Patent Number: 046719199
Section: claims

1. A method of monitoring reactor power levels in a nuclear reactor, comprising the steps of: (a) producing a sample signal indicating radiation detected during a sampling period having a predetermined length;  (b) converting the sample signal into a converted signal;  (c) multiplying the converted signal by a first constant to produce a first multiplied signal;  (d) multiplying the converted signal by a second constant divided by the length of the sampling period to produce a second multiplied signal;  (e) converting the first and second multiplied signals into current power level and rate of power level change signals, respectively;  (f) summing a prior rate of power level change signal produced during an immediately previous sampling period with the second multiplied signal to produce the current rate of power level change signal in step (e);  (g) summing a prior power level signal produced during the immediately previous sampling period with the length of the sampling period multiplied by the prior rate of power level change signal produced during the immediately previous sampling period to produce a predicted power level signal;  (h) subtracting the predicted power level signal from the sample signal to produce the converted signal in step (b);  (i) summing the first multiplied and predicted power level signals to produce the current power level signal in step (e); and  (j) outputting the current power level, rate of power level change and predicted power level signals.  radiation sensing means for sensing radiation emitted from the nuclear reactor and outputting a sample signal indicative of the radiation sensed during a sampling period having a predetermined length; and  microprocessing means for converting the sample signal into reactor power level, rate of reactor power level change and predicted reactor power level signals.  neutron sensing means for sensing neutrons emitted from the pressurized light water nuclear reactor and outputting a current indicative of the neutrons sensed during the sampling period;  current-to-voltage converting means for converting the current output by said neutron sensing means into an analog voltage; and  analog/digital converting means for converting the analog voltage output by said current-to-voltage converting means into the sample signal.  means for converting the sample signal into a converted signal;  means for multiplying the converted signal by a first constant to produce a first multiplied signal;  means for multiplying the converted signal by a second constant divided by the length of the sampling period to produce a second multiplied signal;  means for summing a prior rate of reactor power level change signal for an immediately previous sampling period with the second multiplied signal to produce the rate of reactor power level change signal for the sampling period;  means for summing a prior reactor power level signal for the immediately previous sampling period with the length of the sampling period multiplied by the prior rate of reactor level change signal to produce the predicted reactor power level signal;  means for subtracting the predicted reactor power level signal from the sample signal to produce the converted signal; and  means for summing the first multiplied and predicted reactor power level signals to produce the reactor power level signal for the sampling period.  (a) producing a sample signal f(k) indicating neutrons detected during a sampling period k having a predetermined length T;  (b) producing a rate of power level change signal p(k) in accordance with ##EQU7## where p(k-1) is the rate of power level change during an immediately previous sampling period, .beta. is a constant with a value between zero and one, inclusive, and p.sub.p (k) is a predicted power level for a next sampling period;  (c) producing a reactor power level signal p(k) in accordance with EQU p(k)=p.sub.p (k)-.alpha.[f(k)-p.sub.p (k)],  where .alpha. is a constant equal to 2.sqroot..beta.-.beta.; and  (d) producing the predicted power level p.sub.p (k) in accordance with EQU p.sub.p (k)=p(k-1)+T p(k-1),  where p(k-1) is the power level of the immediately previous sampling period.  neutron detecting means for detecting neutrons emitted from the pressurized light water nuclear reactor and outputting a sample signal f(k) indicative of the neutrons detected during a sampling period k having a predetermined length T;  rate means for converting the sample signal k into a rate of power level change signal p(k) in accordance with ##EQU8## where p(k-1) is the rate of power level change for an immediately previous sampling period k-1, .beta. is a constant with a value between zero and one, inclusive, and p.sub.p (k) is a predicted power level for a next sampling period;  power signal means for converting the sample signal into a reactor power level signal p(k) in accordance with EQU p(k)-p.sub.p (k)-.alpha.[f(k)-p.sub.p (k)],  where .alpha. is equal to 2.sqroot..beta.-.beta.; and  predicted power signal means for converting the sample signal into a predicted reactor power level signal p.sub.p (k) in accordance with EQU p.sub.p (k)=p(k-1)+T p(k-1), 2. A reactor power level monitor for a nuclear reactor, comprising: 3. A reactor power level monitor as recited in claim 2, wherein the sample signal contains noise and said microprocessor means comprises noise reduction means for reducing the noise in said sample signal. 4. A reactor power level monitor as recited in claim 2, wherein said radiation sensing means comprises: 5. A reactor power level monitor as recited in claim 2, wherein said microprocessor means comprises: 6. A method of monitoring reactor power levels in a pressurized light water nuclear reactor, comprising the steps of: 7. A reactor power level monitor for a pressurized light water nuclear reactor, comprising: