Method and device for monitoring a converter

What is claimed is: 1. A converter, including: a converter circuit situated between a first network and a second network and for converting one of a direct voltage and an alternating voltage at an input terminal at an input side into one of a direct voltage and an alternating voltage at an output terminal at an output side, the one of the direct voltage and the alternating voltage at the input side and the one of the direct voltage and the alternating voltage at the output side each being based on a shared potential; a first monitoring circuit situated between the input terminal and the converter circuit and configured to detect a current flow into the converter circuit at the input terminal when the converter circuit is deactivated; a second monitoring circuit situated between the output terminal and the converter circuit and configured to detect a current flow into the converter circuit at the output terminal when the converter circuit is deactivated; and at least one of: a first separation element situated between the input terminal and the converter circuit and for establishing a connection between the input terminal and the converter circuit as a function of the current flow detected by the first monitoring circuit, and a second separation element situated between the output terminal and the converter circuit and for establishing a connection between the output terminal and the converter circuit as a function of the current flow detected by the second monitoring circuit. 2. The converter as recited in claim 1 , wherein the converter is a DC/DC converter for use in a motor vehicle. 3. The converter as recited in claim 1 , further comprising: a control unit for suppressing an activation of the converter as a function of the current flow detected in at least one of the first monitoring circuit and the second monitoring circuit. 4. The converter as recited in claim 1 , wherein at least one of: the first monitoring circuit and the first separation element are connected in parallel with one another, and the second monitoring circuit and the second separation element are connected in parallel with one another. 5. The converter as recited in claim 1 , wherein the shared potential is applied to a shared potential line to which the converter circuit is connected directly. 6. The converter as recited in claim 1 , wherein the shared potential is applied to a shared potential line to which the converter circuit is connected via a measuring shunt. 7. The converter as recited in claim 1 , wherein the converter circuit includes at least one half-bridges connected between the first monitoring circuit and the shared potential. 8. The converter as recited in claim 1 , wherein at least one of the first separation element and the second separation element one of enables and suppresses a current flow from a network assigned to the respective separation element into the converter circuit, independently of a switching status of the respective separation element. 9. The converter circuit as recited in claim 8 , wherein at least one of the first separation element and the second separation element includes a diode connected in parallel. 10. A method for operating a converter that includes a converter circuit situated between a first network and a second network and for converting one of a direct voltage and an alternating voltage at an input terminal at an input side into one of a direct voltage and an alternating voltage at an output terminal at an output side, the one of the direct voltage and the alternating voltage at the input side and the one of the direct voltage and the alternating voltage at the output side each being based on a shared potential; a first monitoring circuit situated between the input terminal and the converter circuit and configured to detect a current flow into the converter circuit at the input terminal; a second monitoring circuit situated between the output terminal and the converter circuit and configured to detect the current flow into the converter circuit at the output terminal; and at least one of: a first separation element situated between the input terminal and the converter circuit and for establishing a connection between the input terminal and the converter circuit as a function of the current flow detected by the first monitoring circuit, and a second separation element situated between the output terminal and the converter circuit and for establishing a connection between the output terminal and the converter circuit as a function of the current flow detected by the second monitoring circuit, the method comprising: suppressing a triggering of at least one of the first separation element and the second separation element for closing at least one of a respective separation element and switch elements of half-bridges, the suppressing being performed depending on a current flow detected in at least one of the first monitoring circuit and the second monitoring circuit when the converter circuit is deactivated. 11. A converter, including: a converter circuit situated between a first network and a second network and for converting one of a direct voltage and an alternating voltage at an input terminal at an input side into one of a direct voltage and an alternating voltage at an output terminal at an output side, the one of the direct voltage and the alternating voltage at the input side and the one of the direct voltage and the alternating voltage at the output side each being based on a shared potential; a first monitoring circuit situated between the input terminal and the converter circuit and for detecting a current flow into the converter circuit at the input terminal; a second monitoring circuit situated between the output terminal and the converter circuit and for detecting the current flow into the converter circuit at the output terminal; and at least one of: a first separation element situated between the input terminal and the converter circuit and for establishing a connection between the input terminal and the converter circuit as a function of the current flow detected by the first monitoring circuit, and a second separation element situated between the output terminal and the converter circuit and for establishing a connection between the output terminal and the converter circuit as a function of the current flow detected by the second monitoring circuit, wherein at least one of: the first monitoring circuit and the first separation element are connected in parallel with one another, and the second monitoring circuit and the second separation element are connected in parallel with one another.