current source having a first current terminal coupled to said second terminal node of said first MOS transistor and a second current terminal coupled to a first voltage reference level, said first current source responsive to a first control signal for switching a first operating current through said first MOS transistor on when said first control signal has a first value and switching said first operating current through said first MOS transistor off when said first control signal has a second value; a second current source having a first current terminal coupled to said second terminal node of said second MOS transistor and a second current terminal coupled to said first voltage reference level, said second current source responsive to a second control signal for switching a second operating current through said second MOS transistor on when said second control signal has a first value and switching said second operating current through said second MOS transistor off when said second control signal has a second value; a second pair of matching MOS transistors including a third and fourth MOS transistor, each of said third and fourth transistors having a first terminal node, a second terminal node and a gate terminal node, said gate terminal nodes of said second pair of transistors receiving a second bias current for controlling an operating current between said first terminal node and second terminal node and wherein said first terminal node of said third MOS transistor is coupled to the first output node and said first terminal node of said fourth MOS transistor is coupled to the second output node; a third current source having a first current terminal coupled to said second terminal node of said third MOS transistor and a second current terminal coupled to a second voltage reference level, said third current source responsive to a third control signal for switching a third operating current through said third MOS transistor on when said third control signal has a first value and switching said third operating current through said third MOS transistor off when said third control signal has a second value; and a fourth current source having a first current terminal coupled to said second terminal node of said fourth MOS transistor and a second current terminal coupled to said second voltage reference level, said fourth current source responsive to a fourth control signal for switching a fourth operating current through said fourth MOS transistor on when said fourth control signal has a first value and switching said fourth operating current through said fourth MOS transistor off when said fourth control signal has a second value.
2. The cell of claim 2 further comprising: a controller, coupled to said current sources and responsive to an enable signal and a bit control signal, which asserts said first, second, third and fourth control signals.
3. The cell of claim 2 wherein said controller disables each current source when said enable signal is deasserted.
4. The cell of claim 3 wherein said controller turns said first and fourth current sources on and said second and said third current sources off when said bit control signal has a first value and said enable signal is asserted, said controller turns said first and fourth current sources off and said second and said third current sources on when said bit 74 control signal has a second value and said enable signal is
75 asserted.
76 5. The cell of claim 4 further comprising:
77 a first impedance coupled between the first output node
78 and said first voltage reference;
79 a second impedance coupled between the first output node
80 and said second voltage reference;
81 a third impedance coupled between the second output
82 node and said first voltage reference; and
83 a fourth impedance coupled between the second output
84 node and said second voltage reference.
85 6. A CMOS digital to analog converter, comprising:
86 a controller for providing a first and a second bit
87 control signal to collectively identify a desired current
88 output level for a complementary output, said controller
89 providing a first and a second bias current signal, an enable
90 signal and a clock signal;
91 a first MOS mirror transistor responsive to said first
92 bias current signal to establish a first mirror current at a
93 first mirror current terminal;
94 a second MOS mirror transistor responsive to said second
95 bias current signal to establish a second mirror current at a
96 second mirror current terminal;
97 a first and a second synchronizer, one for each bit
98 control signal and each responsive to said clock signal, for
99 concurrently asserting, respectively, a first and a second
100 synchronized bit control signal responsive to said respective
101 bit control signal when said clock signal is asserted;
102 a first current cell receiving said first synchronized
103 bit control signal, said enable signal and said mirror
104 currents, said first current cell including a first plurality
105 of least significant current cells each responsive to said
106 first bit control signal and to said mirror currents for
107 generating a first complementary output current on said
108 complementary output when said enable signal is asserted; and 109 a second current cell receiving said second synchronized
110 bit control signal and said mirror currents, said second
111 current cell including a second plurality of least significant
112 current cells each responsive to said second bit control
113 signal and to said mirror currents for generating a second
114 complementary output current on said complementary output when
115 said enable signal is asserted.
116 7. The CMOS digital to analog converter of claim 6
117 wherein each said least significant current cell comprises:
118 a first pair of matching MOS transistors including a
119 first and second MOS transistor, each transistor having a
120 first terminal node, a second terminal node and a gate
121 terminal node, said gate terminal nodes receiving said first
122 mirror current for controlling an operating current between
123 said first terminal node and second terminal node and wherein
124 said first terminal node of said first MOS transistor is
125 coupled to the first output node and said first terminal node
126 of said second MOS transistor is coupled to the second output
127 node;
128 a first current source having a first current terminal
129 coupled to said second terminal node of said first MOS
130 transistor and a second current terminal coupled to a first
131 voltage reference level, said first current source responsive
132 to a first control signal for switching a first operating
133 current through said first MOS transistor on when said first
134 control signal has a first value and switching said first
135 operating current through said first MOS transistor off when
136 said first control signal has a second value;
137 a second current source having a first current terminal
138 coupled to said second terminal node of said second MOS
139 transistor and a second current terminal coupled to said first
140 voltage reference level, said second current source responsive
141 to a second control signal for switching a second operating
142 current through said second MOS transistor on when said second
143 control signal has a first value and switching said second
144 operating current through said second MOS transistor off when
145 said second control signal has a second value; 146 a second pair of matching MOS transistors including a
147 third and fourth MOS transistor, each of said third and fourth
148 transistors having a first terminal node, a second terminal
149 node and a gate terminal node, said gate terminal nodes of
150 said second pair of transistors receiving said second mirror
151 current for controlling an operating current between said
152 first terminal node and second terminal node and wherein said
153 first terminal node of said third MOS transistor is coupled to
154 the first output node and said first terminal node of said
155 fourth MOS transistor is coupled to the second output node;
156 a third current source having a first current terminal
157 coupled to said second terminal node of said third MOS
158 transistor and a second current terminal coupled to a second
159 voltage reference level, said third current source responsive
160 to a third control signal for switching a third operating
161 current through said third MOS transistor on when said third
162 control signal has a first value and switching said third
163 operating current through said third MOS transistor off when
164 said third control signal has a second value; and
165 a fourth current source having a first current terminal
166 coupled to said second terminal node of said fourth MOS
167 transistor and a second current terminal coupled to said
168 second voltage reference level, said fourth current source
169 responsive to a fourth control signal for switching a fourth
170 operating current through said fourth MOS transistor on when
171 said fourth control signal has a first value and switching
172 said fourth operating current through said fourth MOS
173 transistor off when said fourth control signal has a second
174 value.
175 8. The CMOS digital to analog converter of claim 7
176 further comprising:
177 a controller, coupled to said current sources and
178 responsive to said enable signal and said bit control signals,
179 which asserts said first, second, third and fourth control
180 signals. 181 9. The cell of claim 8 wherein said controller disables
182 each current source when said enable signal is deasserted.
183 10. The cell of claim 9 wherein said controller turns
184 said first and fourth current sources on and said second and
185 said third current sources off when said bit control signal
186 has a first value and said enable signal is asserted, said
187 controller turns said first and fourth current sources off and
188 said second and said third current sources on when said bit
189 control signal has a second value and said enable signal is
190 asserted.
191 11. The cell of claim 10 further comprising:
192 • a first impedance coupled between the first output node
193 and said first voltage reference;
194 a second impedance coupled between the first output node
195 and said second voltage reference;
196 a third impedance coupled between the second output node
197 and said first voltage reference; and
198 a fourth impedance coupled between the second output node
199 and said second voltage reference.
200 12. The cell of claim 7 wherein said transistors of said
201 first pair match said first mirror transistor and wherein said
202 transistors of said second pair match said second mirror transistor.
PCT/US1996/002823 1995-06-07 1996-03-01 High speed, low power cmos d/a converter for wave synthesis in network WO1996041421A1 (en)

Priority Applications (3)

Application Number Priority Date Filing Date Title
DE69601268T DE69601268T2 (en) 1995-06-07 1996-03-01 HIGH-SPEED CMOS D / A CONVERTER LOW PERFORMANCE FOR WAVE SYNTHESIS IN A NETWORK
EP96908603A EP0834220B1 (en) 1995-06-07 1996-03-01 High speed, low power cmos d/a converter for wave synthesis in network
JP9500430A JPH11506286A (en) 1995-06-07 1996-03-01 High speed low power CMOS D / A converter for waveform synthesis in networks

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US08/482,113 1995-06-07
US08/482,113 US5600321A (en) 1995-06-07 1995-06-07 High speed, low power CMOS D/A converter for wave synthesis in network

Publications (1)

Publication Number Publication Date
WO1996041421A1 true WO1996041421A1 (en) 1996-12-19

Family

ID=23914726

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/US1996/002823 WO1996041421A1 (en) 1995-06-07 1996-03-01 High speed, low power cmos d/a converter for wave synthesis in network

Country Status (6)

Country Link
US (1) US5600321A (en)
EP (1) EP0834220B1 (en)
JP (1) JPH11506286A (en)
DE (1) DE69601268T2 (en)
TW (1) TW295750B (en)
WO (1) WO1996041421A1 (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2021078367A1 (en) * 2019-10-22 2021-04-29 Huawei Technologies Co., Ltd. High speed digital to analogue converter

Families Citing this family (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6072415A (en) * 1998-10-29 2000-06-06 Neomagic Corp. Multi-mode 8/9-bit DAC with variable input-precision and output range for VGA and NTSC outputs
US6411647B1 (en) * 1998-10-30 2002-06-25 Broadcom Corporation Fully integrated ethernet transmitter architecture with interpolating filtering
US6185263B1 (en) * 1998-11-09 2001-02-06 Broadcom Corporation Adaptively configurable class-A/class-B transmit DAC for transceiver emission and power consumption control
US6925130B2 (en) * 1998-10-30 2005-08-02 Broadcom Corporation Method and system for a reduced emissions direct drive transmitter for unshielded twisted pair (UTP) applications
US6775529B1 (en) 2000-07-31 2004-08-10 Marvell International Ltd. Active resistive summer for a transformer hybrid
US7312739B1 (en) 2000-05-23 2007-12-25 Marvell International Ltd. Communication driver
USRE41831E1 (en) 2000-05-23 2010-10-19 Marvell International Ltd. Class B driver
US7433665B1 (en) 2000-07-31 2008-10-07 Marvell International Ltd. Apparatus and method for converting single-ended signals to a differential signal, and transceiver employing same
US7194037B1 (en) 2000-05-23 2007-03-20 Marvell International Ltd. Active replica transformer hybrid
US7606547B1 (en) * 2000-07-31 2009-10-20 Marvell International Ltd. Active resistance summer for a transformer hybrid
JP3494366B2 (en) * 2000-08-04 2004-02-09 松下電器産業株式会社 DA converter
US6642799B2 (en) * 2000-11-01 2003-11-04 Primarian, Inc. Phase lock loop destress circuit
US7023370B2 (en) * 2002-02-28 2006-04-04 Charles Douglas Murphy Shared parallel digital-to-analog conversion
US6952177B1 (en) * 2004-03-08 2005-10-04 The Boeing Company Traveling wave, multiplying D/A converter
EP1643651B1 (en) * 2004-09-29 2008-03-05 STMicroelectronics S.r.l. Apparatus for the digital to analog conversion of a signal
US7081844B1 (en) * 2005-04-22 2006-07-25 Ess Technology, Inc. Devices and methods for converting a digital signal into an analog signal
US7312662B1 (en) 2005-08-09 2007-12-25 Marvell International Ltd. Cascode gain boosting system and method for a transmitter
US7577892B1 (en) 2005-08-25 2009-08-18 Marvell International Ltd High speed iterative decoder
US7345612B2 (en) * 2006-02-07 2008-03-18 Nokia Corporation Digital-to-radio frequency conversion device, chip set, transmitter, user terminal and data processing method
US10608661B1 (en) * 2019-03-29 2020-03-31 Intel Corporation Digital-to-analog converter

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5148164A (en) * 1990-04-23 1992-09-15 Mitsubishi Denki Kabushiki Kaisha Current generating device for complementarily generating two currents of different magnitudes in response to one-bit data
US5254994A (en) * 1991-03-06 1993-10-19 Kabushiki Kaisha Toshiba Current source cell use in current segment type D and A converter
US5357145A (en) * 1992-12-22 1994-10-18 National Semiconductor Corporation Integrated waveshaping circuit using weighted current summing

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS56153832A (en) * 1980-04-30 1981-11-28 Nec Corp Digital to analog converter
US5276716A (en) * 1990-02-15 1994-01-04 Advanced Micro Devices Inc. Bi-phase decoder phase-lock loop in CMOS
KR930009432B1 (en) * 1991-12-31 1993-10-04 현대전자산업 주식회사 Digital/analog converter current unit
US5446457A (en) * 1994-02-16 1995-08-29 Sgs-Thomson Microelectronics, Inc. Current-summing digital-to-analog converter with binarily weighted current sources

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5148164A (en) * 1990-04-23 1992-09-15 Mitsubishi Denki Kabushiki Kaisha Current generating device for complementarily generating two currents of different magnitudes in response to one-bit data
US5254994A (en) * 1991-03-06 1993-10-19 Kabushiki Kaisha Toshiba Current source cell use in current segment type D and A converter
US5357145A (en) * 1992-12-22 1994-10-18 National Semiconductor Corporation Integrated waveshaping circuit using weighted current summing

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2021078367A1 (en) * 2019-10-22 2021-04-29 Huawei Technologies Co., Ltd. High speed digital to analogue converter

Also Published As

Publication number Publication date
TW295750B (en) 1997-01-11
EP0834220A1 (en) 1998-04-08
JPH11506286A (en) 1999-06-02
US5600321A (en) 1997-02-04
DE69601268T2 (en) 1999-08-12
EP0834220B1 (en) 1998-12-30
DE69601268D1 (en) 1999-02-11

Similar Documents

Publication Publication Date Title
US5600321A (en) High speed, low power CMOS D/A converter for wave synthesis in network
US7176823B2 (en) Gigabit ethernet line driver and hybrid architecture
KR100738961B1 (en) Apparatus for driving output of semiconductor memory
EP0788059B1 (en) Driver circuit device
US7795919B2 (en) Transmitter driver circuit in high-speed serial communications system
US6963218B1 (en) Bi-directional interface and communication link
JPH09130229A (en) Buffer circuit with variable output impedance
WO2002021684A2 (en) Circuit for producing low-voltage differential signals
US5909187A (en) Current steering circuit for a digital-to-analog converter
US6566904B2 (en) Pad calibration circuit with on-chip resistor
US20030198237A1 (en) DAC/driver waveform generator with phase lock rise time control
JPH0653807A (en) Cmos-ecl converter provided with incorporated latch
US6930507B2 (en) Thevenins receiver
US6417790B1 (en) Low-power data serializer
US6069511A (en) Digital slew rate and duty cycle control circuit and method
WO1997029575A1 (en) Differential cmos current amplifier with controlled bandwidth and common mode distortion
US5592166A (en) High speed CMOS D/A converter for wave synthesis in network
US6160436A (en) Driver with switchable gain
US6373276B1 (en) CMOS small signal switchable impedence and voltage adjustable terminator with hysteresis receiver network
US6072413A (en) Current output type digital-to-analog converter capable of suppressing output current fluctuation using a current mirror
US6476642B1 (en) Differential current driver circuit
JP2002057728A (en) Signal transmitter
US6310569B1 (en) Skewless differential switching scheme for current-mode digital-to-analog converters
US6377079B1 (en) Data serializer with slew-rate control
US10771077B1 (en) Hybrid return-to-zero voltage-mode DAC driver

Legal Events

Date Code Title Description
AK Designated states

Kind code of ref document: A1

Designated state(s): JP KR

AL Designated countries for regional patents

Kind code of ref document: A1

Designated state(s): AT BE CH DE DK ES FI FR GB GR IE IT LU MC NL PT SE

DFPE Request for preliminary examination filed prior to expiration of 19th month from priority date (pct application filed before 20040101)
121 Ep: the epo has been informed by wipo that ep was designated in this application
WWE Wipo information: entry into national phase

Ref document number: 1996908603

Country of ref document: EP

ENP Entry into the national phase

Ref country code: JP

Ref document number: 1997 500430

Kind code of ref document: A

Format of ref document f/p: F

WWP Wipo information: published in national office

Ref document number: 1996908603

Country of ref document: EP

WWG Wipo information: grant in national office

Ref document number: 1996908603

Country of ref document: EP