WO2013124508A1

WO2013124508A1 - Electronic circuit with an electrical output magnitude dependent on the voltage difference between two input nodes and on the temperature difference between two of the devices thereof

Info

Publication number: WO2013124508A1
Application number: PCT/ES2013/070096
Authority: WO
Inventors: Josep Altet Sanahujes; Dídac GÓMEZ SALINAS; Diego Mateo Peña
Original assignee: Universitat Politècnica De Catalunya
Priority date: 2012-02-23
Filing date: 2013-02-18
Publication date: 2013-08-29
Also published as: ES2429877B1; ES2429877A1

Abstract

The present invention describes an electronic circuit, the electrical output magnitude of which depends on the voltage difference between two of the input nodes of said circuit as well as on the temperature difference between two of the internal devices thereof. Figure 1 shows the symbol of the electronic circuit. Said circuit has two voltage inputs (2) and (3) and two power supply inputs (6) and (7) as electrical inputs and has one node (1) as an output. In addition, said circuit has two internal devices (4) and (5), the temperature difference between which will directly influence the value of the electrical magnitude of the output node. In the circuit of the present invention, the variation in the electrical magnitude of the output (1) depends on the voltage difference between the two input nodes (2) and (3) as well as on the temperature difference between the internal devices (4) and (5).

Description

ELECTRONIC CIRCUIT WITH ELECTRICAL MAGNITUDE OF DEPENDENT OUTPUT OF THE DIFFERENCE OF VOLTAGE OF TWO INPUT NODES AND OF THE TEMPERATURE DIFFERENCE OF TWO OF ITS

DISPOSITIVES

Technical sector:

The present invention relates to an electronic circuit with electrical output magnitude dependent on the voltage difference of two input nodes and the temperature difference of two of its devices. The sector of the technique to which it refers is that of electronic instrumentation for measuring temperature in integrated circuits.

State of the art:

In the field of electronic instrumentation technique there are, on the one hand, electronic circuits in which the electrical magnitude of its main output depends on the difference in electrical quantities of two input nodes. These amplifiers are called differential amplifiers, the operational example being the paradigmatic example. Several examples of these circuits can be found in the book [1]. On the other hand, there are the so-called differential temperature sensors [2]. They are circuits with applications for temperature measurements in integrated circuits. Its operation is that the output voltage (or current) has a variation that is proportional to the temperature difference of two devices, called temperature transducers. These sensors are normally used in test applications and characterization of integrated circuits, such as those described by patents [3], [4], since the operation of a certain electronic circuit causes a power dissipation and this in turn a variation of temperature in its vicinity. Therefore, a temperature measurement near this circuit can provide information about possible anomalies and its characteristics. Compared to the classic methods of checking integrated circuits based on the measurement of electrical quantities, the use of temperature as observable has the main advantage that the circuit under measure is not electrically charged, which is critical for high frequency circuits .

[1] Phillip E. Alien and Douglas R. Holberg, "CMOS Analog Circuit Design", Oxford University Press, 2002, 2nd Ed. [2] Eduardo Aldrete-Glass, Diego Mateo and Josep Altet, "Differential Temperature Sensors Fully Compatible With at 0.35-μηι CMOS Process ", IEEE TRANSACTIONS ON COMPONENTS AND PACKAGING TECHNOLOGIES, VOL. 30, NO. 4, DECEMBER 2007. [3] Patent number 2294888. Procedure for determining the electrical characteristics of integrated analog circuits.

[4] Patent number 2332688. Heterodyne procedure for temperature measurements.

[5] P.R. Gray, D.J. Hamilton and D. Lieux, "Analysis and design of temperature stabilized substrate integrated circuits," Solid-State Circuits, IEEE Journal of, vol.9, no.2, pp. 61-69, Apr 1974.

Explanation of the invention:

Differential temperature sensors are used to measure the temperature variations caused by the operation of a circuit, and from these measurements, extract electrical characteristics of the circuit. These sensors have the advantage of having a high sensitivity to temperature variations caused by power dissipation by circuits located in the same semiconductor crystal as the sensor, and very little sensitivity to temperature variations that affects both temperature transducers, such as variations in ambient temperature. The state of the art of the differential temperature sensors shows architectures based on differential amplifiers (for example, two bipolar coupled by emitter). Being a circuit with a temperature input and a voltage (or current) output, it is not possible to simply perform a negative feedback between the output and the input that allows reducing the sensitivity to process variations, controlling the sensitivity of the sensor , vary the dynamic range or cancel offset voltages. In differential temperature sensors, the voltage (or current) of the output node must follow the following equation:

Where

depending on the case) is the variation of the electrical magnitude of the sensor output, and G _T is the differential temperature gain of the sensor in V / ° C (ol / ° C, as the case may be), also called sensitivity. In the rest of the present invention, and without subtracting it in general, the voltage option will be used for the output when making the explanations.

The present invention describes a circuit in which the electrical output magnitude depends on both the voltage difference of two of its inputs and the temperature difference of two of its internal electronic devices. Thus, if we apply to the node (2) of Figure 1 a voltage referred to the reference node of value V + and node (3) of value V., if the internal devices (4) and (5) meet at an absolute temperature T + and T. respectively, and assuming a voltage mode output of the V _out value circuit, the mathematical expression of a circuit that behaves as described in the present invention is:

Where G _v is the differential voltage gain, G _T the differential temperature gain, and V _D c_out is the voltage at the output node when there is no differential voltage at the input and the temperatures of the two devices are the same. Another way of writing the same expression is by looking only at the variation of the output voltage with respect to the rest voltage,

In general, the terms of gain Gv and GT may be non-constant and depend on the input voltages and the absolute temperatures of the two sensor devices. For simplicity of explanation, and without limiting the scope of the invention, the rest of the patent will be considered to be constant. A circuit of these characteristics allows, on the one hand, to perform a differential temperature sensing, and on the other, to immediately establish a feedback between the sensor output and the voltage inputs, since all these nodes belong to the domain of electrical signals .

Description of the drawings

Figure 1 shows an electronic circuit with two supply nodes (6) and (7), an electronic output (1) in voltage or current mode, two electronic inputs in voltage or current mode, one inverter (2) and one non-inverter (3), and two internal devices (4) and (5) whose temperature difference (T ₍₄₎ -T ₍₅₎ = T + -T. = ΔΤ) directly intervenes in the value of the output (1) .

Figure 2 shows a possible transistor level implementation of the circuit of Figure 1. The indications (1) to (7) of figure 2 correspond to those of figure 1: the two supply nodes (6) and (7), the output (1) (in this case in voltage mode and also indicated with V _ou t), the electronic inputs in voltage mode (2) (inverter, also indicated with voltage V.) and (3) (non-inverter, indicated with the voltage V ₊ ), and the temperature sensing devices which in this implementation are the bipolar transistors Qi and Q ₂ (corresponding to (4) and (5) in Figure 1 and marked as such in Figure 2), connected as differential torque mode. The dotted square on the left (8) frames what is a possible implementation of a classic differential temperature sensor, where in addition to the thermal differential pair formed by Q1 and Q2 there are transistors M3 to M8, which perform functions of active loads and power mirrors The dotted square on the right (9) frames a classic electric differential pair formed by transistors M1 and M2, which is located in the implementation of the circuit of the present invention in a parallel connection to the thermal differential pair.

Figure 3 shows the same circuit as in Figure 1, but in negative electrical-electric feedback configuration, that is, connecting the electrical output node (1) to the inverting electrical input (2). This connection is made in the figure through a network that provides a generic gain of value b.

Figure 4 shows a block diagram of the internal circuit structure of the present invention. The block (1) corresponds to a voltage difference transconductor (V + - V.) unlike current (lv_a-lv _ _b ). Block (2) corresponds to a temperature difference transconductor of two internal devices (4) and (5), (T + - T.), unlike current (Ιτ_ ₉ -Ιτ __>) - And block (3) corresponds to an amplifier that converts the sum of both differences from current to voltage (or current, as the case may be) monopolar to the output. If the output is in voltage, said block (3) is usually called transimpedance amplifier.

Description of preferred applications

The first preferred application is shown in Figure 2. It is a possible implementation of the circuit proposed in the present invention. The devices the temperature difference of which directly affects the output of the circuit are the bipolar transistors Qi (4) and Q ₂ (5), while the voltage inputs are those indicated as V ₊ (3) and V. (2), and the output is the voltage corresponding to the node marked V _out (1).

This circuit consists of a thermal part and an electrical part in parallel. The thermal part is formed by two temperature transducers (4) and (5) coupled by emitter. If the temperature of the two devices is the same, both will have the same collector current being equal to half of the current supplied by the source l _bias1. In case one of the two temperature transducers is at a temperature higher than the other, the symmetry condition disappears and the currents flowing through the differential pair will be different. In applications where the temperature has small variations with respect to equilibrium, the difference in current can be approximated by the two bipolar collectors such as:

where S is the gain or sensitivity of the current by the bipolar collectors at temperature variations. The transistors M3, M4, M5, M6, M7 and M8 form a classic transimpedance amplifier, converting the differential current of the differential torque (due in turn to temperature differences between Q ₁ and Q ₂ ), in voltage variations a the output with respect to the resting voltage of said node V _out (1). The conversion ratio, which has resistance units, is usually called transimpedance and is assigned the expression K. Its value will generally depend on the aspect ratios of the current mirrors and the technological constants of the transistors. Voltage variations at the sensor output can be expressed as

where is the difference in current between the two branches,

). Considering only the thermal differential torque, the voltage variations at the sensor output can be expressed:

In parallel with the thermal differential pair, the sensor also has an electrical differential pair formed by transistors M1 and M2 (and its current source I _bias2 ). If we now consider only the transistors of the electrical differential pair M1 - M2, the resulting circuit is a classic implementation of a voltage differential amplifier, whose output admits an expression:

where G is the current gain of the electrical differential torque.

The core of the circuit of the present invention is the parallel of the two differential pairs, the thermal and the electric. When working the output of said differential pairs in current, its parallel connection allows to add the currents directly, so that the expression of the output is given by:

In this way, variations in the circuit's output voltage depend on the difference in voltage at the input and the temperature difference between the two internal transconducting devices of the circuit.

As a second preferred application, the one in Figure 3 is shown. In it, a feedback has been made of the output V _out to the inverting input V. with a feedback gain b, and a constant voltage source of value V _re f has been placed in the inverting voltage input. In such a configuration it is obtained that the output of the circuit V _ou t is given by the expression:

Where, finally:

In the case of a classic differential temperature sensor, G _v = 0, so that the expression for a classic differential temperature sensor is:

The classic differential temperature sensors are mainly based on an open loop transconductance amplifier, which has the disadvantage of a great dependence on the process variations, both the so-called inter-die or dry process variations, as the intra-die or disappearance -mismatching-, and even with temperature variations. This dependence is basically given because process or temperature variations can vary considerably V _D c_out (which is ideally located by design at a certain point, optimal when it comes to sensor performance) and therefore remove the sensor from its ideal work point, thus affecting its benefits.

The classic solution of using feedback to compensate for the effects of process or temperature variations is easily implemented in the case of differential voltage amplifiers, but not in the case of differential temperature sensors, as the temperature sensor is a amplifier transconductor that passes from the thermal to the electrical domain, that is, that the feedback should act by passing from the electrical to the thermal domain, thus acting on the temperature of the sensor temperature transconducting devices increasing or decreasing their temperature as indicated by the loop. Said temperature control is very complex and expensive to implement [5].

In the case of the circuit presented in the present invention, the necessary feedback to minimize the effects of process or temperature variations on the circuit's performance is of immediate implementation, having a mixed behavior and use, differential temperature sensor - differential amplifier tensile. Taking the equation corresponding to a feedback with gain b for the circuit of the present invention:

it is observed that by controlling the reference voltage V _re f, the feedback parameter b, and the voltage gain Gv, it is possible to control the effect of variations of V _D c_out on the circuit performance when it is operating as a sensor temperature differential

The third preferred application is shown in Figure 4. It is an electronic circuit comprising a block or subcircuit (1) whose current difference at its output is proportional to the temperature difference between two internal devices with dependency ratio S, in parallel with another block or subcircuit (2) whose current difference at its output is proportional to the voltage difference of two input nodes, with dependency ratio G. Said parallel connection is in turn the input of a block (3) which converts the sum of both current differences into a monopolar electrical value, either voltage (as is the case in Figure 4), or current, with dependency ratio K. Thus, the mathematical expression of the circuit's operation can be:

Claims

Claims:

1.- An electronic circuit characterized by the variation in its electrical output magnitude (which can be voltage)

depend on the temperature difference of two of your internal devices of

the voltage difference of two of its input nodes following

the behavior indicated by the expression:

Gv being the gain in circuit voltage and GT the gain in temperature or circuit sensitivity.

2. An electronic circuit according to claim 1 characterized by the parallel connection of two vessels or subcircuits: a first block or subcircuit with two output branches whose current difference at its output is proportional to the

temperature difference between two internal devices

with dependence relation S, and a second block or subcircuit with two voltage inputs and two output branches whose current difference at its output is proportional

at the voltage difference of its two input nodes with dependence relation G. This parallel connection makes the sum of both current differences, and is in turn the input of a block or subcircuit with

two input branches and an output node that converts the sum of both current differences into a monopolar electrical value, either voltage, or current, with dependency ratio K. Thus, the mathematical expression of the circuit's operation can be obtained:

where G _T is the gain in temperature or sensitivity and G _v the gain in tension, expression coincident with that given in claim 1.