A new three-dimensional, continuous ionospheric model based on radio occultation observation, called the TaiWan Ionospheric model (TWIM), is used for the first time to remove absolute and differential ionospheric delays in single-frequency C/A code pseudorange observations. To evaluate its performance, two positioning algorithms namely stand-alone positioning and differential positioning are used. The VTEC maps and positioning results using TWIM is compared with results using other models, such as the Klobuchar (KLB) and the global ionospheric maps (GIM). It has been demonstrated that global and regional TEC maps using TWIM and GIM exhibit a detailed structure of the ionosphere, particularly at low-latitude region, whereas KLB only provide the basic diurnal and geographic features of the ionosphere. TWIM can also provide three-dimensional ionospheric electron density and improve positioning significantly. Using the stand-alone positioning, it is shown that TWIM provides very good positioning comparable to GIM and better than KLB even for low satellite elevation masks. Based on the average performance rating of each model across all stations and all days of observation, TWIM performs very well and can provide meter-to-decimeter accuracy and its results is very comparable with the results using GIM. KLB is a far third where occasionally performs even worse than UNC. In differential positioning, daily horizontal mean errors for all baselines show a highly positive linear correlation with the horizontal baseline vector. This effect is significantly reduced when using differential ionospheric correction derived from ionospheric models, and does not take effect along the vertical. TWIM can even provide decimeter-to-centimeter level accuracy in differential GPS positioning for single-frequency receivers during geomagnetic quiet conditions across all seasons and various solar activities. This shows that based on both positioning algorithms the general order of increasing accuracy is KLB, TWIM, and GIM. The similarity of the performance of TWIM and GIM demonstrates the applicability of TWIM in providing quality electron density and electron density gradients, which can be extended to other geodetic and space science applications.