Recent years, Iot (internet of things) has become a very popular topic in consumer electronics. Wearable device and various of sensors which construct the Iot makes the market have tremendous demand. Iot biosensing application such as food safety, medical and drug testing. It is attractive article of sensor product with cost-effective price. Biosensing technology such as 2 D PhC (photonic crystal) biosensor. The detection limit can reach to watery concentration. Although the high detection limit it reached, the measurement facility such as light source and monochromatic meter are still in high cost. Usage of low resolution detector and low cost light source but sill remain the sufficient precision is an important issue to promote the biosensor to consumer. In this thesis, the anatyle detection via 2 D PhC band diagram is studied. In the first part, we fabricated the 2 D PhC structure on silicon wafer. Three kinds of LED (light emitting diode) are used to measuring refractive index of glucose solution which the concentration range are 0.002 mole/L to 0.5 mole/L. The device is putting on the stage and fixing the angle of incident light. The LED illuminated the PhC biosensor sensing area via fiber. The reflect signal was collected by the cost-effective spectral meter. The traditional analysis method including angular spectra and spectral analysis was executed. The results found that our 2 D PhC biosensor cannot measure the glucose solution reflective index under the low resolution spectral meter with traditional analysis. In second part, the same 2 D PhC structure is fabricate on silicon wafer. Multi period grating can be measured by changing the incident direction on 2 D photonic crystal. Thus we extend the experiment in the first part. Measuring the 3 kinds LEDs and changing the glucose solution range from 0.002 mole/L to 0.5mole/L on the PhC biosensor. Changing the grating period by rotating the stage. Also, traditional measurement method employed and the main method in this thesis – band diagram analysis to analyze the reflective index of glucose concentration. Results shows that the traditional measurement method still interfered by noise. The PhC band diagram analysis benefits from the normalize process which can control the noise and presenting the refractive index with self-align rather than water reference. The sensor’s detection limit and sensitivity are also defined. The sensitivity is proportional to PhC period. The detection limit is effected by incident spectral and absorption of analyte.