The present invention relates to differential amplifiers, and more particularly, to a differential amplifier with a network for limiting output voltages.
An architecture of a differential amplifier commonly used in modern electronic circuits is the so-called open collector architecture. In particular, the open collector architecture is used when an amplifier is required to exchange current with external components. In this situation, the collectors of the differential pair of transistors are coupled to connection pins. The amplifier is supplied by connecting these pins to a DC line through external components.
A typical connection scheme of an open collector differential pair of transistors Q1, Q2 to a supply line by external inductive loads L1, L2 is depicted in
In the shown example, the AC components of the voltages on the output nodes C1 and C2 are floating, and also depend on the signals applied on the control nodes of the transistors of the differential pair Q1, Q2. This is while the respective DC components are set by the value of the supply voltage VDD.
In these amplifiers it may happen that the voltages on the nodes C1, C2 reach values larger than those established by the technology used. This is due to the spurious common mode, or differential voltages due to inductive loads connected to the nodes C1, C2 and the supply line VDD.
In particular, when the differential amplifier is turned on or off, there are spurious voltage peaks of equal amplitude. The voltage peaks are in phase between them (common mode) on both nodes C1, C2 due to the rapid variations of the current flowing in the inductances L1, L2 superposed to the output voltages, thus raising their level.
To address this problem, several architectures of open collector differential pairs having networks for limiting the output voltage are known. A first example is shown in
VDD+N*VT
the N diodes D1, . . . , Dn are turned on and limit the maximum voltage on the nodes C1 and C2. This approach effectively limits the voltages on the output nodes both in presence of spurious common mode and differential over voltages.
A drawback of this architecture is that the series of diodes do not turn on instantaneously, but gradually enter in a conduction state. Thus, they distort the output signal when its amplitude is smaller than the threshold value N*VT. Using this limitation network causes a relevant harmonic distortion.
Another architecture is shown in
The effect of the protection network shown in
An object of the invention is to provide a differential amplifier that addresses the above mentioned problems by using a network for limiting the output common mode voltage. The network is to connect the output nodes to the supply voltage through respective low impedance paths when the output voltage exceeds a pre-established maximum value.
More precisely, the differential amplifier comprises a differential pair of transistors the current nodes of which, forming respective output nodes of the amplifier, are connected to a supply line through respective inductive loads. A network for limiting output voltages comprising a pair of low impedance paths. Each path connects a respective output node to the supply line, and has an analog switch turned on when a certain voltage threshold is surpassed.
The limiting network does not intervene during the normal functioning of the amplifier but limits the common mode voltage because it comprises a pair of identical resistors connected in series between the output nodes of the amplifier. Also, because both analog switches are turned on when the voltage on the intermediate common node of the identical resistances in series overcomes the pre-established thresholds.
The various aspects and advantages on the invention will be even more evident through a detailed description referring to the attached drawings, wherein:
a and 8b are graphs of the output voltages during a normal functioning phase of the amplifier of the invention.
A basic diagram of the differential amplifier of the invention is depicted in
The voltage on the common node CM of the two identical resistors RP1 is the output common mode voltage. When there is not any spurious common mode over voltage, it coincides with the supply voltage VDD.
A pair of analog switches are connected between the output nodes of the amplifier and the supply line and are turned on by a control voltage equal to the difference between the voltage on the node CM and the voltage VDD. When this difference exceeds a threshold value, the analog switches are in a conduction state and connect the nodes C1, C2 to the supply line VDD through low impedance paths, as long as the difference between the voltage on the node CM and supply voltage does not diminish below the threshold.
Should differential spurious voltages be present, the voltage on the node CM remains unchanged and the limiting network does not intervene. To regulate the activation threshold of the protection network from common mode over voltages, a resistor RP2 is connected between the common node CM and the supply line to form with the resistor RP1 a pair of resistive voltage dividers between the nodes C1, C2 and the supply VDD.
The limiting network of the amplifier of the invention may also be formed using bipolar transistors, as depicted in
In the shown examples the differential amplifier is formed by a differential pair of bipolar transistors Q1, Q2, but it is possible to use MOSFETs or even Darlington transistors.
VDD=5V; RP1=50 kΩ; RP2=15 kΩ; L1=L2=100 μH.
Without the limiting network the oscillations of the voltage VC1 are not dampened rapidly (the chosen time scale does not allow the dampening to be illustrated), while with the limiting network the oscillations are immediately limited to the maximum value of 7V from the turning on of the transistors QP1, QP2. The exponential dampening is determined by the circuit R-L composed of inductive loads L1, L2 and by the load resistance (not depicted in figure) connected between the output nodes C1, C2.
a and 8b depict graphs of the voltages VC1, VC2 on the output nodes C1 and C2 after an input sine differential signal at a frequency of 10 MHz, with and without the limiting network, respectively. The limiting network practically does not influence the response of the amplifier during its normal functioning because the limiting circuit is not sensitive to differential signals.
Number | Date | Country | Kind |
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VA2003A0034 | Sep 2003 | IT | national |
Number | Name | Date | Kind |
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4904953 | McCormack | Feb 1990 | A |
5221909 | Cole | Jun 1993 | A |
Number | Date | Country | |
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20050104660 A1 | May 2005 | US |