Systems and methods for estimating a volume of a hollow organ

What is claimed is: 1. A system comprising: a device configured to float within urine housed within a patient's bladder, the device comprising: a first portion that is within a water-resistant housing, the first portion comprising: a first light-based distance sensor located on a first polar end of the device, the first light-based distance sensor comprising: a first emitter, comprising a first infrared light emitting diode (LED), to transmit a conical beam of first light to a first inner surface of the patient's urinary bladder; and a first detector, comprising a first photodiode or a first phototransistor, to receive a portion of the first light back-reflected from the first inner surface of the patient's urinary bladder, wherein the portion of the first light back-reflected is based on a first distance between the first light-based distance sensor and the first inner surface of the patient's urinary bladder; a second light-based distance sensor located on a second polar end of the device, wherein the second polar end of the device is opposite of the first polar end, the second light-based distance sensor comprising: a second emitter, comprising a second infrared light emitting diode (LED), to transmit a conical beam of second light to a second inner surface of the patient's urinary bladder; and a second detector, comprising a second photodiode or a second phototransistor, to receive a portion of the second light back-reflected from the second inner surface of the patient's urinary bladder, wherein the portion of the second light back-reflected is based on a second distance between the second light-based distance sensor and the second inner surface of the patient's urinary bladder; electronics configured to determine a radius of the urinary bladder based on an average of the first distance between the first light-based distance sensor and the first surface of the patient's urinary bladder and the second distance between the second light-based distance sensor and the second surface of the patient's urinary bladder; and a battery configured to provide power to the first light-based distance sensor and the second light-based distance sensor, and further configured to act as an orienting weight for the device within the patient's urinary bladder to reduce movement of the device within the patient's urinary bladder; and a second portion that is non-rigid and configured to control a location of the device within the patient's urinary bladder. 2. The system of claim 1 , wherein the first portion is configured to estimate a volume of the patient's urinary bladder based on the radius of the patient's urinary bladder, wherein the patient's urinary bladder is approximated as a sphere. 3. The system of claim 2 , wherein the estimate of the volume of the patient's urinary bladder is further based on a conductance sensed within the patient's urinary bladder. 4. The system of claim 2 , wherein the device further comprises a pressure sensor to detect a pressure within the patient's urinary bladder, wherein the electronics determine a state of the bladder based on the pressure and the estimated volume. 5. A method comprising: transmitting a conical beam of first light from an emitter of a first light-based distance sensor to a first inner surface of a patient's urinary bladder, wherein the first light-based distance sensor is located on a first polar end of a device floating within urine housed inside the patient's urinary bladder; receiving a portion of the light back-reflected from the first inner surface of the patient's urinary bladder at a receiver of the first light-based distance sensor, wherein the back-reflected portion of the first light is reflected from a portion of the first inner surface of the patient's urinary bladder that is on-axis with the first light-based distance sensor and a second light-based distance sensor, and the rest of the back-reflected first light is scattered away at other angles; determining a first distance between the first light-based distance sensor and the first inner surface of the patient's urinary bladder based on the portion of the light back-reflected to the receiver; transmitting a conical beam of second light from a second emitter of the second light-based distance sensor to a second part of the inner surface of the patient's urinary bladder, wherein the second light-based distance sensor is located on a second polar end of the device floating within urine housed inside the patient's urinary bladder, wherein the second polar end is opposite the first polar end; receiving a portion of the second light back-reflected from the second part of the inner surface of the patient's urinary bladder at a second receiver of the second light-based distance sensor, wherein the back-reflected portion of the second light is reflected from a portion of the second inner surface of the patient's urinary bladder that is on-axis with the second light-based distance sensor, and the rest of the back-reflected second light is scattered away at other angles; determining a second distance between the second light-based distance sensor and the second part of the inner surface of the patient's urinary bladder based on the portion of the second light back-reflected to the second receiver; and estimating a volume of the patient's urinary bladder using a spherical approximation based on an average of the first distance between the first light-based distance sensor and the first surface of the patient's urinary bladder and the second distance between the second light-based distance sensor and the second surface of the patient's urinary bladder. 6. The method of claim 5 , further comprising: receiving a conductance of the urine inside the patient's urinary bladder; and wherein the volume is further based on the conductance of the urine. 7. A method comprising: determining bladder pressure at a plurality of points over a time period using a pressure sensor mounted on a device floating within urine housed inside the patient's urinary bladder; determining corresponding bladder volumes at the plurality of points over the time period based on information sensed by two light-based distance sensors located within the bladder on the device, wherein the two light-based distance sensors are located on opposing polar ends of the device, wherein the information sensed by the two light-based distance sensors comprises a distance value for each of the plurality of points, wherein the distance value is determined by: transmitting a conical beam of light from an emitter of each of the two light-based distance sensors to inner surfaces of the patient's urinary bladder; receiving a portion of the light back-reflected from the inner surfaces of the patient's urinary bladder at a receiver of the two light-based distance sensors, wherein the distance value is based on the portion of the light back-reflected to the receiver from the inner surfaces of the patient's urinary bladder; determining a subset of bladder pressures and corresponding bladder volumes corresponding to a time segment during the time period; sending the subset of bladder pressures and corresponding bladder volumes to an external device; and diagnosing a bladder dysfunction based on a comparison of bladder volumes corresponding to the subset of bladder pressures and a quantified metric for the bladder dysfunction.