Optical reception device, station-side device, PON system, preamplifier, optical reception method, and method for suppressing output inversion of integrator

The invention claimed is: 1. An optical reception device configured to receive an optical signal in a burst state, the optical reception device comprising: a light receiving element configured to receive the optical signal; an amplifier configured to receive and amplify a current based on an input current from the light receiving element; a direct-current adjustment circuit connected to an input electric path extending from the light receiving element to the amplifier, the direct-current adjustment circuit being configured to remove an offset current included in the input current; an alternating-current adjustment circuit connected to the input electric path and configured to cause a part of the input current to flow therein; and a controller configured to control the direct-current adjustment circuit and the alternating-current adjustment circuit on the basis of an output of the amplifier and a reference voltage, wherein the controller includes an integrator configured to integrate the output of the amplifier and output a resultant output to two electric paths of a positive phase and a negative phase, and an inversion suppression circuit configured to operate so as to inject a current to the positive phase and extract a current from the negative phase when a negative phase potential of the output of the integrator is higher than a positive phase potential thereof. 2. The optical reception device according to claim 1 , wherein the current injected by the inversion suppression circuit and the current extracted by the inversion suppression circuit are equivalent to each other. 3. The optical reception device according to claim 1 , wherein the inversion suppression circuit includes: an operational transconductance amplifier configured to convert, into a current, a voltage outputted by the integrator and based on a potential difference between the positive phase and the negative phase, the operational transconductance amplifier being configured to output the current; and a current mirror circuit configured to generate a current to be injected to the positive phase and a current to be extracted from the negative phase, on the basis of an output of the operational transconductance amplifier. 4. The optical reception device according to claim 1 , wherein a negative offset voltage is added to the reference voltage. 5. The optical reception device according to claim 1 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 6. The optical reception device according to claim 2 , wherein the inversion suppression circuit includes: an operational transconductance amplifier configured to convert, into a current, a voltage outputted by the integrator and based on a potential difference between the positive phase and the negative phase, the operational transconductance amplifier being configured to output the current; and a current mirror circuit configured to generate a current to be injected to the positive phase and a current to be extracted from the negative phase, on the basis of an output of the operational transconductance amplifier. 7. The optical reception device according to claim 2 , wherein a negative offset voltage is added to the reference voltage. 8. The optical reception device according to claim 3 , wherein a negative offset voltage is added to the reference voltage. 9. The optical reception device according to claim 6 , wherein a negative offset voltage is added to the reference voltage. 10. The optical reception device according to claim 2 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 11. The optical reception device according to claim 3 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 12. The optical reception device according to claim 4 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 13. The optical reception device according to claim 6 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 14. The optical reception device according to claim 7 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 15. The optical reception device according to claim 8 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 16. The optical reception device according to claim 9 , wherein when the positive phase potential is higher than the negative phase potential, the inversion suppression circuit does not perform an operation of injecting a current to the positive phase and extracting a current from the negative phase. 17. An optical line terminal connected to a plurality of optical network units via an optical transmission line formed by an optical fiber, the optical line terminal comprising: a light receiving element configured to receive an optical signal in a burst state from each optical network unit; an amplifier configured to receive and amplify a current based on an input current from the light receiving element; a direct-current adjustment circuit connected to an input electric path extending from the light receiving element to the amplifier, the direct-current adjustment circuit being configured to remove an offset current included in the input current; an alternating-current adjustment circuit connected to the input electric path and configured to cause a part of the input current to flow therein; and a controller configured to control the direct-current adjustment circuit and the alternating-current adjustment circuit on the basis of an output of the amplifier and a reference voltage, wherein the controller includes an integrator configured to integrate the output of the amplifier and output a resultant output to two electric paths of a positive phase and a negative phase, and an inversion suppression circuit configured to operate so as to inject a current to the positive phase and extract a current from the negative phase when a negative phase potential of the output of the integrator is higher than a positive phase potential thereof. 18. A PON system comprising: a plurality of optical network units; an optical transmission line formed by an optical fiber; and an optical line terminal configured to communicate with the plurality of optical network units via the optical transmission line, wherein an optical reception device installed at least to t