EP4295485A1 - Level converter - Google Patents

Abstract

The invention relates to a level converter (L) for adjusting a first reference potential (P1) and/or a first communication voltage (K1) of a first component (E1) to a second reference potential (P2) and/or a second communication voltage (K2) of a second component (E2), wherein the level converter (L) is arranged between the first component (E1) and the second component (E2), wherein the level converter (L) has a first transistor (T1) with a downstream first resistor (R1), wherein the level converter (L) is configured in such a way that the second reference potential (P2) drops at the first resistor (R1) in a blocked state of the first transistor (T1) and that the second communication voltage (K2) drops at the first resistor (R1) in an open state of the first transistor (T1).

Description

level converter

The invention relates to a level converter for adapting a first reference potential and/or a first communication voltage of a first component to a second reference potential and/or a second communication voltage of a second component, the level converter being arranged between the first component and the second component.

In automation technology, in particular in process automation technology, field devices are often used which are used to record and/or influence process variables. Sensors, such as level meters, flow meters, pressure and temperature meters, pH and redox potential meters, conductivity meters, etc., are used to record process variables, which record the corresponding process variables level, flow rate, pressure, temperature, pH value or conductivity. Actuators such as valves or pumps, which can be used to change the flow of a liquid in a pipeline section or the fill level in a container, are used to influence process variables. In principle, all devices that are used close to the process and that supply or process process-relevant information are referred to as field devices. In connection with the invention, field devices are also understood to mean, in particular, remote I/Os, radio adapters or devices in general that are arranged at the field level.

Field devices are usually connected to a higher-level unit, such as a control unit or a control system, via a two-wire line, ie a line with two separately formed wires. The measured values of the sensors or the control values of the actuators are communicated analogously as a 4-20 mA current signal to the higher-level unit. The field devices can also be supplied with energy via the two-wire line, but the energy available this way is quite limited. If a field device requires more energy than can be provided via the two-wire line, three- or four-wire lines are used, for example. In addition to this analogue connection of the field device via the two-wire line, new and digital transmission and communication systems are playing an increasing role. One of these systems is IO-Link. IO-Link represents an IEC 61131-9 standard published with the issue date September 2013 under the name "Single-drop digital communication interface for small sensors and actuators" (SDCI) standardized communication system for connecting intelligent sensors and actuators. There are often several in the field devices Operating states are available: analog 4-20 mA operation, IO-Link operation and, if necessary, other operating states. One possibility of embedding these different operating states in a uniform electronic system is disclosed, for example, in DE 102019 116 193 A1.

If individual components of such a circuit are at a common reference potential and use the same communication voltage, direct communication between the components, e.g. for data exchange, is possible without any problems. If this is not the case, level converters are used between the components, which adapt the reference potential of one component to that of the other component. For example, microprocessors often have the ground (GND, 0 V) as a reference potential and 3.3 V as the communication voltage. An IO device, on the other hand, typically has the so-called IOL ground (IOL-GND, -10...0 V) as the reference potential and IOL-GND + 3V as the communication voltage. Previous level converters often represent inductive and galvanically isolated transmission components, which are relatively expensive and require a comparatively large amount of space in the circuit. So-called level shifters, on the other hand, only convert the communication voltage from one value to another and can only be used if the components have an identical reference potential.

The problem to be solved by the present invention is therefore to specify a level converter which, in a simple manner, enables a communication voltage to be converted even if the reference potentials of the components are different. The object is achieved according to the invention by a level converter for adapting a first reference potential and/or a first communication voltage of a first component to a second reference potential and/or a second communication voltage of a second component, the level converter being arranged between the first component and the second component, wherein the level converter has a first transistor with a downstream first resistor, wherein the level converter is designed such that the second reference potential drops across the first resistor when the first transistor is in a blocked state, and the second reference potential drops across the first resistor when the first transistor is open communication voltage drops.

The level converter according to the invention is able to convert both a communication voltage and a reference potential from the first component to the second component. This is achieved primarily via the first transistor, whose state, open or closed, decides what voltage is obtained at the output of the level shifter. A great advantage of the level converter according to the invention is its simple construction. In particular, no inductive or galvanic separations are necessary, only standardized components such as a transistor and a resistor are required.

Since the second reference potential is maintained when the first transistor is blocked and the second communication voltage is maintained when it is open, two levels are passed on to the second component as upper and lower limits or as high and low levels or as 0 and 1. so that communication between the two components is made possible. As part of a field device, the level converter according to the invention can be used, for example, between a microprocessor and an IO-Link in order to coordinate their different reference potentials, GND or IOL-GND, and their different communication voltages. The first transistor is preferably a bipolar pnp transistor or a field effect transistor.

In one possible configuration, the first resistor is arranged between the first transistor and the second reference potential. In this way, when the first transistor is in the off state, the second reference potential will always drop across the first resistor and will thus be provided at the output of the level converter. As is known to those skilled in the art, smaller leakage currents can occur at the first transistor, so that the voltage at the output of the level converter can deviate slightly from the second reference potential.

In a further possible configuration, the first transistor has a first input and a first output, with a current flowing through the first input and the first output when the first transistor is open, with the first output being connected to the second reference potential, with the first input is connected to a first voltage source, the first voltage source outputting a voltage which is identical to the second communication voltage or is a voltage which is higher than the second reference potential, so that when the first transistor is open, the second communication voltage is present at the first resistance drops. When the first transistor opens, the second communication voltage should drop at the output of the level converter. If the second reference potential is GND, for example, ie 0 V, the first voltage source outputs the second communication voltage, for example 3.3 V, since the second communication voltage is thus obtained at the output of the level converter. It should be noted that transistors typically have a saturation voltage, which can lead to small deviations in the second communication voltage. In the case that the second reference potential is -10 V, for example, the first voltage source should output a voltage of 3 V in order to obtain 3 V as the second communication voltage. The open or the blocked state of the first transistor can advantageously be set by means of a first control connection of the first transistor. As is known from the prior art, transistors have an input, an output and a control connection. The state of the transistor can be set with the latter. As a rule, the transistor is opened as soon as a defined voltage is provided at the control connection, this defined voltage is typically around 0.7 V. When the transistor is open, a current flows through the input into the output of the transistor. If the voltage at the control connection falls below the defined level, the transistor remains blocked. These basic considerations apply to both the first transistor and the second transistor.

In one possible configuration, the first input is connected to the first control connection via a fourth resistor, with a fifth resistor being connected to the first control side in parallel with the fourth resistor. One possibility for controlling the first transistor using the first control connection is to integrate a fourth and a fifth resistor in the level converter. If the first transistor is a pnp transistor, for example, then a voltage of approximately 0.7 V must be able to emerge from the first control connection so that the first transistor is opened. By connecting the first control terminal to the first input, the pnp transistor is only opened when the difference between the potential at the first input and the potential at the fourth resistor is greater than approximately 0.7V.

In an alternative configuration, the first control connection is connected to a second transistor, the second transistor being configured such that when the second transistor is in the open state, the first transistor is open and when the second transistor is in the blocked state, the first transistor is blocked. Instead of using resistors, an additional, second transistor can be used to control the first transistor. The second transistor can be part of an open collector or push/pull output of a component, such as an IO device. A further embodiment provides that the first reference potential is connected to a second output of the second transistor, a second voltage source being connected to the second input of the second transistor, the second voltage source outputting a voltage which is higher than that of the first reference potential, wherein the first transistor is connected between the second voltage source and the second input of the second transistor, wherein a second resistor and a third resistor are respectively provided between the first transistor and the second voltage source and between the first transistor and the second input of the second transistor. Depending on the first reference potential, the second voltage source must output such a voltage that when the second transistor opens, such a voltage drops at the first control terminal of the first transistor that the first transistor is also opened.

The present invention will be explained in more detail below with reference to FIGS. 1-3. They show:

1: a diagram of the integration of the level converter according to the invention in a circuit.

2: a first embodiment of the level converter according to the invention.

3: a second embodiment of the level converter according to the invention.

The level converter according to the invention can be used in particular in field devices of all types in which a conversion of the different reference potentials and/or different communication voltages of two components is required.

1 shows a schematic of the level converter L according to the invention, which is arranged between a first component E1 and a second component E2. The first and the second component E1,E2 each have different first and second reference potentials P1,P2 and first and second communication voltages K1,K2. The level converter L is used according to the invention for adapting the first reference potential P1 and/or the first communication voltage K1 of the first component E1 to the second reference potential P2 and/or the second communication voltage K2 of the second component E2. Without the level converter L connected between the two components E1, E2, communication between the two components E1, E2 would not be possible. In order to enable communication in both directions, two level converters L are required, which translate in opposite directions. The first component is a microprocessor, for example, which requires a first reference potential of 0 V or GND and a communication voltage of 3 V, while the second component, an IO device, requires a second reference potential of -10...0 V or IOL_GND and requires a second communication voltage of IOL-GND + 3V for communication.

2 shows a first possible embodiment of the level converter L according to the invention. The level converter L has an input in and an output out, via which the level converter L is connected to the first and the second component E1, E2, and a first transistor T1 with a downstream resistor R1. The first transistor has a first input G1, a first output A1 and a first control connection B1. When the first transistor T1 is open, a current flows through the first input G1 and the first output A1.

The level converter L is designed to receive the second reference potential P2 at the first resistor R1 when the first transistor T1 is in a blocked state and to receive the second communication voltage K2 when the first transistor T1 is open. The first transistor T1 is, for example, a bipolar pnp transistor, although a field effect transistor can also be used. The first resistor R1 is arranged, for example, between the first output A1 of the first transistor T1 and the second reference potential P2. As a result of this arrangement, when the transistor T1 is in the off state, the second reference potential P2 drops across the first resistor R1.

In order for the second communication voltage K2 to drop across the first resistor R1 when the first transistor T1 is open, the first input is G1 of the first transistor T1 is connected to a first voltage source V1, for example. The first voltage source V1 is used to output a voltage which is either identical to the second communication voltage K2 or is a voltage which is so higher than the second reference potential P2 that when the first transistor T1 is open, the second communication voltage K2 is present at the first resistor R1 is obtained. In particular, when the second reference potential P2 corresponds to GND, the first voltage source V1 can be set to the second communication voltage K2.

The setting of the state of the first transistor T1 or the opening and blocking of the first transistor T1 takes place, for example, via the first control connection B1. One possibility for controlling the first transistor T1 is to connect a second transistor T2 to the first control connection.

The first transistor T1 then assumes that state which is specified by the second transistor T2, so that both transistors T1, T2 are either open or blocked at the same time.

The second transistor T2 in turn has a second input G2, a second output A2 and a second control connection B2. For example, the first reference potential P1 is connected to the second output A2 and a second voltage source V2 is connected to the second input G2. To open the first transistor, the second voltage source V2 must output a voltage that is higher than that of the first reference potential P1. The voltage output at the second voltage source V2 must, for example, be at least as much greater than the first reference potential P1 as the base current that is required to open the first transistor T1 at the first control connection B1. The first transistor T1 lies between the second voltage source V2 and the second input G2. In addition, two further resistors R2, R3 are provided. The second resistor R2 is located between the first transistor T1 and the second voltage source V2. The third resistor R3 is arranged between the first transistor T2 and the second input G2. The second transistor T2 is controlled by the second control connection B2, to which at least the first reference potential P1 is received, for example. In this case, the second transistor would be blocked, since the first reference potential is also present at the second output A2. The second transistor T2 opens when a voltage is present at the second control connection B2 which is at least as great as the sum of the first reference potential P1 and the minimum voltage required to switch the second transistor T2.

3 shows a second embodiment of the level converter according to the invention. In this case, no second transistor T2 is used to control the first transistor T1, but rather a combination of resistors. The fourth resistor R4 provides a connection between the first voltage source V1 and the first control terminal B1.

A fifth resistor R5 is connected in parallel with the fourth resistor R4 between the input in of the level converter and the first control connection. The voltage entering the level converter drops across the fifth resistor R5, while the voltage of the first voltage source V1 drops across the fourth resistor R4. The first transistor T1 is opened only when a voltage drop at the node between the fourth resistor R4 and the fifth resistor R5 corresponds at most to the difference between the voltage of the first voltage source V1 and the base current of the first transistor T1. For example, the first voltage source outputs 3.3V. If there are also 3.3 V at the input of the level converter L, the first transistor T1 is blocked. As soon as a voltage below 2.6 V is present at the input of the level converter L, the first transistor T1 is opened, since the base voltage of the first transistor T1 is approximately 0.7 V. Reference List

L level converter

E1 first component

E2 second component

P1 first reference potential

P2 second reference potential

K1 first communication voltage

K2 second communication voltage

V1 first voltage source

V2 second voltage source

T1 first transistor

G1 first input of the first transistor

A1 first output of the first transistor

B1 first control connection of the first transistor

T2 second transistor

G2 second input of the second transistor

A2 second output of the second transistor

B2 second control connection of the second transistor

R1 first resistor

R2 second resistor

R3 third resistor

R4 fourth resistor

R5 fifth resistor in input signal of the level converter out output signal of the level converter

Claims

patent claims

1 . Level converter (L) for adapting a first reference potential (P1) and/or a first communication voltage (K1) of a first component (E1) to a second reference potential (P2) and/or a second communication voltage (K2) of a second component (E2), wherein the level converter (L) is arranged between the first component (E1) and the second component (E2), wherein the level converter (L) has a first transistor (T1) with a downstream first resistor (R1), wherein the level converter (L ) is designed in such a way that when the first transistor (T1) is in a locked state, the second reference potential (P2) drops across the first resistor (R1), and that when the first transistor (T1) is open, the second reference potential drops across the first resistor (R1). Communication voltage (K2) drops.

2. Level converter according to claim 1, wherein the first transistor (T1) is a bipolar pnp transistor or a field effect transistor.

3. Level converter according to at least one of the preceding claims, wherein the first resistor (R1) is arranged between the first transistor (T1) and the second reference potential (P2).

4. Level converter according to at least one of the preceding claims, wherein the first transistor (T1) has a first input (G1) and a first output (A1), wherein in the open state of the first transistor (T1) a current flows through the first input (G1 ) and the first output (A1 ), the first output (A1 ) being connected to the second reference potential (P2), the first input (G1 ) being connected to a first voltage source (V1 ), the first voltage source (V1 ) outputs a voltage that is identical to the second communication voltage (K2) or is a voltage that is higher than the second reference potential (P2), so that im open state of the first transistor (T1), the second communication voltage (K2) at the first resistor (R1) drops.

5. Level converter according to at least one of the preceding claims, wherein the open or the blocked state of the first transistor (T1) can be set by means of a first control connection (B1) of the first transistor (T1).

6. Level converter according to claim 5, wherein the first control connection (B1) is connected to a second transistor (T2), the second transistor (T2) being designed such that when the second transistor (T2) is in an open state, the first transistor ( T1) is open and that when the second transistor (T2) is in a blocked state, the first transistor (T1) is blocked.

7. Level converter according to claim 6, wherein the first reference potential (P1) is connected to a second output (A2) of the second transistor (T2), a second voltage source (V2) being connected to the second input (G2) of the second transistor (T2). is, wherein the second voltage source (V2) outputs a voltage which is higher than that of the first reference potential (P1), wherein the first transistor (T 1) between the second voltage source (V2) and the second input (G2) of the second Transistor (T2) is connected, with a second resistor (R2) and a third resistor (R3) between the first transistor (T1) and the second voltage source (V2) and between the first transistor (T1) and the second input (G2 ) of the second transistor (T2) is provided.

8. Level converter according to claim 5, wherein the first input (G1) is connected to the first control terminal (B1) via a fourth resistor (R4), with a fifth Resistor (R5) is connected in parallel with the fourth resistor (R5) to the first control side (B1).