At 30 GHz, any antenna inside of a living tissue would not work. The complex permittivity and a high loss will highly attenuate any "radiated" power. You can start with a salty-water "tissue phantom" to see the results.
As well as a tissue, salty water has the permittivity of ~ 80, so your antenna size will have to be reduced by a square root of it, or, ~9 times. In air, at 30 GHz, the wavelength is 10 mm, so your antenna will be ~1.1 mm long.
I guess any leakage from the equipment around will mask any signal that could propagate from this tissue-embedded antenna. BTW, how can you generate a 30GHz signal in the tissue?
at 30 GHz (milimeter wave) the size of the antenna is small. that why i try to design at this range of frequency but u a right i don't have any experience in high frequency. i try to search any journal from internet but cannot get much info about medical implant at this frequency.
The complex permittivity and a high loss will highly attenuate any "radiated" power. You can start with a salty-water "tissue phantom" to see the results.
As well as a tissue, salty water has the permittivity of ~ 80, so your antenna size will have to be reduced by a square root of it, or, ~9 times. In air, at 30 GHz, the wavelength is 10 mm, so your antenna will be ~1.1 mm long.
thank you very much yura717 and volker. i'm very appreciate it. i already design a microstrip rectangular patch antenna at 30 GHz and manage to get a return loss result base on transmission line model. the size of the antenna same like your flickr photo. the problem is which connector are suitable to attach to the patch.
The reason I explained above. Frequencies > 6 GHz cannot effectively propagate from the tissue out. The tissue is VERY lossy. Check google for Alabaster, Ph.D. thesis on Microwave measurement of tissue parameters