Background Current strategies of systematic screening for active tuberculosis (TB) in resource-limited settings use prolonged cough or any TB symptoms as the initial screening criteria. The suboptimal sensitivity or specificity of these criteria lead to the difficulty of selecting the best strategy for TB screening. A prediction model of prevalent TB was developed to improve the use of relevant clinical information and assist decision-making of systematic screening. Methods Cross-sectional data from the prevalence survey of Zambia South Africa Tuberculosis and AIDS Reduction trial were used. Participants with HIV negative/ unknown were included in the analysis. Potential predictors included TB symptoms and risk factors, i.e., gender, life style, history of TB, and body mass index. Multivariable logistic regression model was constructed in the South Africa training set (No. of TB cases: 355) using the backward elimination method based on AIC, and the result was converted into risk scores. Performance of the scoring system was evaluated in the South Africa validation set (No. of TB cases: 176) and Zambia validation set (No. of TB cases: 107). Cost-effectiveness analyses were conducted comparing the scoring system against the conventional strategies (prolonged cough and any TB symptoms). Results The predictors and corresponding scores in the final model were cough >=2wks (5), cough <2wks (2), night sweats (2), personal TB history (2), ever drink (2), household TB history (1), ever smoke (1), and weight loss (1). AUC of the scoring system in South Africa validation set was 0.68 (95%CI: 0.64-0.72), compared against those for prolonged cough (0.58, 0.54-0.62) and any symptoms (0.6, 0.56-0.64). In Zambia dataset the AUC of the scoring system was 0.66 (0.60-0.72), which was also higher than those of current tools. Systematic screening algorithms with the scoring system as an initial screening tool dominated the algorithms using the two conventional tools in cost-effectiveness analyses. The ACER of the algorithm using the new scoring system ranged from 428 to 1848$USD per TB case detected under various cutoff score values in the SA validation set, and it ranged from 171 to 8,461$USD per TB case detected in the Zambia dataset. Conclusions This new prediction model had better discrimination performance and superior cost effectiveness than the conventional tools. It also provides flexible screening options for TB systematic screening programs to target those with high TB risk under budget constraints.